A SAN enables the universal connectivity of servers and disk devices. Compared to the conventional client/server computer system, a SAN delivers the following benefits:

· Allows the servers to share data and directly access data created by one another without having to copy it.

· Improves storage scalability.

· Centralizes the management of data backup, access, and security.

Most SANs use FC or Ethernet to interconnect devices. An FC SAN uses the FC protocol suite for communication, and an Ethernet SAN uses the TCP/IP protocol suite for communication.

This document covers only the FC SAN.

FC SAN

Figure 1 shows three FC SAN networking methods. The first two networking methods are simple and can connect only a limited number of devices.

· Point-to-point connection—Directly connects a server and a disk device.

· Arbitrated loop—Supports up to 126 devices.

· Switched fabric—Connects servers and disk devices through FC switches. In a switched fabric, the servers and disk devices are called "nodes." A fabric uses 24-bit addressing and supports thousands of devices.

Figure 1 FC SAN networking

NOTE:

· An FC SAN refers to a network that includes FC switches and nodes.

· A fabric refers to a transmission network that includes FC switches.

FC protocol

The servers, FC switches, and disk devices in an FC SAN must all support FC.

The world wide name (WWN) is a 64-bit address. It identifies a fabric or an entity (such as an FC switch, node, or port) in an FC SAN. The upper-layer protocol of FC uses WWNs for communication. Each entity has a factory-assigned, globally unique WWN.

FC address

The FC protocol accesses communication entities in an FC SAN through FC addresses. An FC address is also known as an "FC ID."

Figure 2 shows the structure of an FC address. The FC address is 24 bits long and contains the following 8-bit fields:

· Domain_ID—A domain represents a switch and all N_Ports connected to the switch. For more information about N_Ports, see "Port modes." A domain ID, which is in the range of 1 to 239, uniquely identifies an FC switch. Different FC switches in the same fabric have different domain IDs.

· Area_ID—One or more N_Ports on the same node can be assigned to an area, which is identified by an area ID.

· Port_ID—The Port_ID field identifies an N_Port.

Figure 2 Structure of an FC address

An FC address can uniquely identify an N_Port on a node. Different N_Ports on the same node have different FC addresses. FC switches use domain IDs to route messages between each other.

The FC protocol standardizes the FC address usage. For more information, see "Appendixes."

Port modes

In a switched fabric, nodes and FC switches communicate through interfaces operating in different modes.

Figure 3 Port modes

A node supports the following port modes:

· N_Port—Directly connects to a fabric.

· NL_Port—Connects to a fabric through an arbitrated loop.

An FC switch provides the following port modes:

· E_Port—Connects to an E_Port on another FC switch.

· F_Port—Connects to an N_Port on a node or an NP_Port on another FC switch.

· NP_Port—Connects to an F_Port on another FC switch.

E_Ports connect FC switches to form a fabric, and F_Ports connect the nodes to FC switches in the fabric.

Communication flow

FC switches provide data transmission services. Through FC switches, a server sends instructions and data to disk devices and reads data from disk devices.

Figure 4 FC SAN communication model

The following takes a server accessing a disk device as an example to see how data communication occurs in an FC SAN.

1. The server and the disk device send fabric login (FLOGI) packets to register with the FC switches. Then, the FC switches assign FC addresses to each directly-connected node.

A FLOGI packet contains information that includes the port WWN, node WWN, and the expected FC address.

2. The registered server and disk device send name service registration requests to their respective access FC switches to register name service information, including FC4 information. Finally, each FC switch in the fabric stores the name service information of all nodes. For more information about FC4 information, see "Configuring and obtaining FC4 information of nodes."

3. To access a disk device, the server must obtain the list of disk devices in the fabric and their WWNs and FC addresses. For this purpose, the server must send a name service query request to its directly-connected FC switch.

4. After the server obtains the FC address of the disk device, the server can send FC frames destined to the FC address to the FC switch nearby.

5. When the FC switch receives the FC frame from the server, it performs the following operations:

? Queries its FIB table for a data forwarding path according to the destination FC address.

? Forwards the FC frame to the next-hop FC switch.

6. The next-hop FC switch forwards the FC frame in the same way, until the FC switch at the last hop forwards the FC frame to the destination disk device.

NOTE:

A FIB table is generated by the FC switch through calculation based on the FC routing protocol or configured static routes.

VSAN

In actual applications, the data is insecure if the data of all users is transmitted in the same FC SAN. You can divide one physical FC SAN into multiple virtual storage area networks (VSANs). VSANs are separated from one another and provide independent services. This enhances adaptability and security of the network and offers more effective services for users. For more information about VSANs, see "Configuring VSANs."

FC zone

The VSAN technique divides one physical SAN into multiple logical SANs. A VSAN, however, cannot perform access control over the servers and disk devices (or the N_Ports) connected to a fabric. N_Ports in the same VSAN can access one another only if these N_Ports register name services. This creates data security risks.

Zoning can solve the preceding problem by dividing a VSAN into zones and adding N_Ports to different zones for different purposes. N_Ports in different zones are separated to implement access control.

For more information about FC zones, see "Configuring FC zones."

FCoE

A data center using the FC SAN technology typically includes separate local area networks (LANs) and SANs. LANs carry traditional Ethernet/IP services, and SANs carry network storage services.

To provide services for LANs and use SANs for storage simultaneously in a traditional network, the servers must use independent Ethernet adapters and FC adapters. In addition, the IP switches and the FC switches are also independent and have independent network connections. Such a network needs many switches, network adapters, and cables, and it brings high investments and maintenance costs and low scalability.

FCoE was introduced to solve this problem. FCoE transports FC over Ethernet. In an FCoE solution:

· The server uses an FCoE-capable Ethernet adapter.

· The FCoE forwarder (FCF) switch integrates the functions of both the traditional IP switch and FC switch.

FCoE reduces the number of network adapters, switches, and cables, and the network operation and maintenance workload. In all, FCoE reduces the total cost.

Figure 5 FCoE for I/O consolidation

As shown in Figure 5:

· In the traditional network, the server is connected to the LAN through an Ethernet interface and to the SAN through an FC interface.

· In the FCoE network, the server is connected to the LAN and SAN through one FCoE-capable FCF switch. The link between the server and the FCF switch can transmit both Ethernet frames and FC frames.

Basic concepts

As shown in Figure 6, the link between the FCF switch and the ENode can receive and send both Ethernet frames and FC frames. ENodes can transport FC over Ethernet. ENodes include servers and disk devices.

Figure 6 FCoE network diagram

VFC interface and VN interface

A virtual fibre channel (VFC) interface is a logical interface manually created on an FCF switch to simulate the functionality of a physical FC interface.

To use a VFC interface, bind it to a physical Ethernet interface.

You can connect either an ENode or an FCF switch to a VFC interface.

VFC interfaces support E mode, F mode (default), and NP mode.

The virtual node (VN) interface is a logical interface on an ENode to simulate the function of a physical FC interface.

FIP protocol

FCoE initialization protocol (FIP) is an FCoE control protocol that establishes and maintains virtual links.

FIP establishes a virtual link between the VFC interface of an FCF switch and either of the following:

· A VN interface of an ENode.

· A VFC interface of another FCF switch.

The virtual links provide a physical infrastructure for transmitting FC frames over Ethernet.

FCoE frames

To transmit an FC frame over Ethernet, FCoE encapsulates the FC frame in an FCoE frame by adding an Ethernet frame header to the FC frame.

An FCoE frame uses Ethernet II encapsulation, which has the following fields in the Ethernet header:

· EtherType 0x8906.

· Destination MAC address/source MAC address—The definitions of this field are different for switches and nodes.

? For a switch, this field is the FCoE MAC address of the switch (which can be displayed by using the display fcoe command).

? For a node, this field is the fabric provided MAC address (FPMA) of the node. As shown in Figure 7, an FPMA contains the following elements:

- The FC-MAP as the 24 most significant bits.

- The FC address of the VN interface as the 24 least significant bits.

The FC-MAP takes the value of the switch FC-MAP, 0x0efc00 by default and configurable by using the fcoe fcmap command.

Figure 7 FPMA composition

How FCoE works

This section describes how FCoE works on the FCF switch (rather than on the ENode).

Figure 8 Block diagrams of the ENode and the FCF switch

Procedure for receiving and sending FC frames over Ethernet

An FC frame is transmitted over Ethernet using the following workflow:

1. FIP establishes a virtual link between the VFC interface of the FCF switch and one of the following interfaces:

? A VN interface of an ENode.

? A VFC interface of another FCF switch.

2. After the virtual link is established, the FCF switch encapsulates the FC frame in an FCoE frame and sends it out.

3. After receiving the FCoE frame, the FCF switch removes its Ethernet header to send the original FC frame to the upper layer for processing.

How FIP works

FIP establishes and maintains virtual links between a VFC interface and a VN interface or between VFC interfaces.

FIP uses Discovery Solicitation packets and Discovery Advertisement packets. Discovery Advertisement packets include the following types:

· Solicited Discovery Advertisement—A reply for a Discovery Solicitation.

· Unsolicited Discovery Advertisement—Periodically sent to advertise the presence of a virtual link or maintain an existing virtual link.

The following example shows how a virtual link is established between an FCF switch and an ENode.

Figure 9 FIP operation

As shown in Figure 9, the following workflow is used to establish a virtual link:

1. The ENode sends a Discovery Solicitation containing its FCoE MAC address.

2. After receiving the Discovery Solicitation, the FCF switch acts differently depending on whether the receiving VFC interface is bound to an FCoE MAC address.

? If it is not bound to an FCoE MAC address, the switch learns the FCoE MAC address and replies with a solicited Discovery Advertisement. The fcf priority field of the solicited Discovery Advertisement transports the FCF priority of the VFC interface.

? If it is bound to an FCoE MAC address, the switch identifies whether the FCoE MAC address in the Discovery Solicitation matches the bound FCoE MAC address.

- If they match, the switch replies with a solicited Discovery Advertisement, whose fcf priority field carries the FCF priority of the VFC interface.

- If they do not match, the switch discards the Discovery Solicitation.

3. The FCF switch periodically sends unsolicited Discovery Advertisements, whose fcf priority field carries the FCF priority of the system.

The sending interval is specified by using the fcoe fka-adv-period command and defaults to 8 seconds.

4. After receiving the Discovery Advertisements, the ENode determines the FCF switch with the highest priority according to the fcf priority field. Then, the ENode sends a FLOGI request to that switch for login.

5. After receiving the FLOGI request, the FCF switch identifies whether the source MAC address matches its learned or bound FCoE MAC address.

? If they match, the FCF switch sends a FLOGI LS_ACC, which indicates that the establishment of the virtual link is completed.

? If they do not match, the FCF switch discards the FLOGI request.

6. The FCF switch also periodically sends unsolicited Discovery Advertisements to maintain established virtual links. If the ENode fails to receive an unsolicited Discovery Advertisement within a period 2.5 times the FKA advertisement interval, it deletes the virtual link.

FCoE modes

The switch supports the following FCoE modes:

· FCF mode—A switch operating in this mode is called an FCF switch. Its VFC interfaces support E mode (E_Port) and F mode (F_Port).

· NPV mode—A switch operating in this mode is called an N Port Virtualization (NPV) switch. Its VFC interfaces support F mode (F_Port) and NP mode (NP_Port).

· Transit mode—A switch operating in this mode is called a Transit switch. Its Ethernet interfaces can operate in ENode mode or FCF mode.

An FCoE-capable switch can operate in the following modes:

· FCF mode—When the switch operates in this mode, it can perform one of the following operations:

? Connect to the E_Port on another FCF switch through its E_Port.

? Connect to the N_Port on a node or the NP_Port on an NPV switch through its F_Port.

· NPV mode—When the switch operates in this mode, it can perform one of the following operations:

? Connect to the N_Port on a node through its F_Port.

? Connect to the F_Port on an FCF switch through its NP_Port.

· Transit mode—When the switch operates in this mode, you can perform one of the following tasks:

? Configure an Ethernet interface to operate in ENode mode, so that the Ethernet interface can receive traffic from only an ENode.

? Configure an Ethernet interface to operate in FCF mode, so that the Ethernet interface can receive traffic from only an FCF switch.

· Non-FCoE mode—When the switch operates in this mode, it is a standard switch and does not provide any FCoE capabilities.

FCF mode

An FCF switch encapsulates FC frames in Ethernet frames and uses FCoE virtual links to simulate physical FC links. An FCF switch provides the FC switch features on a lossless Ethernet network.

Figure 10 FCF network diagram

In an FCoE environment as shown in Figure 10, FCF switches communicate with the ENode over a lossless Ethernet network. The end of an FCoE virtual link on an FCF switch is a VFC interface. The peer end of an FCoE virtual link can be a VN interface on an ENode or a VFC interface on another FCF switch.

Like an FC switch, each FCF switch is assigned a domain ID. Each FC SAN supports a maximum of 239 domain IDs, so an FC SAN cannot have more than 239 switches.

NPV mode

An FC SAN needs a large number of edge switches that are connected directly to nodes. NPV switches are developed to expand the number of switches in an FC SAN.

Figure 11 NPV network diagram

As shown in Figure 11, the NPV switch resides between nodes and the core switch on the edge of the fabric. The core switch is a switch operating in FCF mode. The NPV switch is connected to the nodes through its F_Ports and to the core switch through its NP_Port. The NPV switch forwards traffic from its connected nodes to the core switch.

The NPV switch appears as an FCF switch to nodes and as a node to the core switch.

For more information about NPV, see "Configuring NPV."

Transit mode

FCoE supports FC SANs built on lossless Ethernet networks, and allows Transit switches to be added between FCF switches and ENodes. Figure 12 shows a scenario where ENodes are connected to FCF switches through a Transit switch.

Figure 12 Transit network diagram

Ethernet interfaces on a Transit switch can operate in ENode mode or FCF mode.

· An Ethernet interface connected to an ENode must be configured to operate in ENode mode.

· An Ethernet interface connected to an FCF switch must be configured to operate in FCF mode.

When Transit switches are interconnected, you must configure Ethernet interfaces to operate in the correct modes. As shown in Figure 13, ENode 2 can register with only FCF switch 2. To register ENode 2 with FCF switch 1, you must swap the operating modes of the Ethernet interfaces that connect the two Transit switches.

Figure 13 Transit cascading network diagram

Figure 14 shows a network scenario where both Transit and NPV switches are present.

Figure 14 Network diagram for NPV and Transit switches

The primary responsibilities of Transit switches are filtering and forwarding FCoE protocol packets. They can recognize and control FCoE packets as compared to standard Ethernet switches. However, they do not provide FCoE traffic processing capabilities as complex as FCF switches or NPV switches.

Protocols and standards

· FC-FS-3, Fibre Channel - Framing and Signaling - 3

· FC-SW-5, Fibre Channel - Switch Fabric - 5

· FC-LS-2, Fibre Channel - Link Services - 2

· FC-GS-6, Fibre Channel - Generic Services - 6

· FC-BB-5, Fibre Channel - Back Bone – 5

FCoE configuration restrictions and guidelines

Only the following interface modules support FCoE:

· EC interface modules.

· SE interface modules.

· SF interface modules.

· SG interface modules.

Installing a license

To use FCoE, you must install a valid data center license. For more information about licenses, see Fundamentals Configuration Guide.

Configuring the switch to operate in advanced mode

The switch supports FCoE only when it is operating in advanced mode. For more information about system operating modes, see Fundamentals Configuration Guide.

Configuring the FCoE mode

An FCoE-capable switch can operate in the FCF, NPV, Transit, or non-FCoE mode.

To configure a switch operating in an FCoE mode to operate in another FCoE mode, follow these steps:

1. Configure the switch to operate in the non-FCoE mode.

2. Configure the switch to operate in the target FCoE mode.

After you configure the switch to operate in non-FCoE mode, all FCoE-related settings in the original FCoE mode except VFC interfaces are cleared.

To configure an FCoE mode for a switch:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Configure an FCoE mode for the switch.	fcoe-mode { fcf \| fcf-npv \| npv \| transit }	By default, a switch operates in non-FCoE mode. The fcf-npv keyword is not supported in the current software version.
3. Display the FCoE mode of the switch.	display fcoe-mode	Available in any view.

FCoE features supported in different FCoE modes

The switch supports the following FCoE modes: FCF mode, NPV mode, and Transit mode. Each mode supports different FCoE features, as shown in Table 1. You can choose to configure different features based on the FCoE mode of a switch.

Table 1 FCoE features supported in different FCoE modes

FCoE feature	FCF mode	NPV mode	Transit mode
Configuring VFC interfaces	Supported.	Supported.	Not supported.
Configuring basic FCoE	Supported.	Supported.	Not supported.
Configuring VSANs	Supported.	Supported.	Not supported.
Building a fabric	Supported.	Only the Setting fabric timers function is supported.	Not supported.
Configuring FC routing and forwarding	Supported.	Only the following functions are supported: · Displaying FC routing table information. · Displaying FC FIB table information. · Display FC Exchange table information.	Not supported.
Configuring FC zones	Supported.	Not supported.	Not supported.
Configuring NPV	Not supported.	Supported.	Not supported.
Configuring FIP snooping	Not supported.	Not supported.	Supported.
Configuring FCS	Supported.	Not supported.	Not supported.
Configuring FDMI	Supported.	Not supported.	Not supported.
Configuring FC ping	Supported.	Not supported.	Not supported.
Configuring FC tracert	Supported.	Not supported.	Not supported.

Configuring VFC interfaces

A VFC interface can connect to an ENode, or a switch operating in the FCF, NPV, or Transit mode.

A VFC interface can operate in E mode, F mode (the default), or NP mode.

A VFC interface is a virtual logical interface. It implements the functionality of an FC interface. To make a VFC interface work, bind it to a physical Ethernet interface. The switch encapsulates the FC packets on a VFC interface in FCoE packets and transmits the packets over the Ethernet interface bound to the VFC interface.

Configuration restrictions and guidelines

If the Ethernet interface bound to a VFC interface is a hybrid or trunk port, for the VFC interface to come up, make sure the Ethernet interface allows its PVID. If its PVID is VLAN 1, the undo port hybrid vlan 1 or undo port trunk permit vlan 1 command cannot be configured on the Ethernet interface. If its PVID is not VLAN 1, the port hybrid vlan pvid untagged or port trunk permit vlan pvid command must be configured on the Ethernet interface.

To avoid FCoE packet loss in the Ethernet, you must perform the following tasks on the Ethernet interface bound to the VFC interface:

· Configure DCBX, PFC in auto mode, and ETS on the Ethernet interfaces that connect the switch to servers.

· Configure DCBX and PFC in auto mode on the Ethernet interfaces that connect the switch to disk devices.

· Forcibly enable PFC on the Ethernet interfaces connected to other switches.

For more information about DCBX, PFC, and ETS, see LLDP configuration in Layer 2—LAN Switching Configuration Guide.

Configuring a VFC interface

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Create a VFC interface and enter its view.	interface vfc interface-number	N/A
3. Configure the mode of the VFC interface.	fc mode { e \| f \| np }	By default, the mode of a VFC interface is F. An FCF switch supports E and F modes. An NPV switch supports F and NP modes.
4. Bind the specified Ethernet interface to the VFC interface.	bind interface interface-type interface-number [ mac mac-address ]	By default, no Ethernet interface is bound to a VFC interface. The VFC interface sends and receives packets through the Ethernet interface bound to it. When you bind an Ethernet interface to a VFC interface connecting to multiple ENodes through a Transit switch, you must specify an FCoE MAC address.
5. Add the VFC interface to the specified VSAN as a trunk interface.	port trunk vsan vsan-id-list	By default, a VFC interface is not added to any VSAN as a trunk interface. You can assign a VFC interface to a VSAN that does not exist and then create the VSAN.
6. (Optional.) Configure a description for the VFC interface.	description text	By default, the description of an interface is Interface name Interface, for example, Vfc1 Interface.
7. (Optional.) Set the expected bandwidth of the interface.	bandwidth bandwidth-value	By default, the expected bandwidth (in kbps) is the interface baud rate divided by 1000.
8. (Optional.) Restore the default settings for the VFC interface.	default	N/A
9. Bring up the VFC interface.	undo shutdown	By default, a VFC interface is up.

Displaying and maintaining VFC interfaces

Execute display commands in any view and reset commands in user view.

Task	Command
Display VFC interface information.	display interface [ vfc [ interface-number ] ] [ brief [ description \| down ] ]
Clear the statistics for VFC interfaces.	reset counters interface [ vfc [ interface-number ] ]

Configuring basic FCoE

To make the FCoE features operate, you must enable FCoE.

Basic FCoE configuration task list

Tasks at a glance
(Required.) Enabling FCoE for a VLAN and mapping the VLAN to a VSAN
(Optional.) Setting the FC-MAP value of the FCoE network
(Optional.) Setting the FKA advertisement interval value of the FCoE network
(Optional.) Setting the FCF priority of the FCoE network

Enabling FCoE for a VLAN and mapping the VLAN to a VSAN

When you use a VFC interface to transmit packets, the Ethernet interface bound to the VFC interface might allow multiple VLANs. You must enable FCoE for one of these VLANs and map a VSAN to the VLAN. Then, the packets from the VSAN are tagged with the VLAN tag and transmitted within the VLAN.

After you enable FCoE for a VLAN, the following changes occur on the VLAN:

· An FCoE-capable VLAN allows only FCoE traffic.

· All member ports in an FCoE-capable VLAN are isolated and will not form loops. For this reason, you do not need to enable STP or other loop detection protocols in an FCoE-capable VLAN. Otherwise, FCoE links might be blocked.

· A Layer 2 protocol enabled in an FCoE-capable VLAN runs based on the topology where all member ports in the VLAN are isolated at Layer 2.

Configuration restrictions and guidelines

When you configure this feature, follow these restrictions and guidelines:

· FCoE cannot be enabled for VLAN 1.

· VSANs are mapped to VLANs on a one-to-one basis.

· When you use a VFC interface to transmit packets, enable FCoE for the same VLAN and map this VLAN to the same VSAN at both ends.

· Make sure the Ethernet interface bound to the VFC interface allows the FCoE-capable VLAN.

Configuration procedure

To enable FCoE for a VLAN and map the VLAN to a VSAN:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VLAN view.	vlan vlan-id	N/A
3. Enable FCoE for the VLAN and map the VLAN to a VSAN.	fcoe enable [ vsan vsan-id ]	By default, FCoE is disabled for a VLAN. Make sure the VSAN to be mapped has been created.

Setting the FC-MAP value of the FCoE network

The FC-MAP value identifies an FCoE network. Switches in the same FCoE network must have the same FC-MAP value.

After an FC-MAP value is set, VFC interfaces perform a renegotiation. The same FC-MAP value is required for two VFC interfaces to negotiate successfully.

To set an FC-MAP value:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Set an FC-MAP value.	fcoe fcmap fc-map	The default setting is 0x0EFC00.

Setting the FKA advertisement interval value of the FCoE network

The FKA advertisement interval determines the length of time the switch takes to detect the disconnection of a virtual link.

The following workflow is used to maintain the virtual link established with a peer switch:

1. The switch sends unsolicited Discovery Advertisements every FKA advertisement interval out of its VFC interfaces in E mode.

The FKA advertisement interval value is carried in unsolicited Discovery Advertisements.

2. After receiving an unsolicited Discovery Advertisement, the peer switch maintains the status of the virtual link and records the FKA advertisement interval value.

3. If the peer switch fails to receive an unsolicited Discovery Advertisement within 2.5 FKA advertisement intervals, it deletes the virtual link.

The following workflow is used to maintain the virtual link established with a peer ENode:

4. The switch sends unsolicited Discovery Advertisements every FKA advertisement interval out of its VFC interfaces in F mode.

The FKA advertisement interval value is carried in unsolicited Discovery Advertisements.

5. After receiving an unsolicited Discovery Advertisement, the peer ENode maintains the status of the virtual link and records the FKA advertisement interval value.

6. If the peer ENode fails to receive an unsolicited Discovery Advertisement within 2.5 FKA advertisement intervals, it deletes the virtual link.

In addition, the ENode sends keepalive frames to the switch every FKA advertisement interval value. This value is obtained from unsolicited Discovery Advertisements received from the switch. After receiving a keepalive frame, the switch maintains the status of the virtual link. If the switch fails to receive a keepalive frame within 2.5 FKA advertisement intervals, it deletes the virtual link.

Configuration guidelines

When setting the FKA advertisement interval value on an FCF or NPV switch, use Table 2 as a reference to avoid service disruption.

Recommended value	Application scenarios	Remarks
Less than 90 seconds	Connected to servers, storage devices, or third-party switches.	According to FC-BB-5, the upper limit of the FKA advertisement interval is 90 seconds. In this scenario, a single-MPU FCF switch or NPV switch will experience FCoE traffic disruption during an ISSU reboot because of the following reasons: · This ISSU reboot takes more than 225 (2.5*90) seconds. · The peer deletes the virtual link for failing to receive unsolicited Discovery Advertisements within 225 seconds. You must also adjust the FKA advertisement interval on the upstream FCF switch to ensure service continuity in the following cases: · An active/standby switchover on an NPV switch. · An ISSU reboot on a dual-MPU NPV switch. You must do that for the following reasons: · The FKA advertisement interval set on the NPV switch affects only its VFC interfaces in F mode and connected ENodes. · Its VFC interfaces in NP mode use the FKA advertisement interval learned from the upstream FCF switch.
60–90 seconds	Active/standby switchover on the switch takes more than 2.5 x 60 seconds because of the amount of FCoE configuration. ISSU reboot on a dual-MPU switch takes more than 2.5 x 60 seconds because of the amount of FCoE configuration.	For more information about ISSU, see Fundamentals Configuration Guide.
300–600 seconds	ISSU reboot on a single-MPU switch to which no nodes are attached.	During an ISSU reboot on a single-MPU switch, the switch cannot send unsolicited Discovery Advertisements or keepalive frames.

Configuration procedure

To set an FKA advertisement interval value:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Set an FKA advertisement interval value.	fcoe fka-adv-period fka-adv-period	The default setting is 8 seconds.

Setting the FCF priority of the FCoE network

The FCF priority includes the system FCF priority and the VFC interface FCF priority.

· System FCF priority—The system FCF priority is used in the fcf priority field in a solicited Discovery Advertisement.

· VFC interface FCF priority—The VFC interface FCF priority is used in the fcf priority field in an unsolicited Discovery Advertisement.

An ENode selects the FCF switch with the highest priority from the FCF switches sending Discovery Advertisements and sends a FLOGI request to the FCF switch for login.

The FCF priority takes effect only on a VFC interface connected to an ENode (VFC interface operating in F mode).

Setting the system FCF priority

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Set the system FCF priority.	fcoe global fcf-priority priority	The default setting is 128. The configuration takes effect on all VFC interfaces operating in F mode.

Step

Command

Remarks

1. Enter system view.

system-view

N/A

2. Set the system FCF priority.

fcoe global fcf-priority priority

The default setting is 128.

The configuration takes effect on all VFC interfaces operating in F mode.

Setting the VFC interface FCF priority

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VFC interface view.	interface vfc interface-number	N/A
3. Set the FCF priority for the VFC interface.	fcoe fcf-priority priority	The default setting is 128. The configuration takes effect only on a VFC interface operating in F mode.

Displaying and maintaining basic FCoE

Execute display commands in any view.

Task	Command
Display global FCoE configuration.	display fcoe

Basic FCoE configuration example

Network requirements

As shown in Figure 15, use FCoE in a data center combining a LAN and a SAN to reduce the number of devices, network adapters, and cables.

Figure 15 Network diagram

Configuration procedure

1. Configure Switch A:

a. Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchA> system-view

[SwitchA] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchA] save

[SwitchA] quit

<SwitchA> reboot

b. Configure VLANs and interfaces:

# Create VLAN 10 and 20, which are intended to transmit Ethernet data traffic and storage traffic, respectively.

<SwitchA> system-view

[SwitchA] vlan 10

[SwitchA-vlan10] quit

[SwitchA] vlan 20

[SwitchA-vlan20] quit

# Configure interface Ten-GigabitEthernet 1/0/1 as a hybrid port.

[SwitchA] interface ten-gigabitethernet 1/0/1

[SwitchA-Ten-GigabitEthernet1/0/1] port link-type hybrid

# Assign interface Ten-GigabitEthernet 1/0/1 to VLAN 10 as an untagged member.

[SwitchA-Ten-GigabitEthernet1/0/1] port hybrid vlan 10 untagged

# Assign interface Ten-GigabitEthernet 1/0/1 to VLAN 20 as a tagged member.

[SwitchA-Ten-GigabitEthernet1/0/1] port hybrid vlan 20 tagged

# Set the PVID to VLAN 10 for interface Ten-GigabitEthernet 1/0/1.

[SwitchA-Ten-GigabitEthernet1/0/1] port hybrid pvid vlan 10

[SwitchA-Ten-GigabitEthernet1/0/1] quit

# Configure interface Ten-GigabitEthernet 1/0/2 as a trunk port, and assign the interface to VLAN 20.

[SwitchA] interface ten-gigabitethernet 1/0/2

[SwitchA-Ten-GigabitEthernet1/0/2] port link-type trunk

[SwitchA-Ten-GigabitEthernet1/0/2] port trunk permit vlan 20

[SwitchA-Ten-GigabitEthernet1/0/2] quit

# Configure interface Ten-GigabitEthernet 1/0/3 as a trunk port, and assign the interface to VLAN 10.

[SwitchA] interface ten-gigabitethernet 1/0/3

[SwitchA-Ten-GigabitEthernet1/0/3] port link-type trunk

[SwitchA-Ten-GigabitEthernet1/0/3] port trunk permit vlan 10

[SwitchA-Ten-GigabitEthernet1/0/3] quit

c. Configure DCBX:

# Enable LLDP globally.

[SwitchA] lldp global enable

# Create Layer 2 ACL 4000.

[SwitchA] acl mac 4000

# Configure ACL 4000 to permit FCoE packets (whose protocol number is 0x8906) and FIP protocol packets (whose protocol number is 0x8914) to pass through.

[SwitchA-acl-mac-4000] rule 0 permit type 8906 ffff

[SwitchA-acl-mac-4000] rule 5 permit type 8914 ffff

[SwitchA-acl-mac-4000] quit

# Create a class named DCBX, specify the operator of the class as OR, and use ACL 4000 as the match criterion of the class.

[SwitchA] traffic classifier DCBX operator or

[SwitchA-classifier-DCBX] if-match acl 4000

[SwitchA-classifier-DCBX] quit

# Create a behavior named DCBX, and configure the behavior to mark packets with 802.1p priority value 3.

[SwitchA] traffic behavior DCBX

[SwitchA-behavior-DCBX] remark dot1p 3

[SwitchA-behavior-DCBX] quit

# Create a QoS policy named DCBX, associate class DCBX with traffic behavior DCBX in the QoS policy, and specify that the association apply to DCBX.

[SwitchA] qos policy DCBX

[SwitchA-qospolicy-DCBX] classifier DCBX behavior DCBX mode dcbx

[SwitchA-qospolicy-DCBX] quit

# Enable LLDP and DCBX TLV advertising on interface Ten-GigabitEthernet 1/0/1.

[SwitchA] interface ten-gigabitethernet 1/0/1

[SwitchA-Ten-GigabitEthernet1/0/1] lldp enable

[SwitchA-Ten-GigabitEthernet1/0/1] lldp tlv-enable dot1-tlv dcbx

# Apply QoS policy DCBX to the outgoing traffic of Ten-GigabitEthernet 1/0/1.

[SwitchA-Ten-GigabitEthernet1/0/1] qos apply policy DCBX outbound

d. Configure PFC:

# Enable PFC in auto mode on interface Ten-GigabitEthernet 1/0/1.

[SwitchA-Ten-GigabitEthernet1/0/1] priority-flow-control auto

# Enable PFC for 802.1p priority 3 on the interface.

[SwitchA-Ten-GigabitEthernet1/0/1] priority-flow-control no-drop dot1p 3

# Configure the interface to trust the 802.1p priority carried in incoming packets.

[SwitchA-Ten-GigabitEthernet1/0/1] qos trust dot1p

[SwitchA-Ten-GigabitEthernet1/0/1] quit

# Forcibly enable PFC on interface Ten-GigabitEthernet 1/0/2.

[SwitchA] interface ten-gigabitethernet 1/0/2

[SwitchA-Ten-GigabitEthernet1/0/2] priority-flow-control enable

# Enable PFC for 802.1p priority 3 on the interface.

[SwitchA-Ten-GigabitEthernet1/0/2] priority-flow-control no-drop dot1p 3

# Configure the interface to trust the 802.1p priority carried in incoming packets.

[SwitchA-Ten-GigabitEthernet1/0/2] qos trust dot1p

[SwitchA-Ten-GigabitEthernet1/0/2] quit

e. Configure ETS:

# Configure the 802.1p-local priority mapping table as follows:

- Map 802.1p priority value 3 to local precedence 1.

- Map the other 802.1p priorities to local precedence 0.

[SwitchA] qos map-table dot1p-lp

[SwitchA-maptbl-dot1p-lp] import 3 export 1

[SwitchA-maptbl-dot1p-lp] import 0 1 2 4 5 6 7 export 0

[SwitchA-maptbl-dot1p-lp] quit

# Configure WRR on interface Ten-GigabitEthernet 1/0/1 as follows:

- Assign 50% of the interface bandwidth to the FCoE traffic (traffic assigned to queue 1).

- Assign 50% of the interface bandwidth to the LAN traffic (traffic assigned to queue 0).

[SwitchA] interface ten-gigabitethernet 1/0/1

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr byte-count

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr 1 group 1 byte-count 1

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr 0 group 1 byte-count 1

# Assign the other queues to the SP group on interface Ten-GigabitEthernet 1/0/1.

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr 2 group sp

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr 3 group sp

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr 4 group sp

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr 5 group sp

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr 6 group sp

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr 7 group sp

[SwitchA-Ten-GigabitEthernet1/0/1] quit

f. Configure FCoE:

# Configure the switch to operate in FCF mode and create VSAN 10.

[SwitchA] fcoe-mode fcf

[SwitchA] vsan 10

[SwitchA-vsan10] quit

# Create interface VFC 1, and configure the mode of VFC 1 as F.

[SwitchA] interface vfc 1

[SwitchA-Vfc1] fc mode f

# Bind VFC 1 to interface Ten-GigabitEthernet 1/0/1, and assign VFC 1 to VSAN 10 as a trunk port.

[SwitchA-Vfc1] bind interface ten-gigabitethernet 1/0/1

[SwitchA-Vfc1] port trunk vsan 10

[SwitchA-Vfc1] quit

# Create interface VFC 2, and configure the mode of VFC 2 as E.

[SwitchA] interface vfc 2

[SwitchA-Vfc2] fc mode e

# Bind VFC 2 to interface Ten-GigabitEthernet 1/0/2, and assign VFC 2 to VSAN 10 as a trunk port.

[SwitchA-Vfc2] bind interface ten-gigabitethernet 1/0/2

[SwitchA-Vfc2] port trunk vsan 10

[SwitchA-Vfc2] quit

# Enable FCoE for VLAN 20 and map VLAN 20 to VSAN 10.

[SwitchA] vlan 20

[SwitchA-vlan20] fcoe enable vsan 10

[SwitchA-vlan20] quit

# Permit members in the default zone to access each other. By default, the server and disk belong to the default zone and members in the default zone are not permitted to access each other. For more information about zones, see "Configuring FC zones."

[SwitchA] vsan 10

[SwitchA-vsan10] zone default-zone permit

[SwitchA-vsan10] quit

2. Configure Switch B:

a. Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchB> system-view

[SwitchB] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchB] save

[SwitchB] quit

<SwitchB> reboot

b. Configure VLANs and interfaces:

# Create VLAN 20, which is intended to transmit storage traffic.

<SwitchB> system-view

[SwitchB] vlan 20

[SwitchB-vlan20] quit

# Configure interface Ten-GigabitEthernet 1/0/2 as a trunk port, and assign the interface to VLAN 20.

[SwitchB] interface ten-gigabitethernet 1/0/2

[SwitchB-Ten-GigabitEthernet1/0/2] port link-type trunk

[SwitchB-Ten-GigabitEthernet1/0/2] port trunk permit vlan 20

[SwitchB-Ten-GigabitEthernet1/0/2] quit

c. Configure PFC:

# Forcibly enable PFC on interface Ten-GigabitEthernet 1/0/2.

[SwitchB] interface ten-gigabitethernet 1/0/2

[SwitchB-Ten-GigabitEthernet1/0/2] priority-flow-control enable

# Enable PFC for 802.1p priority 3 on the interface.

[SwitchB-Ten-GigabitEthernet1/0/2] priority-flow-control no-drop dot1p 3

# Configure the interface to trust the 802.1p priority carried in incoming packets.

[SwitchB-Ten-GigabitEthernet1/0/2] qos trust dot1p

[SwitchB-Ten-GigabitEthernet1/0/2] quit

d. Configure FCoE:

# Configure the switch to operate in FCF mode and create VSAN 10.

<SwitchB> system-view

[SwitchB] fcoe-mode fcf

[SwitchB] vsan 10

[SwitchB-vsan10] quit

# Create interface VFC 2, and configure the mode of VFC 2 as E.

[SwitchB] interface vfc 2

[SwitchB-Vfc2] fc mode e

# Bind VFC 2 to interface Ten-GigabitEthernet 1/0/2, and assign VFC 2 to VSAN 10 as a trunk port.

[SwitchB-Vfc2] bind interface ten-gigabitethernet 1/0/2

[SwitchB-Vfc2] port trunk vsan 10

[SwitchB-Vfc2] quit

# Enable FCoE for VLAN 20 and map VLAN 20 to VSAN 10.

[SwitchB] vlan 20

[SwitchB-vlan20] fcoe enable vsan 10

[SwitchB-vlan20] quit

[SwitchB] vsan 10

[SwitchB-vsan10] zone default-zone permit

[SwitchB-vsan10] quit

Configuring VSANs

The virtual storage area network (VSAN) technology breaks a physical SAN into multiple VSANs, and provides more secure, reliable, and flexible services.

Devices in a VSAN cannot get information about any other VSAN and devices in any other VSAN. Each VSAN performs the following operations independently:

· Selecting a principal switch.

· Assigning domain IDs.

· Running routing protocols.

· Maintaining routing table and FIB table.

· Providing services.

The VSAN technology delivers the following benefits:

· Improved security—VSANs are isolated from each other.

· Improved scalability—Each VSAN independently runs and provides services. Different VSANs can use the same address space so that network scalability is improved.

· Flexibility—You can assign interfaces to different VSANs without changing the physical connections of the SAN.

VSAN fundamentals

VFC interfaces in a VSAN can only work as trunk ports. A trunk port can belong to multiple VSANs.

Trunk VSAN in an FC network

The trunk VSAN technology implements logical isolation among VSANs. A trunk VSAN adds a Virtual Fabric Tagging Header (VFT_Header, also known as VSAN tag) to the FC frames. The VFT_Header contains a VF_ID (also known as "VSAN ID") field to indicate the VSAN of the FC frames. In this way, FC frames with different VF_IDs are contained in their respective VSANs, and different VSANs cannot communicate with each other. The trunk VSAN implements physical connectivity and logical isolation in the network.

Figure 16 shows a typical trunk VSAN.

· The F_Ports in blue on switches are configured as access ports and assigned to VSAN 1.

· The F_Ports in purple are configured as access ports and assigned to VSAN 2.

· The E_Ports are configured with trunk VSANs 1 and 2.

When servers read the disks, the N_Ports of different servers send FC frames without VFT_Headers to the F_Ports on FC switch Switch A. Switch A searches for the outgoing interfaces in the FIB table of the VSAN that each F_Port belongs to. These F_Ports use the same E_Port as the outgoing interface. When the frames are forwarded out of the E_Port, they are tagged with the VFT_Header of VSAN 1 and VSAN 2. Then, the frames travel across multiple VSAN-capable switches to the E_Port of FC switch Switch B.

According to the VFT_Headers, Switch B searches for the outgoing interfaces in the FIB tables of the VSANs, and forwards them to the F_Ports. Then, the F_Ports remove the VFT_Headers and send the frames to the N_Ports of different disk devices. The frames from the disk devices to the server are processed in the same way and finally reach the servers.

Figure 16 Trunk VSAN network

During the transmission process, VFT_Headers are added to and removed from the frames. A switch can use the same physical interface to support multiple VSANs. The trunk VSAN technology reduces the number of physical connections, actually implementing logical isolation in a physical network.

Trunk VSAN in an FCoE network

FCoE carries FC over Ethernet. In an FCoE network:

· VSANs in FC must be mapped to VLANs as configured by the user.

· The FIB table for a VSAN is also stored on the relevant VLAN.

FCoE frames use VLAN_Header in place of VFT_Header in FC frames and are forwarded based on the VLAN ID in VLAN_Header.

A VFC interface can only work as a trunk port. The bound Ethernet interface must also be configured as a trunk port. Its trunk VLAN list must include the VLANs mapped to each VSAN in the trunk VSAN list of the VFC interface. An FCoE frame transmitted from a VFC interface can use the VLAN ID in VLAN_Header to identify the VLAN to which it belongs.

Creating a VSAN

Initially, only the default VSAN (VSAN 1) exists. You cannot create or delete VSAN 1. You can create VSANs 2 to 3839.

To create a VSAN:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Create a VSAN and enter VSAN view.	vsan vsan-id	By default, only the default VSAN (VSAN 1) exists, and the name of VSAN 1 is VSAN0001.

Configuring a trunk VSAN

A VFC interface can be assigned to multiple VSANs as a trunk port.

If you assign a VFC interface to VSANs as a trunk port multiple times, the new configuration does not overwrite the old configurations. The final trunk VSAN list is the union of all the VSANs to which you have assigned the VFC interface.

To assign a VFC interface to the specified VSANs as a trunk port:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VFC interface view.	interface vfc interface-number	N/A
3. Assign the VFC interface to the specified VSANs as a trunk port so that the interface allows the specified VSANs to pass through.	port trunk vsan vsan-id-list	By default, a VFC interface does not belong to any VSAN (including VSAN 1) as a trunk port. You can assign a VFC interface to a nonexistent VSAN as a trunk port.

Displaying and maintaining VSANs

Execute display commands in any view.

Task	Command
Display the member ports of VSANs.	display vsan [ vsan-id ] port-member

VSAN configuration example

Network requirements

As shown in Figure 17, configure the VSANs to meet the following requirements:

· Server A can read and write only the data of Disk A and Disk B.

· Server B can read and write only the data of Disk C.

Figure 17 Network diagram

Configuration procedure

This section describes only the VSAN configurations.

1. Configure Switch A:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchA> system-view

[SwitchA] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchA] save

[SwitchA] quit

<SwitchA> reboot

# Configure the switch to operate in FCF mode.

<SwitchA> system-view

[SwitchA] fcoe-mode fcf

# Create VSAN 10 and VSAN 20.

[SwitchA] vsan 10

[SwitchA-vsan10] quit

[SwitchA] vsan 20

[SwitchA-vsan20] quit

# Create interface VFC 1.

[SwitchA] interface vfc 1

# Configure the mode of VFC 1 as F.

[SwitchA-Vfc1] fc mode f

# Bind VFC 1 to interface Ten-GigabitEthernet 1/0/1.

[SwitchA-Vfc1] bind interface ten-gigabitethernet 1/0/1

# Assign VFC 1 to VSAN 10 as a trunk port.

[SwitchA-Vfc1] port trunk vsan 10

[SwitchA-Vfc1] quit

# Configure Ten-GigabitEthernet 1/0/1 as a trunk port, and assign the port to VLAN 10.

[SwitchA] interface ten-gigabitethernet 1/0/1

[SwitchA-Ten-GigabitEthernet1/0/1] port link-type trunk

[SwitchA-Ten-GigabitEthernet1/0/1] port trunk permit vlan 10

[SwitchA-Ten-GigabitEthernet1/0/1] quit

# Create interface VFC 2.

[SwitchA] interface vfc 2

# Configure the mode of VFC 2 as F.

[SwitchA-Vfc2] fc mode f

# Bind VFC 2 to interface Ten-GigabitEthernet 1/0/2.

[SwitchA-Vfc2] bind interface ten-gigabitethernet 1/0/2

# Assign VFC 2 to VSAN 20 as a trunk port.

[SwitchA-Vfc2] port trunk vsan 20

[SwitchA-Vfc2] quit

# Configure Ten-GigabitEthernet 1/0/2 as a trunk port, and assign the port to VLAN 20.

[SwitchA] interface ten-gigabitethernet 1/0/2

[SwitchA-Ten-GigabitEthernet1/0/1] port link-type trunk

[SwitchA-Ten-GigabitEthernet1/0/1] port trunk permit vlan 20

[SwitchA-Ten-GigabitEthernet1/0/1] quit

# Create interface VFC 4.

[SwitchA] interface vfc 4

# Configure the mode of VFC 4 as E.

[SwitchA-Vfc4] fc mode e

# Bind VFC 4 to interface Ten-GigabitEthernet 1/0/4.

[SwitchA-Vfc4] bind interface ten-gigabitethernet 1/0/4

# Assign VFC 4 to VSANs 10 and 20 as a trunk port.

[SwitchA-Vfc4] port trunk vsan 10 20

[SwitchA-Vfc4] quit

# Configure Ten-GigabitEthernet 1/0/4 as a trunk port, and assign the port to VLANs 10 and 20.

[SwitchA] interface ten-gigabitethernet 1/0/4

[SwitchA-Ten-GigabitEthernet1/0/4] port link-type trunk

[SwitchA-Ten-GigabitEthernet1/0/4] port trunk permit vlan 10 20

[SwitchA-Ten-GigabitEthernet1/0/4] quit

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 10.

[SwitchA] vlan 10

[SwitchA-vlan10] fcoe enable vsan 10

[SwitchA-vlan10] quit

# Enable FCoE for VLAN 20 and map VLAN 20 to VSAN 20.

[SwitchA] vlan 20

[SwitchA-vlan20] fcoe enable vsan 20

[SwitchA-vlan20] quit

[SwitchA] vsan 10

[SwitchA-vsan10] zone default-zone permit

[SwitchA-vsan10] quit

[SwitchA] vsan 20

[SwitchA-vsan20] zone default-zone permit

[SwitchA-vsan20] quit

2. Configure Switch B in the same way Switch A is configured.

Verifying the configuration

# Display member interfaces of each VSAN on switches, for example, Switch A.

[SwitchA] display vsan port-member

VSAN 1:

Access Ports:

Trunk Ports:

VSAN 10:

Access Ports:

Trunk Ports:

Vfc1

Vfc4

VSAN 20:

Access Ports:

Trunk Ports:

Vfc2

Vfc4

Building a fabric

Overview

A fabric transmits data for servers and disk devices. When building a fabric, you must perform the following tasks:

· Assign a domain ID to each FCF switch in the fabric.

· Assign an FC address to each node connected to the fabric.

You can build a fabric through one of the following modes:

· Static mode—You must manually assign domain IDs to all switches in the network. Then, each switch assigns FC addresses to the N_Ports connected to it. The static mode avoids network flapping, but it is applicable only to simple, small-sized networks.

· Dynamic mode—A principal switch is automatically elected to assign domain IDs to all switches in the network. Then, each switch assigns FC addresses to the N_Ports connected to it. The dynamic mode enables centralized network management and is applicable to large-sized networks.

Figure 18 Fabric building workflows

Principal switch selection

During the dynamic fabric building process, it is the principal switch that assigns domain IDs to all switches in the network.

The switch with the highest priority (smallest priority value) is selected as the principal switch. When multiple switches have the same priority, the switch with the smallest WWN is selected.

The principal switch selection process is as follows:

1. When the principal switch selection starts, each switch performs the following operations:

? Considers itself to be the principal switch.

? Records itself in the principal switch information.

? Starts the Principal Switch Selection Timer (PSST), which is 10 seconds.

2. Before the PSST times out, the switches exchange packets carrying the principal switch information to select a principal switch. On receiving such a packet, a switch compares the priority and WWN of the principal switch carried in the packet against those locally recorded. The switch replaces the locally-recorded principal switch information with the information recorded in the packet. It notifies the other switches when any of the following conditions exist:

? The priority carried in the packet is higher.

? The priority in the packet is the same and the WWN is smaller.

Finally, all switches in the network make an agreement on the principal switch.

3. When the PSST times out, if the locally-recorded principal switch information is the local switch, the switch becomes the principal switch.

After the principal switch is selected, the WWN of the principal switch becomes the fabric name.

NOTE:

During the process, if a switch receives a packet that updates the principal switch information, the switch must record the E_Port receiving the packet. The link relevant to this E_Port is called the "upstream principal link."

Domain ID assignment

A domain represents a switch and all N_Ports connected to the switch. Each domain must have a domain ID.

Domain IDs can be manually configured or automatically assigned for FCF switches.

· When you manually configure static domain IDs, you must assign a unique domain ID to each switch in the fabric.

· When domain IDs are dynamically assigned, the fabric configuration process is performed to select a principal switch and assign domain IDs. After the principal switch is selected, the principal switch assigns domain IDs to all switches in the fabric. After the fabric configuration process, each switch has a unique domain ID.

The dynamic domain ID assignment process is as follows:

1. The principal switch assigns a domain ID to itself.

? If you have configured a domain ID on the principal switch, the principal switch assigns itself the configured domain ID.

? If you have not configured a domain ID on the principal switch, the principal switch assigns itself a random domain ID.

2. The principal switch notifies its downstream switches to request domain IDs from it.

3. A downstream switch requests a domain ID from the principal switch.

If the downstream switch is configured with a domain ID, it requests the configured domain ID from the principal switch.

4. The principal switch assigns a domain ID according to the following rules:

? If the downstream switch requests a desired domain ID that is available, the principal switch assigns the domain ID to the downstream switch.

? The principal switch assigns a random domain ID to the downstream switch when one of the following conditions exists:

- The downstream switch does not request a desired domain ID.

- The desired domain ID is not available.

? If all available domain IDs have been assigned, the principal switch notifies the downstream switch that no domain ID can be assigned to it.

5. After the downstream switch receives the domain ID assignment notification from the principal switch, it works according to the following rules:

? The downstream switch isolates its upstream principal link and brings down the relevant interface when any of the following conditions exist:

- The downstream switch has been configured with a static domain ID different from the one assigned by the principal switch.

- The principal switch notifies the downstream switch that no domain ID can be assigned.

For more information about domain ID types, see "Configuring a domain ID for a switch."

? Otherwise, the downstream switch performs the following operations:

- Accepts the domain ID assigned by the principal switch and records it in a hidden file.

If no new domain ID is configured when the downstream switch requests a domain ID next time, the recorded domain ID is sent in the request. To avoid writing domain IDs to the hidden file frequently, the switch starts a 5-second timer upon a domain ID change. The switch records the assigned domain ID in the hidden file when the timer expires. If a reboot is required after a domain ID change, reboot the switch 5 seconds after the domain ID change..

- Notifies the nearby downstream switch to request a domain ID from the principal switch.

6. Steps 2 through 5 are repeated until all downstream switches have been assigned domain IDs.

NOTE:

During the dynamic domain ID assignment process, if a switch receives the domain ID request on an E_Port, the switch must record the E_Port. The link relevant to this E_Port is called the "downstream principal link."

FC address assignment

After a switch obtains a domain ID, it can assign FC addresses to N_Ports directly connected.

The Domain_ID field in the FC address is the domain ID of the switch, and it does not need assignment.

The switch assigns FC addresses according to the following rules:

· If you have configured a persistent FC address entry for the WWN of an N_Port and an FC address, the switch assigns the bound FC address in the entry to the N_Port.

· If you have configured a desired FC address for an N_Port on the node, the switch assigns the desired FC address, if available.

· The switch assigns the smallest available area ID and port ID to the N_Port when one of the following conditions exists:

? The N_Port itself does not have a desired or bound FC address.

? The desired FC address is unavailable.

Fabric building configuration task list

As a best practice, use dynamic mode for large networks to facilitate centralized management and use static mode for small networks to avoid network flapping.

Building a fabric statically

Tasks at a glance	Remarks
(Required.) Enabling or disabling the fabric configuration feature	To statically build a fabric, you must disable the fabric configuration feature.
(Required.) Setting a fabric name	When statically building a fabric, you must manually configure the fabric name, and make sure all switches in the fabric are configured with the same fabric name.
(Optional.) Configuring the allowed domain ID list	N/A
(Required.) Configuring a domain ID for a switch	When statically building a fabric, you must manually configure a domain ID for each switch.
(Optional.) Configuring the persistent FC address feature	N/A
(Optional.) Setting the maximum number of logged-in nodes	N/A
(Optional.) Setting fabric timers	N/A
(Optional.) Configuring RSCN aggregation	N/A
(Optional.) Configuring and obtaining FC4 information of nodes	N/A
(Optional.) Configuring Smart SAN	N/A

Building a fabric dynamically

Tasks at a glance	Remarks
(Required.) Enabling or disabling the fabric configuration feature	To dynamically build a fabric, you must enable the fabric configuration feature.
(Optional.) Setting the switch priority	Principal switch selection relies on the switch priority.
(Optional.) Configuring the allowed domain ID list	N/A
(Optional.) Configuring a domain ID for a switch	When dynamically building a fabric, you can configure desired domain IDs for switches.
(Optional.) Configuring the persistent FC address feature	N/A
(Optional.) Setting the maximum number of logged-in nodes	N/A
(Optional.) Setting fabric timers	N/A
(Optional.) Configuring the fabric reconfiguration feature	N/A
(Optional.) Configuring a VFC interface to reject incoming RCF requests	N/A
(Optional.) Enabling SNMP notifications	N/A
(Optional.) Configuring RSCN aggregation	N/A
(Optional.) Configuring and obtaining FC4 information of nodes	N/A
(Optional.) Configuring Smart SAN	N/A

Enabling or disabling the fabric configuration feature

After being enabled with the fabric configuration feature, FCF switches exchange messages to select the principal switch. Then the principal switch dynamically assigns domain IDs to all switches in the fabric.

· To dynamically build a fabric, you must enable the fabric configuration feature on switches.

· To statically build a fabric, you must disable the fabric configuration feature on switches and manually configure domain IDs for the switches.

To enable or disable the fabric configuration feature:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Enable or disable the fabric configuration feature for the VSAN.	· Enable the fabric configuration feature: domain configure enable · Disable the fabric configuration feature: undo domain configure enable	By default, the fabric configuration feature is enabled. Enable or disable the feature for all switches in the VSAN as required.

Setting a fabric name

You can set a fabric name for each VSAN on an FCF switch. The default fabric name for a VSAN is the WWN of the switch.

Set the fabric names only when you build a fabric statically. Make sure the same fabric name is set for a VSAN on all switches in the fabric. In a dynamically built fabric, each VSAN uses the WWN of the principal switch as the fabric name.

To set a fabric name:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Configure a fabric name.	fabric-name name	By default, the WWN of the switch in a VSAN is used as the fabric name of that VSAN.

Setting the switch priority

The priority value for FCF switches is in the range of 1 to 254. The smaller the value, the higher the priority. The FCF switch with the highest priority will be selected as the principal switch.

The priority is configured on a per-VSAN basis, and one FCF switch can have different priorities in different VSANs.

In a stable fabric, the configured priority does not take effect immediately. Therefore, the running priority of a switch might be different from the configured priority. To validate the configured priority, use the domain restart disruptive command to perform a disruptive reconfiguration. After a disruptive reconfiguration, the running priority might be different from the configured priority, depending on the configured priority value, as shown in Table 3.

Table 3 Configured priority and running priority mappings

Configured priority	Running priority
≤ 2	· Principal switch—Same as the configured priority. · Non-principal switch—3.
> 2	· Principal switch—2. · Non-principal switch—Same as the configured priority.

Configured priority

Running priority

≤ 2

· Principal switch—Same as the configured priority.

· Non-principal switch—3.

> 2

· Principal switch—2.

· Non-principal switch—Same as the configured priority.

To set the switch priority:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Set the switch priority in the VSAN.	priority value	The default setting is 128.

Configuring the allowed domain ID list

Configuring the allowed domain ID list has an effect on switches as follows:

· Principal switch—The principal switch can only assign domains IDs included in the allowed domain ID list. The list must include all domain IDs that are already assigned or manually configured. Otherwise, the list configuration will fail.

· Non-principal switch—The manually configured domain ID must be included in the allowed domain ID list. Otherwise, the domain ID configuration will fail. The principal switch must assign the switch a domain ID included in the allowed domain ID list. Otherwise, the switch refuses the assigned domain ID and isolates its interface connected to the principal switch. If the runtime domain ID for a switch is not included in the list, the list configuration will fail.

As a best practice, configure the same allowed domain ID list for all switches in a VSAN.

To configure the allowed domain ID list:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Configure the allowed domain ID list for the VSAN.	allowed-domain-id domain-id-list	By default, the allowed domain IDs are 1 to 239.

Configuring a domain ID for a switch

In different scenarios, the configured domain ID has different meanings.

· In a statically built fabric, the configured domain ID is the actual domain ID of the switch.

· In a dynamically built fabric, the configured domain ID is desired by the switch but might not be the actual domain ID.

When you statically build a fabric, you must manually configure a domain ID for each switch.

When you dynamically build a fabric, you can configure a desired domain ID for a switch. However, the domain ID assigned to the switch might not be the desired one.

The configured domain ID can be static type or preferred type.

· In a statically built fabric, the two types make no difference.

· In a dynamically built fabric, when a non-principal switch fails to obtain the desired domain ID from the principal switch, the following rules apply:

? If the desired domain ID is preferred, the non-principal switch can use another domain ID assigned by the principal switch.

? If the desired domain ID is static, the non-principal switch will isolate the upstream link and refuse other domain IDs assigned by the principal switch.

As a best practice, configure domain IDs of the same type for all switches in a VSAN.

To configure a domain ID for a switch:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Configure a domain ID for the switch.	domain-id domain-id { preferred \| static }	By default, the domain ID of a switch is 0 and is of the preferred type.

Configuring the persistent FC address feature

The persistent FC address feature binds WWNs of N_Ports or NP_Ports to FC addresss in persistent FC address entries. When an N_Port or NP_Port logs in to the fabric for the first time or across switch reboots, it is assigned the bound FC address. Persistent FC address entries include the following types:

· Static entries—Can only be manually configured.

· Dynamic entries—Can be manually configured or dynamically learned. When an N_Port or NP_Port logs in and is assigned an FC address, the system learns the WWN and binds the assigned FC address to the WWN. The N_Port or NP_Port is assigned the bound FC address across device reboots if you have saved the configuration.

A WWN can be bound to only one FC address, and vice versa. If the WWN has been assigned another FC address or the FC address has been assigned to another WWN, a persistent FC address entry cannot be created.

To configure the persistent FC address feature:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Enable the persistent FC address feature in the VSAN.	fcid persistent enable	By default, the persistent FC address feature is enabled.
4. (Optional.) Configure a persistent FC address entry.	wwn wwn-value fcid fcid-value [ dynamic ]	By default, no user-configured persistent FC address entries exist. Manually configured persistent FC address entries take effect only when the persistent FC address feature is enabled.

Setting the maximum number of logged-in nodes

This feature is available only on switches operating in FCF mode.

Logged-in nodes consume ACL resources. To save ACL resources, you can set the maximum number of logged-in nodes allowed in a VSAN. The number of logged-in nodes is the number of directly connected NPV switches plus the number of logged-in servers and disks.

If the number of logged-in nodes exceeds the set maximum number, no logged-in nodes will be logged out. However, any new nodes cannot log in. You can manually log out nodes by shutting down interfaces connected to these nodes.

The maximum number of logged-in nodes allowed depends on both this feature and hardware ACL resources. When hardware ACL resources are exhausted, any new nodes cannot log in.

To set the maximum number of logged-in nodes:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Set the maximum number of logged-in nodes allowed in the VSAN.	fc login-limit max-number	By default, no maximum number is configured.

Setting fabric timers

The fabric operation involves the following timers:

· Distributed service timeout period.

· Error detection timeout period.

· Resource allocation timeout period.

For more information about these timers, see FC-related protocols and standards.

You can set fabric timers in one of the following views:

· System view—The configuration takes effect on all VSANs.

· VSAN view—The configuration takes effect only on the VSAN.

If you set a fabric timer in both system view and VSAN view, the setting in VSAN view applies to the VSAN.

Setting fabric timers in system view

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Set the global distributed service timeout period.	fc timer distributed-services value	The default setting is 5000 milliseconds.
3. Set the global error detection timeout period.	fc timer error-detect value	The default setting is 2000 milliseconds.
4. Set the global resource allocation timeout period.	fc timer resource-allocation value	The default setting is 10000 milliseconds.

Setting fabric timers in VSAN view

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Set the distributed service timeout period for the VSAN.	timer distributed-services value	The default setting is 5000 milliseconds.
4. Set the error detection timeout period for the VSAN.	timer error-detect value	The default setting is 2000 milliseconds.
5. Set the resource allocation timeout period for the VSAN.	timer resource-allocation value	The default setting is 10000 milliseconds.

Configuring the fabric reconfiguration feature

IMPORTANT:

The fabric reconfiguration feature takes effects only when the fabric configuration feature is enabled.

The fabric reconfiguration occurs in one of the following situations:

· A network reconstruction (for example, two fabrics are merged).

· An external intervention (for example, the administrator uses a command to initiate reconfiguration).

The fabric reconfiguration triggers principal switch selection, domain ID assignment, and FC address assignment throughout the fabric.

The fabric reconfiguration includes the following types:

· Disruptive reconfiguration—Floods Reconfigure Fabric (RCF) frames throughout the fabric, and notifies all switches to perform a disruptive reconfiguration. During the reconfiguration procedure, each switch clears all data and performs renegotiation. Data transmission in the fabric is disrupted.

· Nondisruptive reconfiguration—Floods Build Fabric (BF) frames throughout the fabric, and notifies all switches to perform a nondisruptive reconfiguration. During the reconfiguration procedure, each switch tries to save the last running data for its domain ID to remain unchanged. Thus, data transmission in the fabric is not disrupted.

Depending on the triggering conditions, the fabric reconfiguration includes auto reconfiguration and manual reconfiguration.

· When two fabrics are merged:

? The switches automatically perform a disruptive reconfiguration if the domain ID lists overlap.

? The system automatically performs a nondisruptive reconfiguration when the following conditions exist:

- The principal switch information of the two fabrics is different.

- The domain ID lists are not empty or do not overlap.

? You can manually initiate a disruptive reconfiguration to trigger the fabric reconfiguration if ports are isolated and priority values of switches are modified.

· When the principal switch in a fabric is down, the system automatically performs a nondisruptive reconfiguration.

Enabling the automatic reconfiguration feature

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Enable the automatic fabric reconfiguration feature.	domain auto-reconfigure enable	By default, the automatic fabric reconfiguration feature is disabled.

Manually initiating a fabric reconfiguration

Step	Command
1. Enter system view.	system-view
2. Enter VSAN view.	vsan vsan-id
3. Manually initiate a fabric reconfiguration.	domain restart [ disruptive ]

Configuring a VFC interface to reject incoming RCF requests

In a stable fabric, to avoid unnecessary disruptive reconfigurations, you can configure a VFC interface to reject RCF requests received in a VSAN. With this feature, the switch replies with a reject message and isolates the interface that receives the RCF request.

To configure a VFC interface to reject received RCF requests:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VFC interface view.	interface vfc interface-number	N/A
3. Configure the VFC interface to reject the RCF requests received in a VSAN.	fc domain rcf-reject vsan vsan-id	By default, a VFC interface does not reject received RCF requests.

Enabling SNMP notifications

After you enable SNMP notifications for the fabric module or name service module, that module generates notifications for important events and sends the notifications to the SNMP module. For more information about SNMP notifications, see Network Management and Monitoring Configuration Guide.

To enable SNMP notifications:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enable SNMP notifications for the fabric module.	snmp-agent trap enable fc-fabric [ domain-id-change \| fabric-change ] *	By default, SNMP notifications are disabled for the fabric module.
3. Enable SNMP notifications for the name service module.	snmp-agent trap enable fc-name-service [ login \| logout ] *	By default, SNMP notifications are disabled for the name service module.

Configuring RSCN aggregation

RSCN

An FCF switch uses a name service database to store information about registered nodes on the local switch and on remote switches in the fabric. The switch sends Registered State Change Notifications (RSCNs) to inform node information changes (node registration, node deregistration, or registration information change). An RSCN includes only the FC address of the node where the change occurred.

When a change occurs, the switch sends ELS_RSCNs to its concerned registered nodes and SW-RSCNs to all reachable switches in the fabric. After receiving an RSCN, a switch or node automatically sends a name service query to obtain the new information. The switch receiving an RSCN also sends ELS_RSCNs to notify their concerned registered nodes. As a result, the changed information is notified and updated throughout the fabric.

NOTE:

· Support for SW-RSCNs depends on the ESS negotiation between switches.

· Concerned registered nodes refer to the nodes that have sent SCR requests to the switch for receiving RSCNs. Only these registered nodes can receive and respond to ELS_RSCNs.

RSCN aggregation

If changes occur on multiple nodes at the same time, the switch quickly sends multiple ELS_RSCNs for each change to the concerned registered nodes. This can cause a sharp decline in transmission and processing performance.

RSCN aggregation can alleviate the problem by using an RSCN aggregation timer. If multiple changes occur within the RSCN aggregation timer, the switch sends the FC addresses of the nodes with changes in one RSCN.

Configuration procedure

As a best practice, enable RSCN aggregation and set the same timer value on all switches in a VSAN. The RSCN aggregation timer takes effect only when RSCN aggregation is enabled.

To configure RSCN aggregation:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Enable RSCN aggregation.	rscn aggregation enable	By default, RSCN aggregation is disabled.
4. Set the RSCN aggregation timer.	rscn aggregation timer value	The default setting is 2000 ms. You can adjust this timer to control the frequency the switch responds to node information changes based on switch performance.

Configuring and obtaining FC4 information of nodes

After a node registers with a switch through a FLOGI, the node sends a name service registration request to the switch to register extended information, including FC4 information.

FC4 information includes the following fields to describe the FC4-layer protocol supported by a node and the feature of the supported protocol.

· FC4-Type—FC4-layer protocol supported by a node, including SCSI-FCP, IP, SNMP, and NPV.

· Feature—Feature of the supported FC4-layer protocol. Each FC4-layer protocol can include one of the four Features and defines the meaning of each Feature.

Before communicating with other nodes, a node obtains information about all nodes that support SCSI-FCP from the switch. You can use the display fc name-service database command to display the FC4 information of nodes in the name service database.

When registering extended information:

· A server registers SCSI-FCP for FC4-Type and Initiator for Feature.

· A disk device registers SCSI-FCP for FC4-Type and Target for Feature.

As a result, servers can determine the disk devices to send access requests after obtaining information about nodes supporting SCSI-FCP.

Enabling SCSI-FCP information autodiscovery

In some situations, for example, when a node logs out and then logs back in, the node does not register SCSI-FCP support. Therefore, the node does not have a Feature value. This might cause communication failure between the node and other nodes.

This feature enables the switch to automatically obtain SCSI-FCP support and the Feature value by sending a PRLI packet to the node that is logging in. Then, the switch stores the SCSI-FCP information in the name service database.

NOTE:

After this feature is enabled, nodes with older-model HBAs might not actively register name service information with the switch.

To enable SCSI-FCP information autodiscovery:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Enable SCSI-FCP information autodiscovery.	fc name-service auto-discovery	By default, SCSI-FCP information autodiscovery is enabled.

Configuring the default FC4 information for a node

The switch records the default FC4 information in the name service database for a node when the following conditions exist:

· The node does not register FC4 information.

· The switch fails to obtain SCSI-FCP information from the node.

The switch replaces the default FC4 information with the registered FC4 information or obtained SCSI-FCP information when any of the following events occur:

· A node registers FC4 information.

· The switch obtains the SCSI-FCP information.

The fc wwn default-fc4-type command can configure only one combination of FC4-Type and Feature at a time.

To configure the default FC4 information for a node:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Configure the default FC4 information for a node.	fc wwn wwn-value default-fc4-type { type-value feature feature-map \| scsi-fcp feature { feature-map \| both \| initiator \| target } }	By default, no default FC4 information is configured.

Configuring Smart SAN

Overview

Smart SAN is a SAN configuration and management solution that is designed for intelligence, simplicity, ease of maintenance, ease of diagnosis, and self-healing. Smart SAN simplifies user operations while increasing manageability for SANs. Smart SAN is deployed on all SAN network elements (storage devices, servers, and switches). A switch with Smart SAN enabled performs the following operations:

· Collects information about servers and storage devices for mutual discovery.

· Controls access between servers and storage devices, and automates zoning configuration.

The zoning configuration includes creating and deleting peer zones, adding members to peer zones, and adding peer zones to a zone set and activating the zone set.

· Collects diagnostic information about servers and storage devices by using Read Diagnostic Parameters (RDP) request packets for network monitoring and diagnosis.

· Controls automatic login of servers and storage devices.

Configuration procedure

Smart SAN can be configured for FC/FCoE and iSCSI. Smart SAN for iSCSI is not supported in the current software version.

After Smart SAN is enabled for FC/FCoE, the switch notifies the following modules to act accordingly:

· FDMI—This module performs the following operations:

a. Regularly sends RDP request packets to request diagnostic information about nodes.

b. Updates information about local ports.

c. Sends Add Diagnostic Parameters (ADP) packets to other switches to synchronize RDP database information.

· FC zone—This module automatically configures each VSAN to operate in enhanced zoning mode.

To configure Smart SAN:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enable Smart SAN.	smartsan enable [ fcoe \| iscsi ]	By default, Smart SAN is disabled.
3. Set the interval for sending RDP request packets.	rdp request-polling-interval interval	The default setting is 30 minutes. This command can be used only after Smart SAN is enabled for FC/FCoE.

Displaying and maintaining a fabric

Execute display commands in any view.

Task	Command
Display the domain information of the specified VSAN.	display fc domain [ vsan vsan-id ]
Display the list of domain IDs dynamically allocated in the specified VSAN.	display fc domain-list [ vsan vsan-id ]
Display fabric timers.	display fc timer [ distributed-services \| error-detect \| resource allocation ] [ vsan vsan-id ]
Display the local switch WWN.	display fc switch-wwn
Display node login information.	display fc login [ vsan vsan-id ] [ count ]
Display the SCR table for an N_Port.	display fc scr-table [ vsan vsan-id ] [ count ]
Display name service database information.	display fc name-service database [ vsan vsan-id [ fcid fcid ] ] [ verbose ] display fc name-service database [ vsan vsan-id ] count
Display ESS negotiation results.	display fc ess [ vsan vsan-id ]
Display FC address assignment information.	display fcid allocation [ vsan vsan-id ]
Display persistent FC address entries.	display fcid persistent [ unused ] [ vsan vsan-id ]
Display RDP database information.	display rdp database [ port-name port-name ]
Display the interval for sending RDP request packets.	display rdp request-polling-interval
Display Smart SAN status.	display smartsan status
Clear persistent FC address entries for offline WWNs.	reset fcid persistent [ static ] [ vsan vsan-id ]

Fabric building configuration examples

Static fabric building configuration example

Network requirements

As shown in Figure 19, use the static method to build a fabric.

Figure 19 Network diagram

Configuration procedure

This section describes only the fabric building configurations.

1. Configure Switch A:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchA> system-view

[SwitchA] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchA] save

[SwitchA] quit

<SwitchA> reboot

# Configure the switch to operate in FCF mode, and disable the fabric configuration feature in VSAN 1.

<SwitchA> system-view

[SwitchA] fcoe-mode fcf

[SwitchA] vsan 1

[SwitchA-vsan1] undo domain configure enable

# Configure a fabric name.

[SwitchA-vsan1] fabric-name 11:11:11:11:11:11:11:11

# Set the domain ID to 1.

[SwitchA-vsan1] domain-id 1 static

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

[SwitchA-vsan1] quit

# Create interface VFC 1, and configure it to operate in F mode.

[SwitchA] interface vfc 1

[SwitchA-Vfc1] fc mode f

# Bind VFC 1 to interface Ten-GigabitEthernet 1/0/1, and assign VFC 1 to VSAN 1 as a trunk port.

[SwitchA-Vfc1] bind interface ten-gigabitethernet1/0/1

[SwitchA-Vfc1] port trunk vsan 1

[SwitchA-Vfc1] quit

# Configure Ten-GigabitEthernet 1/0/1 as a trunk port, and assign the port to VLAN 20.

[SwitchA] vlan 20

[SwitchA-Vlan20] quit

[SwitchA] interface ten-gigabitethernet1/0/1

[SwitchA-Ten-GigabitEthernet1/0/1] port link-type trunk

[SwitchA-Ten-GigabitEthernet1/0/1] port trunk permit vlan 20

[SwitchA-Ten-GigabitEthernet1/0/1] quit

# Create interface VFC 2, and configure it to operate in E mode.

[SwitchA] interface vfc 2

[SwitchA-Vfc2] fc mode e

# Bind VFC 2 to interface Ten-GigabitEthernet 1/0/2, and assign VFC 2 to VSAN 1 as a trunk port.

[SwitchA-Vfc2] bind interface ten-gigabitethernet1/0/2

[SwitchA-Vfc2] port trunk vsan 1

[SwitchA-Vfc2] quit

# Configure Ten-GigabitEthernet 1/0/2 as a trunk port, and assign the port to VLAN 20.

[SwitchA] vlan 20

[SwitchA-Vlan20] quit

[SwitchA] interface ten-gigabitethernet1/0/2

[SwitchA-Ten-GigabitEthernet1/0/2] port link-type trunk

[SwitchA-Ten-GigabitEthernet1/0/2] port trunk permit vlan 20

[SwitchA-Ten-GigabitEthernet1/0/2] quit

# Enable FCoE for VLAN 20, and map VLAN 20 to VSAN 1.

[SwitchA] vlan 20

[SwitchA-vlan20] fcoe enable vsan 1

[SwitchA-vlan20] quit

# Configure members in the default zone to access each other. By default, the server and disk belong to the default zone and members in the default zone are not permitted to access each other. For more information about zones, see "Configuring FC zones."

[SwitchA] vsan 1

[SwitchA-vsan1] zone default-zone permit

[SwitchA-vsan1] quit

2. Configure Switch B:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchB> system-view

[SwitchB] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchB] save

[SwitchB] quit

<SwitchB> reboot

# Configure the switch to operate in FCF mode, and disable the fabric configuration feature in VSAN 1.

<SwitchB> system-view

[SwitchB] fcoe-mode fcf

[SwitchB] vsan 1

[SwitchB-vsan1] undo domain configure enable

# Configure a fabric name.

[SwitchA-vsan1] fabric-name 11:11:11:11:11:11:11:11

# Set the domain ID to 2.

[SwitchB-vsan1] domain-id 2 static

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

[SwitchB-vsan1] quit

# Create interface VFC 1, and configure it to operate in F mode.

[SwitchB] interface vfc 1

[SwitchB-Vfc1] fc mode f

# Bind VFC 1 to interface Ten-GigabitEthernet 1/0/1, and assign it to VSAN 1 as a trunk port.

[SwitchB-Vfc1] bind interface ten-gigabitethernet1/0/1

[SwitchB-Vfc1] port trunk vsan 1

[SwitchB-Vfc1] quit

# Configure Ten-GigabitEthernet 1/0/1 as a trunk port, and assign the port to VLAN 20.

[SwitchB] vlan 20

[SwitchB-Vlan20] quit

[SwitchB] interface ten-gigabitethernet1/0/1

[SwitchB-Ten-GigabitEthernet1/0/1] port link-type trunk

[SwitchB-Ten-GigabitEthernet1/0/1] port trunk permit vlan 20

[SwitchB-Ten-GigabitEthernet1/0/1] quit

# Create interface VFC 2, and configure it to operate in E mode.

[SwitchB] interface vfc 2

[SwitchB-Vfc2] fc mode e

# Bind VFC 2 to interface Ten-GigabitEthernet 1/0/2, and assign it to VSAN 1 as a trunk port.

[SwitchB-Vfc2] bind interface ten-gigabitethernet1/0/2

[SwitchB-Vfc2] port trunk vsan 1

[SwitchB-Vfc2] quit

# Configure Ten-GigabitEthernet 1/0/2 as a trunk port, and assign the port to VLAN 20.

[SwitchB] vlan 20

[SwitchB-Vlan20] quit

[SwitchB] interface ten-gigabitethernet1/0/2

[SwitchB-Ten-GigabitEthernet1/0/2] port link-type trunk

[SwitchB-Ten-GigabitEthernet1/0/2] port trunk permit vlan 20

[SwitchB-Ten-GigabitEthernet1/0/2] quit

# Enable FCoE for VLAN 20 and map VLAN 20 to VSAN 1.

[SwitchB] vlan 20

[SwitchB-vlan20] fcoe enable vsan 1

[SwitchB-vlan20] quit

[SwitchB] vsan 1

[SwitchB-vsan1] zone default-zone permit

[SwitchB-vsan1] quit

Verifying the configuration

# Verify the configuration on Switch A.

[SwitchA-vsan1] display fc domain vsan 1

Domain Information of VSAN 1:

Running time information:

State: Stable

Switch WWN: 48:33:43:2d:46:43:1A:1A

Fabric name: 11:11:11:11:11:11:11:11

Priority: 128

Domain ID: 1

Configuration information:

Domain configure: Disabled

Domain auto-reconfigure: Disabled

Fabric name: 11:11:11:11:11:11:11:11

Priority: 128

Domain ID: 1 (static)

Principal switch running time information:

Priority: 128

No interfaces available.

The output shows that the domain configuration is complete and that the runtime domain ID of Switch A is 1.

# Verify the configuration on Switch B.

[SwitchB-vsan1] display fc domain vsan 1

Domain Information of VSAN 1:

Running time information:

State: Stable

Switch WWN: 48:33:43:2d:46:43:1B:1B

Fabric name: 11:11:11:11:11:11:11:11

Priority: 128

Domain ID: 2

Configuration information:

Domain configure: Disabled

Domain auto-reconfigure: Disabled

Fabric name: 11:11:11:11:11:11:11:11

Priority: 128

Domain ID: 2 (static)

Principal switch running time information:

Priority: 128

No interfaces available.

The output shows that the domain configuration is complete and that the runtime domain ID of Switch B is 2.

Dynamic fabric building configuration example

Network requirements

As shown in Figure 20, use the dynamic method to build a fabric.

Figure 20 Network diagram

Configuration procedure

This section describes only fabric building configurations.

1. Configure Switch A:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchA> system-view

[SwitchA] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchA] save

[SwitchA] quit

<SwitchA> reboot

# Configure the switch to operate in FCF mode.

<SwitchA> system-view

[SwitchA] fcoe-mode fcf

# Enable the fabric configuration feature in VSAN 1. By default, the fabric configuration feature is enabled.

[SwitchA] vsan 1

[SwitchA-vsan1] domain configure enable

# Set the domain ID to 11.

[SwitchA-vsan1] domain-id 11 preferred

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

[SwitchA-vsan1] quit

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 1.

[SwitchA] vlan 10

[SwitchA-vlan10] fcoe enable vsan 1

[SwitchA-vlan10] quit

# Create interface VFC 2, and bind it to interface Ten-GigabitEthernet 1/0/2.

[SwitchA] interface Vfc 2

[SwitchA-Vfc2] bind interface ten-gigabitethernet1/0/2

# Configure VFC 2 to operate in E mode, and assign it to VSAN 1 as a trunk port.

[SwitchA-Vfc2] fc mode e

[SwitchA-Vfc2] port trunk vsan 1

[SwitchA-Vfc2] quit

# Create interface VFC 1, and bind it to interface Ten-GigabitEthernet 1/0/1.

[SwitchA] interface Vfc 1

[SwitchA-Vfc1] bind interface ten-gigabitethernet1/0/1

# Configure VFC 1 to operate in E mode, and assign it to VSAN 1 as a trunk port.

[SwitchA-Vfc1] fc mode e

[SwitchA-Vfc1] port trunk vsan 1

[SwitchA-Vfc1] quit

[SwitchA] vsan 1

[SwitchA-vsan1] zone default-zone permit

[SwitchA-vsan1] quit

2. Configure Switch B:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchB> system-view

[SwitchB] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchB] save

[SwitchB] quit

<SwitchB> reboot

# Configure the switch to operate in FCF mode.

<SwitchB> system-view

[SwitchB] fcoe-mode fcf

# Enable the fabric configuration feature in VSAN 1. By default, the fabric configuration feature is enabled.

[SwitchB] vsan 1

[SwitchB-vsan1] domain configure enable

# Set the switch priority to 1, so that Switch B can be selected as the principal switch.

[SwitchB-vsan1] priority 1

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 1.

[SwitchB] vlan 10

[SwitchB-vlan10] fcoe enable vsan 1

[SwitchB-vlan10] quit

# Create interface VFC 1, and bind it to interface Ten-GigabitEthernet 1/0/1.

[SwitchB] interface Vfc 1

[SwitchB-Vfc1] bind interface ten-gigabitethernet1/0/1

# Configure VFC 1 to operate in E mode, and assign it to VSAN 1 as a trunk port.

[SwitchB-Vfc1] fc mode e

[SwitchB-Vfc1] port trunk vsan 1

[SwitchB-Vfc1] quit

# Create interface VFC 2, and bind it to interface Ten-GigabitEthernet 1/0/2.

[SwitchB] interface Vfc 2

[SwitchB-Vfc2] bind interface ten-gigabitethernet1/0/2

# Configure VFC 2 to operate in E mode, and assign it to VSAN 1 as a trunk port.

[SwitchB-Vfc2] fc mode e

[SwitchB-Vfc2] port trunk vsan 1

[SwitchB-Vfc2] quit

# Create interface VFC 3, and bind it to interface Ten-GigabitEthernet 1/0/3.

[SwitchB] interface Vfc 3

[SwitchB-Vfc3] bind interface ten-gigabitethernet1/0/3

# Configure VFC 3 to operate in E mode, and assign it to VSAN 1 as a trunk port.

[SwitchB-Vfc3] fc mode e

[SwitchB-Vfc3] port trunk vsan 1

[SwitchB-Vfc3] quit

[SwitchB] vsan 1

[SwitchB-vsan1] zone default-zone permit

[SwitchB-vsan1] quit

3. Configure Switch C:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchC> system-view

[SwitchC] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchC] save

[SwitchC] quit

<SwitchC> reboot

# Configure the switch to operate in FCF mode.

<SwitchC> system-view

[SwitchC] fcoe-mode fcf

# Enable the fabric configuration feature in VSAN 1. By default, the fabric configuration feature is enabled.

[SwitchC] vsan 1

[SwitchC-vsan1] domain configure enable

# Set the domain ID to 13.

[SwitchC-vsan1] domain-id 13 preferred

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 1.

[SwitchC] vlan 10

[SwitchC-vlan10] fcoe enable vsan 1

[SwitchC-vlan10] quit

# Create interface VFC 1, and bind it to interface Ten-GigabitEthernet 1/0/1.

[SwitchC] interface Vfc 1

[SwitchC-Vfc1] bind interface ten-gigabitethernet1/0/1

# Configure VFC 1 to operate in F mode, and assign it to VSAN 1 as a trunk port.

[SwitchC-Vfc1] fc mode f

[SwitchC-Vfc1] port trunk vsan 1

[SwitchC-Vfc1] quit

# Create interface VFC 2, and bind it to interface Ten-GigabitEthernet 1/0/2.

[SwitchC] interface Vfc 2

[SwitchC-Vfc2] bind interface ten-gigabitethernet1/0/2

# Configure VFC 2 to operate in E mode, and assign it to VSAN 1 as a trunk port.

[SwitchC-Vfc2] fc mode e

[SwitchC-Vfc2] port trunk vsan 1

[SwitchC-Vfc2] quit

# Create interface VFC 3, and bind it to interface Ten-GigabitEthernet 1/0/3.

[SwitchC] interface Vfc 3

[SwitchC-Vfc3] bind interface ten-gigabitethernet1/0/3

# Configure VFC 3 to operate in E mode, and assign it to VSAN 1 as a trunk port.

[SwitchC-Vfc3] fc mode e

[SwitchC-Vfc3] port trunk vsan 1

[SwitchC-Vfc3] quit

[SwitchC] vsan 1

[SwitchC-vsan1] zone default-zone permit

[SwitchC-vsan1] quit

4. Configure Switch D:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchD> system-view

[SwitchD] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchD] save

[SwitchD] quit

<SwitchD> reboot

# Configure the switch to operate in FCF mode.

<SwitchD> system-view

[SwitchD] fcoe-mode fcf

# Enable the fabric configuration feature in VSAN 1. By default, the fabric configuration feature is enabled.

[SwitchD] vsan 1

[SwitchD-vsan1] domain configure enable

# Set the domain ID to 14.

[SwitchD-vsan1] domain-id 14 preferred

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 1.

[SwitchD] vlan 10

[SwitchD-vlan10] fcoe enable vsan 1

[SwitchD-vlan10] quit

# Create interface VFC 1, and bind it to interface Ten-GigabitEthernet 1/0/1.

[SwitchD] interface Vfc 1

[SwitchD-Vfc1] bind interface ten-gigabitethernet1/0/1

# Configure VFC 1 to operate in F mode, and assign it to VSAN 1 as a trunk port.

[SwitchD-Vfc1] fc mode f

[SwitchD-Vfc1] port trunk vsan 1

[SwitchD-Vfc1] quit

# Create interface VFC 2, and bind it to interface Ten-GigabitEthernet 1/0/2.

[SwitchD] interface Vfc 2

[SwitchD-Vfc2] bind interface ten-gigabitethernet1/0/2

# Configure VFC 2 to operate in E mode, and assign it to VSAN 1 as a trunk port.

[SwitchD-Vfc2] fc mode e

[SwitchD-Vfc2] port trunk vsan 1

[SwitchD-Vfc2] quit

[SwitchD] vsan 1

[SwitchD-vsan1] zone default-zone permit

[SwitchD-vsan1] quit

Verifying the configuration

Verify the configuration on switches, for example, Switch A.

# Display the domain information of VSAN 1.

[SwitchA-vsan1] display fc domain vsan 1

Domain Information of VSAN 1:

Running time information:

State: Stable

Switch WWN: 48:33:43:2d:46:43:1A:1A

Fabric name: 48:33:43:2d:46:43:1B:1B

Priority: 128

Domain ID: 11

Configuration information:

Domain configure: Enabled

Domain auto-reconfigure: Disabled

Fabric name: 48:33:43:2d:46:43:1A:1A

Priority: 128

Domain ID: 11 (preferred)

Principal switch running time information:

Priority: 1

Path Interface

Upstream Vfc1

Downstream Vfc2

The output shows that the domain configuration is complete and that the principal switch assigns domain ID 11 to Switch A.

# Display the domain ID list of VSAN 1.

[SwitchA-vsan1] display fc domain-list vsan 1

Domain list of VSAN 1:

Number of domains: 4

Domain ID WWN

0x01(5) 48:33:43:2d:46:43:1B:1B [Principal]

0x0b(11) 48:33:43:2d:46:43:1A:1A [Local]

0x0d(13) 48:33:43:2d:46:43:1C:1C

0x0e(14) 48:33:43:2d:46:43:1D:1D

The output shows that Switch B becomes the principal switch and assigns a random domain ID (ID 5) to itself.

Configuring FC routing and forwarding

Overview

Routing and forwarding in an FC SAN is achieved through FCF switches. When an FCF switch receives a packet, an FCF switch performs the following operations:

· Selects an optimal route based on the destination address.

· Forwards the packet to the next FCF switch in the path until the packet reaches the last FCF switch.

The last FCF switch forwards the packet to the destination node.

Routing provides the path information that guides the forwarding of packets.

Routing table and FIB table

An FCF switch determines the best routes by using its routing table and sends those routes to the FIB table, which guides packet forwarding. An FCF switch maintains one routing table and one FIB table for each VSAN.

Routing table contents

The routing table saves the routes discovered by various routing protocols. Routes in a routing table include the following types:

· Direct routes—Routes discovered by link layer protocols.

· Static routes—Routes manually configured by the administrator.

· FSPF routes—Routes discovered by the Fabric Shortest Path First (FSPF) protocol.

To display brief information about a routing table, use the display fc routing-table command as follows:

<Sysname> display fc routing-table vsan 1

Routing Table: VSAN 1

Destinations : 6 Routes : 6

Destination/mask Protocol Preference Cost Interface

0x020000/8 FSPF 20 265 Vfc1

0x120000/8 STATIC 10 0 Vfc2

0xfffc01/24 DIRECT 0 0 InLoop0

0xfffffa/24 DIRECT 0 0 InLoop0

0xfffffc/24 DIRECT 0 0 InLoop0

0xfffffd/24 DIRECT 0 0 InLoop0

...

A route entry includes the following key items:

· Destination—Destination address of an FC frame.

· mask—Together with the destination address, specifies the domain address of the destination node or FCF switch. A logical AND operation between the destination address and the network mask yields the domain address of the destination node or FCF switch. For example, if the destination address is 0x010001 and the mask is 0xff0000, the domain address of the destination node or FCF switch is 0x010000. A network mask is made up of a certain number of consecutive 1s. It can be expressed in hexadecimal format or by the number of 1s.

· Protocol—Protocol type, which can be DIRECT (direct routes), STATIC (static routes), or FSPF (FSPF routes).

· Preference—There might be direct routes, static routes, and FSPF routes to the same destination. All of these types of routes are assigned preferences. Direct routes have a preference of 0, static routes have a preference of 10, and FSPF routes have a preference of 20. The optimal route is the one with the highest priority (smallest preference value).

· Cost—Cost of the route. For routes to the same destination and with the same preference, the route with the lowest cost is the optimal one. The cost of direct routes is 0. The costs of static routes and FSPF routes are configurable.

· Interface—Specifies the interface through which a matching FC frame is to be forwarded out of the FCF switch.

FIB table contents

Each entry in the FIB table specifies the output interface for packets destined for an FCF switch or node.

To display FIB table information, use the display fc fib command as follows:

<Sysname> display fc fib vsan 1

FC FIB information in VSAN 1:

Destination count: 6

FIB entry count: 6

Destination/Mask Interface

0x020000/8 Vfc1

0x120000/8 Vfc2

0xfffc01/24 InLoop0

0xfffffa/24 InLoop0

0xfffffc/24 InLoop0

0xfffffd/24 InLoop0

The key items Destination, Mask, and Interface in an FIB table have the same meanings as those in a routing table.

Direct routes

The sources of direct routes include well-known addresses and the FC addresses that the local switch assigns to directly-connected N_Ports.

· The well-known addresses are usually used to access FCF switches. For information about using common well-known addresses, see "Appendix B Well-known fabric addresses." All well-known addresses are added to the routing table as the destination addresses of direct routes. The direct route includes the following settings:

? The destination address is a well-known address.

? The mask is 0xffffff.

? The outgoing interface is InLoop0.

· When an FCF switch assigns FC addresses to directly connected N_Ports, the FCF switch adds the direct routes of these addresses to the routing table. The direct route includes the following settings:

? The destination address is an assigned FC address.

? The mask is 0xffffff.

? The outgoing interface is the VFC interface connected to the N_Port.

Static routes

Static routes are manually configured by the administrator. After you configure a static route, an FC frame to a destination is forwarded along the specified path.

In a simple network, static routes are enough for implementing network connectivity. By correctly setting up and using static routes, you can improve network performance and guarantee bandwidth for critical network applications.

Static routes cannot adapt to network topology changes. If a fault or a topological change occurs in the network, the network administrator must modify the static routes manually.

Static routes support equal-cost routes. When you configure multiple equal-cost static routes to the same destination but with different outgoing interfaces, equal-cost routes are generated.

FSPF routes

As a route selection protocol based on link states, FSPF can automatically calculate the best path between any two switches in a fabric.

FSPF has the following characteristics:

· Can be used for any topology.

· Supports equal-cost routes.

· Performs topology calculations on a per-VSAN basis.

· Runs only on E_Ports and provides a loop-free topology.

· Provides a topology database on each switch to track the state of all links.

· Uses the Dijkstra algorithm to calculate routes.

· Provides fast convergence in the event of topology changes.

Basic concepts

· LSDB—The link state database (LSDB) stores global topology information for switches and link state information of all switches in link state records (LSRs).

· LSR—An LSR describes information about all link states between a switch and its directly connected switches.

Each LSR generated by a switch is called an LSR instance. LSRs generated by all switches form the LSDB. An LSR contains one or more pieces of link state information, including the following:

? LSR hold time.

? Domain ID of the switch advertising the LSR.

? LSR instance number. Every time an LSR is updated, the instance number increments by 1.

? Link ID, which identifies a link and includes the domain ID of the switch at the peer end of the link.

? Source interface and destination interface of the link.

? Link type, for example, point-to-point connection.

? Cost for packet transmission over the link. The smaller the cost, the better the link. The route selection algorithm uses this value to determine the best route. The interface cost is configurable.

FSPF packet types

The following protocol packets are used in FSPF:

· Hello packets—Sent periodically to discover and maintain FSPF neighbors.

· Link state update (LSU)—Advertises local link state information in LSRs to the neighboring switches.

· Link state acknowledgment (LSA)—Acknowledges the received LSR.

After receiving an LSU, a switch needs to acknowledge its LSR with an LSA. Otherwise, the neighboring switch retransmits the LSR.

How FSPF works

FSPF works as follows:

1. The switch periodically sends hello packets to establish neighbor relationships with other switches.

2. After establishing neighbor relationships, the switches synchronize LSDBs by exchanging all LSRs in their respective LSDBs. A switch carries LSRs in LSUs and acknowledges received LSRs with LSAs.

3. After the synchronization is complete, the LSDB in each switch contains LSRs of all switches in the fabric.

4. The switch uses the Dijkstra algorithm to calculate the shortest paths to other switches based on the local LSDB. Then, it determines the outgoing interfaces and generates an FSPF routing table.

5. When the network topology or link state changes, the switch floods a new LSR to its neighboring switches. After receiving the LSR, the neighboring switches add it to their LSDBs and flood it to their respective neighbors. In this way, all switches in the fabric receive that LSR.

6. Local LSDB updating results in SPF calculation. The calculated shortest path tree list is updated to the FSPF routing table.

Configuring static FC routes

Configuration restrictions and guidelines

When you configure static FC routes, follow these restrictions and guidelines:

· The destination address of a static FC route is in the range of 010000 to EFFFFF (hexadecimal). You cannot configure a route with a well-known address as the destination address.

· The outgoing interface of a static FC route can only be a VFC interface.

· If you configure two routes with the same destination address, mask, and outgoing interface, but with different costs, the route configured later applies.

· The maximum number of static routes allowed in a VSAN is 256.

Configuration procedure

To configure a static FC route:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Configure a static FC route.	fc route-static fcid { mask \| mask-length } interface-type interface-number [ cost cost-value ]	By default, no static FC route exists.

Configuring FSPF

FSPF is enabled by default. Typically, you do not need to perform special operations.

You can change FSPF parameters on a per-VSAN or per-interface basis.

FSPF configuration task list

Tasks at a glance	Remarks
Change FSPF parameters in VSAN view · (Required.) Enabling FSPF · (Optional.) Setting the shortest SPF calculation interval · (Optional.) Setting the minimum LSR arrival interval · (Optional.) Setting the minimum LSR refresh interval	N/A
(Optional.) Change FSPF parameters in interface view · Setting the FSPF cost for an interface · Setting the hello interval for an interface · Setting the dead interval for an interface · Setting the LSR retransmission interval for an interface · Disabling FSPF for an interface	Configure parameters on interfaces operating in E mode.
(Optional.) Configuring FSPF GR · Configuring the GR restarter · Configuring the GR helper	N/A

Enabling FSPF

FSPF-related features can work in a VSAN only after you enable FSPF for the VSAN.

To enable FSPF:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Enable FSPF for the VSAN.	fspf enable	By default, FSPF is enabled after a VSAN is created.

Setting the shortest SPF calculation interval

SPF calculations occur when the LSDB changes. To limit the amount of CPU resources consumed by frequent SPF calculations, you can change the shortest SPF calculation interval.

The shortest SPF calculation interval defines the minimum interval between two consecutive SPF calculations. A smaller value means that FSPF responds faster to fabric changes by recalculating routes in a VSAN, but it requires more CPU resources.

To set the shortest SPF calculation interval:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Set the shortest SPF calculation interval.	fspf spf-hold-time value	The default setting is 0 seconds.

Setting the minimum LSR arrival interval

The minimum LSR arrival interval specifies the interval between received LSR updates in a VSAN. Any LSR updates that arrive before this interval expires are dropped. This helps avoid frequent SPF calculations caused by LSDB updating.

To set the minimum LSR arrival interval:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Set the minimum LSR arrival interval.	fspf min-ls-arrival value	The default setting is 1 second.

Setting the minimum LSR refresh interval

The minimum LSR refresh interval specifies the interval at which LSRs are refreshed. To reduce SPF calculations and LSR flooding in a fabric caused by frequent LSR refreshing, the switch cannot refresh local LSRs within this interval.

To set the minimum LSR refresh interval:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Set the minimum LSR refresh interval.	fspf min-ls-interval interval	The default setting is 5 seconds.

Setting the FSPF cost for an interface

Each link has a cost. The route selection algorithm uses this value to determine the best route. The smaller the interface FSPF cost, the smaller the link cost.

To set the FSPF cost for an interface:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VFC interface view.	interface vfc interface-number	N/A
3. Set the FSPF cost for the interface in a VSAN.	fspf cost cost-value vsan vsan-id	By default, the FSPF cost is calculated by using the formula 1.0e12/baud rate.

Setting the hello interval for an interface

The hello interval specifies the time between the hello packets sent periodically by the switch to discover and maintain neighbor relationships.

NOTE:

The set hello interval must be smaller than the dead interval and must be the same at the two ends of the link.

To set the hello interval for an interface:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VFC interface view.	interface vfc interface-number	N/A
3. Set the hello interval for the interface in a VSAN.	fspf hello-interval interval vsan vsan-id	The default setting is 20 seconds.

Setting the dead interval for an interface

After two switches establish a neighbor relationship, they send hello packets at the hello interval to each other to maintain the neighbor relationship. The dead interval specifies the interval during which at least one hello packet must be received from a neighbor before the neighbor is considered nonexistent and removed.

NOTE:

The set dead interval must be greater than the hello interval and must be the same at the two ends of the link.

To set the dead interval for an interface:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VFC interface view.	interface vfc interface-number	N/A
3. Set the dead interval for the interface in a VSAN.	fspf dead-interval interval vsan vsan-id	The default setting is 80 seconds.

Setting the LSR retransmission interval for an interface

The LSR retransmission interval specifies the time to wait for an LSR acknowledgment from the neighbor before retransmitting the LSR.

To set the LSR retransmission interval for an interface:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VFC interface view.	interface vfc interface-number	N/A
3. Set the LSR retransmission interval for the interface in a VSAN.	fspf retransmit-interval interval vsan vsan-id	The default setting is 5 seconds.

Disabling FSPF for an interface

With FSPF enabled, an interface can participate in SPF calculation. To avoid SPF calculations on an interface, disable FSPF on the interface.

To disable FSPF on an interface:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VFC interface view.	interface vfc interface-number	N/A
3. Disable FSPF for the interface in a VSAN.	fspf silent vsan vsan-id	By default, FSPF is enabled on all interfaces.

Configuring FSPF GR

FSPF Graceful Restart (GR) enables nonstop forwarding of traffic by backing up FSPF configuration information in the following situations:

· A protocol restart (for example, the FSPF process restart triggered by the process command).

· An active/standby switchover.

GR involves the following roles:

· GR restarter—GR-capable device where a protocol restart or active/standby switchover occurs.

· GR helper—The GR restarter's neighboring device that assists in the GR process.

Configuring the GR restarter

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enable FSPF GR.	fspf graceful-restart	By default, FSPF GR is disabled.
3. Set the maximum FSPF GR interval.	fspf graceful-restart interval interval	The default setting is 120 seconds.

Configuring the GR helper

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enable FSPF GR helper.	fspf graceful-restart helper	By default, FSPF GR helper is enabled.

Displaying and maintaining FC routing and forwarding

Execute display commands in any view and reset commands in user view.

Task	Command
Display FC routing table information.	display fc routing-table [ vsan vsan-id ] [ statistics \| verbose ] display fc routing-table vsan vsan-id fc-id [ mask \| mask-length ] [ verbose ]
Display FC FIB table information.	display fc fib [ fcid [ mask-length ] ] vsan vsan-id
Display FC Exchange table information (in standalone mode).	display fc exchange { link \| protocol } [ slot slot-number ] display fc exchange link verbose [ slot slot-number [ exid exid ] ]
Display FC Exchange table information (in IRF mode).	display fc exchange { link \| protocol } [ chassis chassis-number slot slot-number ] display fc exchange link verbose [ chassis chassis-number slot slot-number [ exid exid ] ]
Display FSPF neighbor information.	display fspf neighbor [ vsan vsan-id ]
Display link state database information.	display fspf lsdb [ vsan vsan-id ]
Display FSPF GR state information.	display fspf graceful-restart [ vsan vsan-id ]
Display FSPF statistics.	display fspf statistics [ vsan vsan-id ]
Clear FSPF statistics.	reset fspf counters [ vsan vsan-id ]

FC routing configuration examples

Static FC routing configuration example

Network requirements

The fabric contains three switches, Switch A, B, and C.

Configure static routes so any two FCF switches can communicate with each other.

Figure 21 Network diagram

Configuration procedure

1. Configure Switch A:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchA> system-view

[SwitchA] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchA] save

[SwitchA] quit

<SwitchA> reboot

# Configure the switch to operate in FCF mode.

<SwitchA> system-view

[SwitchA] fcoe-mode fcf

# Enable the fabric configuration feature for VSAN 1.

[SwitchA] vsan 1

[SwitchA-vsan1] domain configure enable

# Set the domain ID to 1.

[SwitchA-vsan1] domain-id 1 static

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

[SwitchA-vsan1] quit

# Create interface VFC 1.

[SwitchA] interface vfc 1

# Configure the mode of VFC 1 as E.

[SwitchA-Vfc1] fc mode e

# Bind VFC 1 to interface Ten-GigabitEthernet 1/0/1.

[SwitchA-Vfc1] bind interface ten-gigabitethernet 1/0/1

# Assign VFC 1 to VSAN 1 as a trunk port.

[SwitchA-Vfc1] port trunk vsan 1

[SwitchA-Vfc1] quit

# Configure Ten-GigabitEthernet 1/0/1 as a trunk port, and assign the port to VLAN 10.

[SwitchA] interface ten-gigabitethernet 1/0/1

[SwitchA-Ten-GigabitEthernet1/0/1] port link-type trunk

[SwitchA-Ten-GigabitEthernet1/0/1] port trunk permit vlan 10

[SwitchA-Ten-GigabitEthernet1/0/1] quit

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 1.

[SwitchA] vlan 10

[SwitchA-vlan10] fcoe enable vsan 1

[SwitchA-vlan10] quit

# Configure two static routes.

[SwitchA] vsan 1

[SwitchA-vsan1] fc route-static 020000 8 vfc 1

[SwitchA-vsan1] fc route-static 030000 8 vfc 1

2. Configure Switch B:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchB> system-view

[SwitchB] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchB] save

[SwitchB] quit

<SwitchB> reboot

# Configure the switch to operate in FCF mode.

<SwitchB> system-view

[SwitchB] fcoe-mode fcf

# Enable the fabric configuration feature for VSAN 1.

[SwitchB] vsan 1

[SwitchB-vsan1] domain configure enable

# Set the domain ID to 2.

[SwitchB-vsan1] domain-id 2 static

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

[SwitchB-vsan1] quit

# Create interface VFC 1.

[SwitchB] interface vfc 1

# Configure the mode of VFC 1 as E.

[SwitchB-Vfc1] fc mode e

# Bind VFC 1 to interface Ten-GigabitEthernet 1/0/1.

[SwitchB-Vfc1] bind interface ten-gigabitethernet 1/0/1

# Assign VFC 1 to VSAN 1 as a trunk port.

[SwitchB-Vfc1] port trunk vsan 1

[SwitchB-Vfc1] quit

# Configure Ten-GigabitEthernet 1/0/1 as a trunk port, and assign the port to VLAN 10.

[SwitchB] interface ten-gigabitethernet 1/0/1

[SwitchB-Ten-GigabitEthernet1/0/1] port link-type trunk

[SwitchB-Ten-GigabitEthernet1/0/1] port trunk permit vlan 10

[SwitchB-Ten-GigabitEthernet1/0/1] quit

# Create interface VFC 2.

[SwitchB] interface vfc 2

# Configure the mode of VFC 2 as E.

[SwitchB-Vfc2] fc mode e

# Bind VFC 2 to interface Ten-GigabitEthernet 1/0/2.

[SwitchB-Vfc2] bind interface ten-gigabitethernet 1/0/2

# Assign VFC 2 to VSAN 1 as a trunk port.

[SwitchB-Vfc2] port trunk vsan 1

[SwitchB-Vfc2] quit

# Configure Ten-GigabitEthernet 1/0/2 as a trunk port, and assign the port to VLAN 10.

[SwitchB] interface ten-gigabitethernet 1/0/2

[SwitchB-Ten-GigabitEthernet1/0/2] port link-type trunk

[SwitchB-Ten-GigabitEthernet1/0/2] port trunk permit vlan 10

[SwitchB-Ten-GigabitEthernet1/0/2] quit

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 1.

[SwitchB] vlan 10

[SwitchB-vlan10] fcoe enable vsan 1

[SwitchB-vlan10] quit

# Configure two static routes.

[SwitchB] vsan 1

[SwitchB-vsan1] fc route-static 010000 8 vfc 1

[SwitchB-vsan1] fc route-static 030000 8 vfc 2

3. Configure Switch C:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchC> system-view

[SwitchC] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchC] save

[SwitchC] quit

<SwitchC> reboot

# Configure the switch to operate in FCF mode.

<SwitchC> system-view

[SwitchC] fcoe-mode fcf

# Enable the fabric configuration feature for VSAN 1.

[SwitchC] vsan 1

[SwitchC-vsan1] domain configure enable

# Set the domain ID to 3.

[SwitchC-vsan1] domain-id 3 static

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

[SwitchC-vsan1] quit

# Create interface VFC 2.

[SwitchC] interface vfc 2

# Configure the mode of VFC 2 as E.

[SwitchC-Vfc2] fc mode e

# Bind VFC 2 to interface Ten-GigabitEthernet 1/0/2.

[SwitchC-Vfc2] bind interface ten-gigabitethernet 1/0/2

# Assign VFC 2 to VSAN 1 as a trunk port.

[SwitchC-Vfc2] port trunk vsan 1

[SwitchC-Vfc2] quit

# Configure Ten-GigabitEthernet 1/0/2 as a trunk port, and assign the port to VLAN 10.

[SwitchC] interface ten-gigabitethernet 1/0/2

[SwitchC-Ten-GigabitEthernet1/0/2] port link-type trunk

[SwitchC-Ten-GigabitEthernet1/0/2] port trunk permit vlan 10

[SwitchC-Ten-GigabitEthernet1/0/2] quit

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 1.

[SwitchC] vlan 10

[SwitchC-vlan10] fcoe enable vsan 1

[SwitchC-vlan10] quit

# Configure two static routes on Switch C.

[SwitchC] vsan 1

[SwitchC-vsan1] fc route-static 010000 8 vfc 2

[SwitchC-vsan1] fc route-static 020000 8 vfc 2

Verifying the configuration

# Display the FC routing table in VSAN 1 on Switch A.

[SwitchA-vsan1] display fc routing-table vsan 1

Routing Table: VSAN 1

Destinations : 6 Routes : 6

Destination/mask Protocol Preference Cost Interface

0x020000/8 STATIC 10 0 Vfc1

0x030000/8 STATIC 10 0 Vfc1

0xfffc01/24 DIRECT 0 0 InLoop0

0xfffffa/24 DIRECT 0 0 InLoop0

0xfffffc/24 DIRECT 0 0 InLoop0

0xfffffd/24 DIRECT 0 0 InLoop0

# Display the FC routing table in VSAN 1 on Switch B.

[SwitchB-vsan1] display fc routing-table vsan 1

Routing Table: VSAN 1

Destinations : 6 Routes : 6

Destination/mask Protocol Preference Cost Interface

0x010000/8 STATIC 10 0 Vfc1

0x030000/8 STATIC 10 0 Vfc2

0xfffc02/24 DIRECT 0 0 InLoop0

0xfffffa/24 DIRECT 0 0 InLoop0

0xfffffc/24 DIRECT 0 0 InLoop0

0xfffffd/24 DIRECT 0 0 InLoop0

# Display the FC routing table in VSAN 1 on Switch C.

[SwitchC-vsan1] display fc routing-table vsan 1

Routing Table: VSAN 1

Destinations : 6 Routes : 6

Destination/mask Protocol Preference Cost Interface

0x010000/8 STATIC 10 0 Vfc2

0x020000/8 STATIC 10 0 Vfc2

0xfffc03/24 DIRECT 0 0 InLoop0

0xfffffa/24 DIRECT 0 0 InLoop0

0xfffffc/24 DIRECT 0 0 InLoop0

0xfffffd/24 DIRECT 0 0 InLoop0

# FCping Switch C from Switch A.

[SwitchA-vsan1] fcping fcid fffc03 vsan 1

FCPING fcid 0xfffc03: 128 data bytes, press CTRL_C to break

Reply from 0xfffc03: bytes = 128 time = 23 ms

Reply from 0xfffc03: bytes = 128 time = 9 ms

Reply from 0xfffc03: bytes = 128 time = 19 ms

Reply from 0xfffc03: bytes = 128 time = 14 ms

Reply from 0xfffc03: bytes = 128 time = 25 ms

--- 0xfffc03 fcping statistics ---

5 packet(s) transmitted

5 packet(s) received

0.00% packet loss

round-trip min/avg/max = 9/18/25 ms

The output shows that Switch A can reach Switch C.

FSPF configuration example

Network requirements

Configure FSPF so the two FCF switches can communicate with each other.

Figure 22 Network diagram

Configuration procedure

This section describes only the FC routing configurations.

1. Configure Switch A:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchA> system-view

[SwitchA] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchA] save

[SwitchA] quit

<SwitchA> reboot

# Configure the switch to operate in FCF mode.

<SwitchA> system-view

[SwitchA] fcoe-mode fcf

# Create VSAN 2 and enable the fabric configuration feature for VSAN 2.

[SwitchA] vsan 2

[SwitchA-vsan2] domain configure enable

# Set the domain ID to 1.

[SwitchA-vsan2] domain-id 1 static

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

# Enable FSPF.

[SwitchA-vsan2] fspf enable

[SwitchA-vsan2] quit

# Create interface VFC 1.

[SwitchA] interface vfc 1

# Configure the mode of VFC 1 as E.

[SwitchA-Vfc1] fc mode e

# Bind VFC 1 to interface Ten-GigabitEthernet 1/0/1.

[SwitchA-Vfc1] bind interface ten-gigabitethernet 1/0/1

# Assign VFC 1 to VSAN 2 as a trunk port.

[SwitchA-Vfc1] port trunk vsan 2

[SwitchA-Vfc1] quit

# Configure Ten-GigabitEthernet 1/0/1 as a trunk port, and assign the port to VLAN 10.

[SwitchA] interface ten-gigabitethernet 1/0/1

[SwitchA-Ten-GigabitEthernet1/0/1] port link-type trunk

[SwitchA-Ten-GigabitEthernet1/0/1] port trunk permit vlan 10

[SwitchA-Ten-GigabitEthernet1/0/1] quit

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 2.

[SwitchA] vlan 10

[SwitchA-vlan10] fcoe enable vsan 2

[SwitchA-vlan10] quit

# Enable FSPF for VFC 1.

[SwitchA] interface vfc 1

[SwitchA-Vfc1] undo fspf silent vsan 2

[SwitchA-Vfc1] quit

2. Configure Switch B:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchB> system-view

[SwitchB] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchB] save

[SwitchB] quit

<SwitchB> reboot

# Configure the switch to operate in FCF mode.

<SwitchB> system-view

[SwitchB] fcoe-mode fcf

# Create VSAN 2 and enable the fabric configuration feature for VSAN 2.

[SwitchB] vsan 2

[SwitchB-vsan2] domain configure enable

# Set the domain ID to 2.

[SwitchB-vsan2] domain-id 2 static

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

# Enable FSPF.

[SwitchB-vsan2] fspf enable

[SwitchB-vsan2] quit

# Create interface VFC 1.

[SwitchB] interface vfc 1

# Configure the mode of VFC 1 as E.

[SwitchB-Vfc1] fc mode e

# Bind VFC 1 to interface Ten-GigabitEthernet 1/0/1.

[SwitchB-Vfc1] bind interface ten-gigabitethernet 1/0/1

# Assign VFC 1 to VSAN 2 as a trunk port.

[SwitchB-Vfc1] port trunk vsan 2

[SwitchB-Vfc1] quit

# Configure Ten-GigabitEthernet 1/0/1 as a trunk port, and assign the port to VLAN 10.

[SwitchB] interface ten-gigabitethernet 1/0/1

[SwitchB-Ten-GigabitEthernet1/0/1] port link-type trunk

[SwitchB-Ten-GigabitEthernet1/0/1] port trunk permit vlan 10

[SwitchB-Ten-GigabitEthernet1/0/1] quit

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 2.

[SwitchB] vlan 10

[SwitchB-vlan10] fcoe enable vsan 2

[SwitchB-vlan10] quit

# Enable FSPF for VFC 1.

[SwitchB] interface vfc 1

[SwitchB-Vfc1] undo fspf silent vsan 2

[SwitchB-Vfc1] quit

Verifying the configuration

# Display the FSPF neighbor information for Switch A.

[SwitchA] display fspf neighbor

FSPF neighbor information of VSAN 2(01):

Interface NbrDomain IfIndex NbrIfIndex Dead Time State

Vfc1 2 0x68 0x68 00:01:06 Full

# Display the routing table information for Switch A.

[SwitchA] display fc routing-table vsan 2

Routing Table: VSAN 2

Destinations : 5 Routes : 5

Destination/mask Protocol Preference Cost Interface

0x020000/8 FSPF 20 100 Vfc1

0xfffc01/24 DIRECT 0 0 InLoop0

0xfffffa/24 DIRECT 0 0 InLoop0

0xfffffc/24 DIRECT 0 0 InLoop0

0xfffffd/24 DIRECT 0 0 InLoop0

# FCping Switch B from Switch A.

[SwitchA] fcping fcid fffc02 vsan 2

FCPING fcid 0xfffc02: 128 data bytes, press CTRL_C to break.

Reply from 0xfffc02: bytes = 128 time = 1.102 ms

Reply from 0xfffc02: bytes = 128 time = 0.276 ms

Reply from 0xfffc02: bytes = 128 time = 0.253 ms

Reply from 0xfffc02: bytes = 128 time = 0.270 ms

Reply from 0xfffc02: bytes = 128 time = 0.247 ms

--- 0xfffc02 fcping statistics ---

5 packet(s) transmitted

5 packet(s) received

0.00% packet loss

round-trip min/avg/max = 0.247/0.430/1.102 ms

The output shows that Switch A can reach Switch B.

Configuring FC zones

Overview

The VSAN technology divides a physical SAN into multiple VSANs, which are separated from one another, and provides more secure, reliable, and flexible services. A VSAN, however, cannot perform access control over the servers and disk devices (or the N_Ports) connected to a fabric. N_Ports in the same VSAN can access one another only if these N_Ports register name services. This creates data security risks.

Zoning can solve the preceding problem by dividing a VSAN into zones and adding N_Ports or F_Ports to different zones for different purposes. In this way, N_Ports in different zones are separated to implement access control.

Adding an F_Port to a zone adds all N_Ports that log in through the F_Port to that zone.

Zoning mode

There are two zoning modes: basic zoning and enhanced zoning.

Table 4 shows the differences between the two zoning modes.

Table 4 Differences between basic zoning and enhanced zoning

Basic zoning	Enhanced zoning
The default zone policy and hard zoning status are not distributed during the zone distribution process. You must manually configure these settings on all switches to ensure consistency across the fabric.	The default zone policy and hard zoning status are distributed throughout the fabric.
If a zone belongs to multiple zone sets, an instance of the zone is created in each zone set.	Zone sets can reference a defined zone, which reduces the payload of packets for zone merge or distribution.
Merge rules are simple.	Merge rules are complex and are affected by the merge control feature.

Zone database

To control access among N_Ports, you can divide N_Ports into different zones as needed, which form a zone set. The same N_Ports can form multiple zone sets according to different zone division policies. These zones and zone sets form a zone database.

Zone database structure

The zone database is organized into three levels (zone set, zone, and zone member).

Figure 23 Zone database structure

In the zone database structure:

· A zone set is a set of zones. A zone is a set of zone members, which are N_Ports or F_Ports. N_Port membership can be identified by the WWN (pWWN) or FC address of an N_Port. F_Port membership is identified by the WWN of an F_Port (fWWN).

· Each VSAN can have multiple zone sets, each zone set can have multiple zones, and each zone can have multiple zone members.

· Zone membership configuration supports use of zone aliases. A zone alias is a set of N_Ports, which can be considered as a whole. To simplify configuration, you can add common zone members in multiple zones to a zone alias, and call the zone alias in different zones.

Active zone set

Each VSAN can have multiple zone sets, but only one zone set can be effective at a time. It is called the active zone set. Access control over N_Ports is subject to the active zone set.

To ensure consistent access control over N_Ports across a fabric, specify a zone set as the active zone set on a switch and distribute it to the entire fabric.

When you activate a zone set, a copy of the zone set at the time of activation is created and is called the active zone set. After that, modifications to the zone set do not take effect on the copy until the copy is reactivated. Figure 24 shows the relationship between active and full zone sets.

Figure 24 Active and full zone sets

In basic zoning mode, the system checks the size of the data to be distributed when you activate a zone set. If the size of the data exceeds the system limit, the activation fails, and an error message is displayed.

In enhanced zoning mode, the system does not limit the size of the data to be distributed.

Default zone

The N_Ports in zones of the active zone set are part of the active zone set. Registered N_Ports that are not in the active zone set automatically become part of the default zone.

If members of the default zone are allowed to access each other, the following events occur:

· The default zone can be considered to be part of the active zone set.

· The default zone participates in access control among N_Ports.

Otherwise, the default zone is not in the active zone set and does not participate in access control among the N_Ports.

In basic zoning mode, the switch does not distribute the default zone policy across the fabric. You must manually configure a consistent default zone policy across the fabric. In enhanced zoning mode, the switch distributes the default zone policy during the zone distribution process.

Peer zone

Peer zones are supported only in enhanced zoning mode.

You can define a peer zone on a target device by specifying a zone name, the principal member, and peer members. The switch automatically creates the defined peer zone when receiving related packets from the target device.

Each peer zone can have one principal member and multiple peer members. The principal member can communicate with all peer members. Any two peer members in a peer zone cannot communicate with each other unless they are allowed to communicate with each other in another zone.

Pairwise

The Pairwise feature is supported only in enhanced zoning mode.

Typically, servers do not need to access each other, and storage devices do not need to access each other. Without the Pairwise feature, an access entry is generated for any pair of members in a zone.

The Pairwise feature allows a member to access only members with a different role in the same zone.

The following roles are defined for zone members:

· Initiator—Typically a server.

· Target—Typically a storage device.

When the Pairwise feature is enabled, access entries are not generated for initiator-initiator pairs or target-target pairs, which saves hardware resources.

The Pairwise feature runs on a per-zone basis. A member can have different roles in different zones. When the Pairwise feature is disabled for a zone, member roles do not take effect in that zone.

When a member acts as an initiator, it can access target members. When a member acts as a target, it can access initiator members. When a member acts as both an initiator and a target, it can access both target members and initiator members.

Zone distribution in basic zoning mode

Zone distribution occurs when a switch distributes its zone database to all the other devices in the same fabric. The distributing switch is called a manager switch, and all other switches are called managed switches.

In basic zoning mode, the following distribution types are provided:

· Complete distribution—Distributes both the active zone set and the zone database.

· Incomplete distribution—Distributes only the active zone set.

Zone distribution methods

You can distribute zones by using one of the following methods:

· Activate a zone set as the active zone set on a switch by using the zoneset activate command. At the time of activation, the active zone set is distributed to all the other switches.

If the size of the zone set exceeds the system limit, the activation fails.

This method determines whether to carry the zone database according to the configured distribution type.

· Distribute the active zone set and the zone database directly by using the zoneset distribute command on a switch.

This method performs a complete distribution regardless of the configured distribution type.

Managed switches replace their respective active zone sets or zone databases with the received data, regardless of the distribution types configured on them. If a managed switch receives only the zone database, the managed switch does not retain its active zone set (if present) after replacement.

Zone distribution process

The manager switch completes data synchronization with each managed switch by using the following packets:

· Acquire Change Authorization (ACA).

· Stage Fabric Configuration Update (SFC).

· Update Fabric Configuration (UFC).

· Release Change Authorization (RCA).

These types of packets implement locking, data synchronization, submission, and unlocking processes, respectively. These processes ensure that only one switch is the manager switch when multiple users trigger a data distribution on different switches at the same time.

Figure 25 Distribution process

The distribution process is as follows:

1. The manager switch obtains the status of each managed switch through an ACA request. The ACA request carries the fabric-wide list of domain IDs (addresses of all switches in the fabric) known to the manager switch. After sending the ACA request, the manager switch enters the locked state.

2. After receiving the ACA request, a managed switch compares its list of domain IDs with that in the packet.

? If they are consistent, the fabric is in stable state. In this case, the managed switch is prepared for synchronization, replies with an ACC (acknowledgment) packet, and enters the change authorization (locked) state.

IMPORTANT:

For a fabric to be stable, make sure the routes are correctly and consistently configured, and no unreachable routes exist.

? If the managed switch has been in change authorization state or cannot process the ACA request, it replies with an RJT (reject) packet.

3. The manager switch starts data synchronization by sending an SFC request only after receiving ACC requests from all managed switches. Otherwise, it notifies managed switches to release the change authorization state by sending an RCA request.

If the managed switch replies with neither an ACC packet nor an RJT packet because of its abnormal state, the manager switch cannot release its locked state. To prevent this situation, the manager switch transmits an ACA request up to three times.

? If no reply is received, the manager switch releases its locked state.

? If the manager switch becomes abnormal after sending an ACA request, the managed switch will be in locked state and cannot receive subsequent packets. In this situation, the managed switch releases its locked state after waiting for a period of time.

4. The manager switch sends an SFC request to all managed switches. The SFC request carries data to be synchronized, including the active zone set and zone database information. After receiving the SFC request, the managed switch calculates the total numbers of zones, zone sets, and zone aliases if its local zone database is replaced.

? If none of the total numbers exceed the limit, the managed switch replies with an ACC packet.

? If any of the total numbers exceed the limit, the managed switch replies with an RJT packet.

? After receiving ACC packets from all managed switches, the manager switch sends a UFC request to the managed switches. The UFC request notifies the managed switches to replace their local data with the received data. Otherwise, the manager switch sends an RCA request to notify managed switches to release the change authorization state.

5. After receiving the UFC request, the managed switch updates its local zone database. It replies with an ACC packet for a successful update and with an RJT packet for a failed update.

6. The manager switch notifies managed switches by sending an RCA request to release the change authorization state after receiving ACC packets from all managed switches.

7. After receiving the RCA request, the managed switch releases its change authorization state and replies with an ACC packet.

8. The manager switch releases its change authorization state after receiving ACC packets from all managed switches.

Zone distribution in enhanced zoning mode

Enhanced zoning has the following differences from basic zoning in zone distribution:

· Enhanced zoning distributes the zone policy and hard zoning status in addition to the active zone set and zone database.

The zone policy includes the merge control mode and default zone policy. For information about the merge control mode, see "Zone merge in enhanced zoning mode."

· Enhanced zoning always performs complete distribution and does not support the zoneset distribute full command.

You can use the same zone distribution methods for basic zoning as used in enhanced zoning mode.

A switchover between basic zoning and enhanced zoning also causes zone distribution. Switchover-triggered distribution distributes the active zone set, zone database, zone policy, and hard zoning status.

For both switchover-triggered distribution and zone distribution in enhanced zoning mode, the SFC request carries the zone policy whether or not the SFC request carries the active zone set and zone database.

For zone distribution in enhanced zoning mode, the SFC request always carries hard zoning status.

For zone distribution caused by a switchover from basic zoning to enhanced zoning, the SFC request carries hard zoning status.

For zone distribution caused by a switchover from enhanced zoning to basic zoning, the SFC request does not carry hard zoning status.

Zone merge in basic zoning mode

When two fabrics are merged, zone data might exist in both fabrics. In this case, zone data needs to be merged. Zone data to be merged includes the active zone set and zone database.

Zone merge in basic zoning mode is subject to merge types. The following merge types are provided:

· Complete merge—Merges both the active zone sets and zone databases.

· Incomplete merge—Merges only the active zone sets.

When initiating a merge process, the switch checks its local merge type.

· If it is configured with complete merge, it sends packets with both the active zone set and zone database.

· If it is configured with incomplete merge, it sends packets with only the active zone set.

The merged switches merge all received data, regardless of their merge types.

NOTE:

The pWWN is a preferred choice over FC addresses to identify zone members, because FC addresses might change at fabric merge and the merge result might not be as expected by users.

Zone merge process

When a switch discovers a new neighbor (the link layer module discovers neighbors and notifies the zone module), it starts a merge process with the neighbor. If the data changes after merging, the switch sends the changed data to neighbor switches until all switches in the fabric update their data.

During the merge, the switch sends Merge Request Resource Allocation (MRRA) requests to negotiate the size of data transmitted. Then, the switch sends Merge Request (MR) packets containing data to be merged to neighbor switches.

Figure 26 Zone merge process between two switches

The zone merge process is as follows:

1. Switch A and Switch B are new neighbors to each other. Suppose that Switch A first initiates a merge to Switch B.

a. Switch A sends an MRRA request carrying the size of its data to be merged to Switch B.

b. After receiving the MRRA request, Switch B determines whether to accept the merge according to its local data size.

- If the size of the data to be merged is acceptable, it replies with an ACC packet.

- If the size of the data to be merged is not acceptable, it replies with an RJT packet.

c. After receiving the ACC packet, Switch A sends an MR request containing its zone data to Switch B.

d. After receiving the MR request, Switch B obtains the zone data and merges it with its local zone data. Then, it replies with an ACC packet for a successful merge or with an RJT packet containing the cause of failure for a failed merge.

2. After the merge process initiated by Switch A is complete, the following rules apply:

? If the local data of Switch B is the same as or a subset of the local data of Switch A, Switch B ends the merge process with Switch A.

? Otherwise, Switch B initiates a merge process with Switch A.

The merge process is the same as the process initiated by Switch A to Switch B, as shown in steps 5, 6, 7, and 8 in Figure 26.

3. After the merge process initiated by Switch A is complete, Switch B initiates a merge process to all its neighbors. This synchronizes Switch B's local database changes resulting from the merge to the entire fabric.

4. Two 1-way merge processes can ensure data consistency between Switch A and Switch B.

NOTE:

Consistent active zone sets among switches can be achieved by a merge. Consistent zone databases achieved after a merge, however, require all participating switches to be configured with complete merge.

Zone merge rules

Table 5 Zone merge rules

Local database	Neighbor database	Merge status	Merge result
The zone databases contain zone sets with the same name, but zones in these zone sets have different names.		Successful	The union of the local database and neighbor database. Zone sets with the same name are merged.
The zone databases contain zone sets with different names.		Successful	The union of the local database and neighbor database. All zone sets with different names are retained.
The zone databases contain zones or zone aliases with different names.		Successful	The union of the local database and neighbor database. All zone sets or zone aliases with different names are retained.
The Pairwise feature status is different for one or more of the zones with the same name in the active zone sets or zone databases.		Failed	Both databases remain unchanged.
The databases contain zones or zone aliases with the same name but with one or more different zone members.		Failed	Both databases remain unchanged.
Zones with the same name in the active zone set contain the same zone members, but one or more of these members have different roles. Or Zones or zone aliases with the same name in the zone databases contain the same zone members, but one or more of these members have different roles.		Failed	Both databases remain unchanged.
Empty	Contain data	Successful	The neighbor database overwrites the local database.
Contain data	Empty	Successful	The local database overwrites the neighbor database.

NOTE:

· If two active zone sets have different names, the larger name obtained by string comparison acts as the name of the active zone set after merging.

· If the active zone sets on two switches fail to merge, the two switches isolate their connecting link by bringing down the relevant ports in the VSAN, in addition to keeping their zone databases unchanged.

Zone merge in enhanced zoning mode

Enhanced zoning has the following differences from basic zoning in zone merge:

· Enhanced zoning always performs complete merges, regardless of the merge type.

· The MR request carries hard zoning status and a merge flag field in addition to the active zone set and zone database.

The merge flag field includes the merge control mode and default zone policy.

· In the event of a merge failure, the link between participating switches is isolated, and both zone databases remain unchanged.

· Merge rules are stricter.

Merge rules in enhanced zoning mode are as follows:

· If either the merge control mode or default zone policy is different from that in the local zone database, the merge will fail.

· If both the merge control mode and default zone policy are the same as that in the local zone database, the following rules apply:

? If the merge control mode is Restrict, the system checks whether the data carried in the MR request is the same as the local zone database.

- If the data is the same as the local zone database, the merge will succeed, and both databases remain unchanged.

- If the data is different from the local zone database, the merge will fail.

? If the merge control mode is Allow, the following rules apply:

- If the two active zone sets contain zones with the same name but with one or more different zone members, the merge will fail.

- If the two zone databases contain zone sets, zones, or zone aliases with the same name but one or more different members, the merge will fail.

- If the two zone databases contain zone members with the same name but one or more of these members have different roles, the merge will fail.

- If the two zone databases contain zones with the same name, but the Pairwise feature status is different for one or more of these zones, the merge will fail.

- If hard zoning status is different in the two zone databases, the merge will fail.

- If the two active zone sets contain zones with different names and none of the preceding conditions exist, the merge will succeed. The merged active zone set is the union of the two active zone sets.

- If the two zone databases contain zone sets, zones, or zone aliases with different names and none of the preceding conditions exist, the merge will succeed. The merged zone database is the union of the two zone databases.

Access control

For a server to access a disk device through the name service, the server and the disk device must be in one zone of the active zone set. Only members in the same zone can access each other.

FC zone configuration task list

Tasks at a glance	Remarks
(Required.) Configuring a zoning mode	N/A
(Required.) Configuring the Pairwise feature	This task can be performed only in enhanced zoning mode.
(Optional.) Configuring zone aliases	N/A
(Required.) Configuring zones	N/A
(Required.) Configuring zone sets	N/A
(Required.) Configuring the default zone policy	N/A
(Required.) Configuring the zone distribution and merge type	This task can be performed only in basic zoning mode.
(Required.) Configuring a merge control mode	This task can be performed only in enhanced zoning mode.
(Optional.) Enabling hard zoning	N/A
(Required.) Activating a zone set and distributing it to the entire fabric	N/A
(Optional.) Triggering a complete distribution	N/A
(Optional.) Renaming zone aliases, zones, and zone sets	N/A
(Optional.) Copying zone aliases, zones, and zone sets	N/A
(Optional.) Deleting the zone database	N/A
(Optional.) Enabling SNMP notifications	N/A

NOTE:

· You cannot modify zone configurations during zone distribution or merge.

· In a fabric, only one manager switch can initiate distribution at a time. The next distribution can be initiated only after the previous one is complete.

Configuring a zoning mode

Two zoning modes are available: basic zoning and enhanced zoning. By default, the basic zoning mode is enabled.

A zoning mode switchover causes a zone distribution to ensure zoning mode consistency across the fabric. You can switch from basic zoning to enhanced zoning only if the following conditions are met:

· All switches in the fabric support the enhanced zoning mode.

· No invalid static routes exist in the fabric.

After enhanced zoning is enabled on a switch, the switch checks ESS negotiation results for enhanced zoning support on other switches.

The switch performs ESS negotiation with all switches that appear in its routing table as destinations, including unreachable destinations in invalid static routes. The switch assumes that unreachable destinations do not support enhanced zoning.

When you switch between zoning modes, the system prints a message that the switchover will cause a zone distribution.

· If you enter No, no operation is performed.

· If you enter Yes, the local switch changes the zoning mode and generates the corresponding configuration. Then, the local switch distributes the change to the entire fabric. If the distribution fails, the system prints a log message, but the change takes effect on the local switch. In this case, you must manually trigger a complete distribution to ensure zoning mode consistency across the fabric.

For a switchover from enhanced zoning to basic zoning, if the size of the active zone set exceeds the system limit in basic zoning mode, the switchover fails.

To configure a zoning mode:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Configure a zoning mode.	· Enable the enhanced zoning mode: zone mode enhanced · Enable the basic zoning mode: undo zone mode enhanced	By default, the basic zoning mode is enabled.

Configuring the Pairwise feature

This feature allows a zone member to access only members with a different role in the same zone. A member with both roles can access both initiator members and target members.

After you disable this feature for a zone, all members in the zone can access each other.

This feature can be configured only in enhanced zoning mode.

To configure the Pairwise feature:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Enter zone view.	zone name zone-name	N/A
4. Configure the Pairwise feature.	· Enable the Pairwise feature: pairwise-zoning enable · Disable the Pairwise feature: undo pairwise-zoning enable	By default, the Pairwise feature is disabled.

Configuring zone aliases

You can specify members of a zone alias by using their FC addresses, pWWNs, or fWWNs. An fWWN is the WWN of an F_Port. An F_Port member represents all N_Ports that log in through the F_Port. Any specified N_Port members can be indirectly connected to the switch.

You can specify the role of a member as an initiator, a target, or both when adding the member. The role can be configured only in enhanced zoning mode and takes effect only when the Pairwise feature is enabled.

To configure a zone alias:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Create a zone alias and enter its view.	zone-alias name zone-alias-name	By default, no zone alias exists.
4. Add a member to the zone alias.	member { fcid fcid \| fwwn fwwn \| pwwn pwwn } [ initiator \| target ]	By default, no member exists in a new zone alias.

Configuring zones

You can specify members of a zone by using their FC addresses, pWWNs, fWWNs, or zone aliases. An fWWN is the WWN of an F_Port. An F_Port member represents all N_Ports that log in through the F_Port. A zone alias represents a group of N_Ports. Any specified N_Port members can be indirectly connected to the switch. A member can belong to more than one zone.

To configure a zone:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Create a zone and enter its view.	zone name zone-name	By default, no zone exists.
4. Add a member to the zone.	member { { fcid fcid \| fwwn fwwn \| pwwn pwwn } [ initiator \| target ] \| zone-alias zone-alias-name }	By default, no member exists in a new zone.

Configuring a peer zone

This feature allows you to convert a common zone to a peer zone. To convert a common zone to a peer zone, you must first enable Smart SAN for FC/FCoE.

A zone enabled with the Pairwise feature cannot be converted to a peer zone.

To configure a peer zone:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Enter zone view.	zone name zone-name	By default, a zone is a common zone.
4. Convert the common zone to a peer zone and specify the principal member for the peer zone.	zone-type peer-zone principal-member wwn	The principal member must be a port on a node. This command sets the principal member to a target. This command deletes the settings for the common zone.

Configuring zone sets

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Create a zone set (if the zone set does not exist) and enter its view.	zoneset name zoneset-name	By default, no zone set exists.
4. Add a zone to the zone set.	member zone-name	By default, no zone exists in a new zone set.

Configuring the default zone policy

In enhanced zoning mode, the switch distributes the default zone policy with other zone data. In basic zoning mode, you must manually configure a consistent default zone policy across the fabric.

After the switch performs a zoning mode switchover, it also distributes the default zone policy with other zone data.

To configure the default zone policy:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Permit members in the default zone to access each other.	zone default-zone permit	Use one of the commands. By default, default zone members are not permitted to access each other.
4. Deny members in the default zone from accessing each other.	undo zone default-zone permit

Configuring the zone distribution and merge type

Complete distribution (or merge) distributes (or merges) both the active zone set and zone database. Incomplete distribution (or merge) distributes (or merges) only the active zone set.

This feature is supported only in basic zoning mode. In enhanced zoning mode, the zone distribution and merge type is always complete, and this feature is not supported.

The configured distribution type applies to distribution operations triggered by the zoneset activate command instead of the zoneset distribute command.

The configured merge type applies to all merge operations.

To configure the zone distribution and merge type:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Configure zone distribution and merge types as complete.	zoneset distribute full	The default setting is incomplete.

Configuring a merge control mode

Two merge control modes are available: Restrict and Allow. For information about these two modes, see "Zone merge in enhanced zoning mode."

In enhanced zoning mode, the merge control mode affects the result of a merge operation. Also, a merge operation is allowed only when the merge control mode is the same on both participating switches. Otherwise, the merge operation fails, and the link connecting the participating switches is isolated.

This feature is supported only in enhanced zoning mode. To ensure a consistent merge control mode across the fabric, use the zone activate or zone distribute command after you configure a merge control mode.

To configure a merge control mode:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Configure a merge control mode.	· Configure the merge control mode as Restrict: zone merge-control restrict · Configure the merge control mode as Allow: undo zone merge-control restrict	The default merge control mode is Allow.

Enabling hard zoning

Overview

Switches implement zone access control in one of the following methods:

· Soft zoning—When a registered node queries the nodes in the current fabric through generic service packets, soft zoning filters the nodes based on zone rules and returns only the matching nodes. Soft zoning is always in effect.

Because soft zoning is used only when a node accesses other nodes, it can restrict only the result of queries that a node initiates to switches, and it cannot directly control the underlayer traffic. When a node performs traffic attacks against the node that should be filtered by zone rules, soft zoning cannot perform access control for the node.

· Hard zoning—Hard zoning converts the zone configurations into lower-layer driver rules and deploys the rules to the hardware to form hardware zone rules. Then, the traffic in the switch is forwarded strictly based on hardware zone rules. Hard zoning takes effect only when the hardware resources are sufficient for deploying zone rules.

When the underlayer resources are not sufficient for deploying the hardware zone rules of the current VSAN, the system performs the following operations:

? Clears all deployed hardware zone rules in order to keep the integrity of rules.

? Automatically disables hard zoning.

To improve the security for a VSAN, you can enable hard zoning for the VSAN. After hard zoning is enabled for a VSAN, the system triggers deploying all zone rules of the VSAN. After hard zoning is manually disabled for a VSAN, the system clears the hardware zone rules already deployed for the VSAN and stops deploying new zone rules for the VSAN.

The two methods can work separately and supplement each other. They work together to implement node access control based on the zone configurations.

Configuration restrictions and guidelines

When you configure hard zoning, follow these restrictions and guidelines:

· When soft zoning is enough for meeting the access control requirements of a VSAN, you can disable hard zoning for the VSAN to save the hardware entry resources.

· In basic zoning mode, you must manually configure hard zoning to ensure consistency across the fabric. In enhanced zoning mode, zone distribution distributes hard zoning status with other zone data.

· To view the hard zoning status, use the display zone status command.

· Do not configure the zone hard-zoning enable command when the switch is merging or distributing zones.

Configuration procedure

To enable hard zoning:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Enable hard zoning.	zone hard-zoning enable	By default, hard zoning is enabled.

Activating a zone set and distributing it to the entire fabric

You can use the zoneset activate command to activate a zone set as the active zone set on a switch and distribute the active zone set to the entire fabric. Then, the active zone set is used to implement access control. The modifications to the active zone set do not take effect until reactivation.

The zone set to be activated must have been created and must contain at least one N_Port member. Only one active zone set can exist in a VSAN. In basic zoning mode, if the size of the active zone set exceeds the system limit, the activation fails.

In basic zoning mode, the distribution type specified by using the zoneset distribute full command applies to distribution operations triggered by the zoneset activate command. In enhanced zoning mode, the zoneset distribute full command is not supported, and the distribution type is always complete.

In either basic or enhanced zoning mode, the system prints a log message if the distribution fails because of a network fault. To ensure a consistent active zone set across the fabric, reactivate the zone set after the network fault is fixed.

To activate a zone set and distribute it to the entire fabric:

Step	Command
1. Enter system view.	system-view
2. Enter VSAN view.	vsan vsan-id
3. Activate a zone set as the active zone set and distribute it to the entire fabric.	zoneset activate name zoneset-name

NOTE:

Active zone set information will not contain the alias names of zone members. If a zone in the active zone set has members with a zone alias, the non-overlapping N_Port members in the zone alias are added to the zone. You can view the zone member change by using the display zoneset active command.

Triggering a complete distribution

Use the zoneset distribute command to trigger a one-time complete distribution, which distributes both the active zone set and zone database. In enhanced zoning mode, the zone policy and hard zoning status are also distributed.

After activating a zone set as the active zone set by using the zoneset activate command, you can modify the zone database configuration. The zoneset distribute command distributes the active zone set and the modified zone database to the entire fabric without changing the active zone set.

If the distribution fails because of a network fault, the system prints a log message. To ensure zone data consistency across the fabric, trigger a new complete distribution after the network fault is fixed.

To trigger a complete distribution:

Step	Command
1. Enter system view.	system-view
2. Enter VSAN view.	vsan vsan-id
3. Trigger a complete distribution.	zoneset distribute

Renaming zone aliases, zones, and zone sets

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Rename a zone alias.	zone-alias rename old-name new-name	The zone alias to be renamed must have been created, and the new zone alias must not have been created.
4. Rename a zone.	zone rename old-name new-name	The zone to be renamed must have been created, and the new zone must not have been created.
5. Rename a zone set.	zoneset rename old-name new-name	The zone set to be renamed must have been created, and the new zone set must not have been created.

Copying zone aliases, zones, and zone sets

You can create a zone alias, zone, or zone set by copying an existing one. The source and the destination have the same contents but different names.

To copy a zone alias, zone, and zone set:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Copy an existing zone alias to create a new zone alias.	zone-alias clone src-name dest-name	The source zone alias must have been created, and the destination zone alias must not have been created.
4. Copy an existing zone to create a new zone.	zone clone src-name dest-name	The source zone must have been created, and the destination zone must not have been created.
5. Copy an existing zone set to create a new zone set.	zoneset clone src-name dest-name	The source zone set must have been created, and the destination zone set must not have been created.

Deleting the zone database

You can delete the zone database for the specified VSAN, including all zone sets, zones, and zone aliases, but not the active zone set.

To delete the zone database:

Step	Command
1. Enter system view.	system-view
2. Enter VSAN view.	vsan vsan-id
3. Delete the zone database.	delete zone database all

Enabling SNMP notifications

To report critical zoning events to an NMS, enable SNMP notifications for the zoning module. For zoning event notifications to be sent correctly, you must also configure SNMP on the device. For more information about SNMP configuration, see the network management and monitoring configuration guide for the device.

To enable SNMP notifications for the zoning module:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enable SNMP notifications for the zoning module.	snmp-agent trap enable fc-zone [ activation-completed \| defaultzone-change \| hardzone-change \| merge-failed \| merge-succeeded ] *	By default, SNMP notifications for the zoning module are disabled.

Displaying and maintaining FC zones

Execute display commands in any view and reset commands in user view.

Task	Command
Display zone alias information.	display zone-alias [ [ name zone-alias-name ] vsan vsan-id ]
Display zone information.	display zone [ [ name zone-name ] vsan vsan-id ]
Display zone set information.	display zoneset [ [ name zoneset-name ] vsan vsan-id ]
Display information about the active zone set.	display zoneset active [ vsan vsan-id ]
Display parent information for a zone member.	display zone member { fcid fcid \| pwwn pwwn \| zone-alias zone-alias-name } [ vsan vsan-id ]
Display the running status and configuration of an FC zone.	display zone status [ vsan vsan-id ]
Display zone packet statistics.	display zone statistics [ vsan vsan-id ]
Clear zone packet statistics.	reset zone statistics [ vsan vsan-id ]

FC zone configuration example

Network requirements

As shown in Figure 27, all nodes have registered with the switches.

Configure access control in VSAN 1 to meet the following requirements:

· Server A cannot access any disk but might need to subsequently.

· Server B can access Disks A, B, and C.

· Server C can access Disks B and C.

· Servers cannot access each other.

Figure 27 Network diagram

Requirements analysis

To meet the network requirements, divide VSAN 1 into three zones as follows:

· Assign Server A to zone Zone1.

· Assign Server B and Disks A, B, and C to zone Zone2.

· Assign Server C and Disks B and C to zone Zone3.

· Enable Pairwise for Zone2, configure Server B as an initiator, and configure Disks A, B, and C as targets.

· Enable Pairwise for Zone3, configure Server C as an initiator, and configure Disks B and C as targets.

· Create a zone alias named Alias1, which contains Disks B and C, to simplify the configuration.

· Create a zone set named Zoneset1, which contains zones Zone1, Zone2, and Zone3, and activate it.

Configuration procedure

This section describes only FC zone configurations on Switch A. You do not need to configure FC zones on Switch B.

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchA> system-view

[SwitchA] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchA] save

[SwitchA] quit

<SwitchA> reboot

# Configure the switch to operate in FCF mode.

<SwitchA> system-view

[SwitchA] fcoe-mode fcf

# Enable the enhanced zoning mode in VSAN 1.

[SwitchA] vsan 1

[SwitchA-vsan1] zone mode enhanced

The zoning database in this switch would be distributed throughout the fabric. Continue? [Y/N]:y

[SwitchA-vsan1]

# Create a zone alias named Alias1.

[SwitchA-vsan1] zone-alias name Alias1

# Add pWWN 22:33:44:55:66:77:88:99 (Disk B) and FC address 020004 (Disk C) as its target members.

[SwitchA-vsan1-zone-alias-Alias1] member pwwn 22:33:44:55:66:77:88:99 target

[SwitchA-vsan1-zone-alias-Alias1] member fcid 020004 target

[SwitchA-vsan1-zone-alias-Alias1] quit

# Create a zone named Zone1, and specify FC address 010001 as its member.

[SwitchA-vsan1] zone name Zone1

[SwitchA-vsan1-zone-Zone1] member fcid 010001

[SwitchA-vsan1-zone-Zone1] quit

# Create a zone named Zone2, and enable the Pairwise feature for Zone2.

[SwitchA-vsan1] zone name Zone2

[SwitchA-vsan1-zone-Zone2] pairwise-zoning enable

# Specify FC address 010002 and pWWN 11:22:33:44:55:66:77:88 as its initiator member and target member, respectively.

[SwitchA-vsan1-zone-Zone2] member fcid 010002 initiator

[SwitchA-vsan1-zone-Zone2] member pwwn 11:22:33:44:55:66:77:88 target

# Add zone alias Alias1 to Zone2 as a member.

[SwitchA-vsan1-zone-Zone2] member zone-alias Alias1

[SwitchA-vsan1-zone-Zone2] quit

# Create the zone Zone3, and enable the Pairwise feature for Zone3.

[SwitchA-vsan1] zone name Zone3

[SwitchA-vsan1-zone-Zone3] pairwise-zoning enable

# Specify FC address 010003 as an initiator member of Zone3.

[SwitchA-vsan1-zone-Zone3] member fcid 010003 initiator

# Add zone alias Alias1 to Zone3 as a member.

[SwitchA-vsan1-zone-Zone3] member zone-alias Alias1

[SwitchA-vsan1-zone-Zone3] quit

# Create a zone set named Zoneset1 and add zones Zone1, Zone2, and Zone3 as its members.

[SwitchA-vsan1] zoneset name Zoneset1

[SwitchA-vsan1-zoneset-Zoneset1] member Zone1

[SwitchA-vsan1-zoneset-Zoneset1] member Zone2

[SwitchA-vsan1-zoneset-Zoneset1] member Zone3

[SwitchA-vsan1-zoneset-Zoneset1] quit

# Configure the zone distribution and merge type as complete.

[SwitchA-vsan1] zoneset distribute full

# Activate a zone set as the active zone set and distribute it to the entire fabric.

[SwitchA-vsan1] zoneset activate name Zoneset1

Verifying the configuration

Perform all verification tasks on Switch B.

# Display zone set information for VSAN 1.

<SwitchB> display zoneset vsan 1

VSAN 1:

zoneset name Zoneset1

zone name Zone1

fcid 0x010001

zone name Zone2

fcid 0x010002 initiator

pwwn 11:22:33:44:55:66:77:88 target

zone-alias Alias1

fcid 0x020004 target

pwwn 22:33:44:55:66:77:88:99 target

zone name Zone3

fcid 0x010003 initiator

zone-alias Alias1

fcid 0x020004 target

pwwn 22:33:44:55:66:77:88:99 target

# Display information about Zone 2 in VSAN 1.

<SwitchB> display zone name Zone2 vsan 1

VSAN 1:

zone name Zone2

fcid 0x010002 initiator

pwwn 11:22:33:44:55:66:77:88 target

zone-alias Alias1

fcid 0x020004 target

pwwn 22:33:44:55:66:77:88:99 target

# Display information about all zone aliases.

<SwitchB> display zone-alias

VSAN 1:

zone-alias name Alias1

fcid 0x020004 target

pwwn 22:33:44:55:66:77:88:99 target

# Display the zone or zone alias to which 020004 (FC address type) belongs.

<SwitchB> display zone member fcid 020004

fcid 0x020004

VSAN 1:

zone-alias Alias1

zone Zone2

zone Zone3

# Display information about the active zone set in VSAN 1.

<SwitchB> display zoneset active vsan 1

VSAN 1:

zoneset name Zoneset1

zone name Zone1

*fcid 0x010001

zone name Zone2

*fcid 0x010002

*fcid 0x020004

*fcid 0x020005 [pwwn 22:33:44:55:66:77:88:99]

*fcid 0x020006 [pwwn 11:22:33:44:55:66:77:88]

zone name Zone3

*fcid 0x010003

*fcid 0x020004

*fcid 0x020005 [pwwn 22:33:44:55:66:77:88:99]

Configuring NPV

Overview

NPV enables an FC SAN to accommodate more than 239 switches.

NPV switches forward traffic from nodes to the core switch.

Figure 28 shows a typical NPV network diagram.

Figure 28 NPV network diagram

NOTE:

An NPV switch must be directly connected to the core switch.

Downlink interface and downlink

A downlink interface, also known as a server interface, is an interface through which an NPV switch connects to a node. It must be a VFC interface operating in F mode.

A downlink is a link from an NPV switch to its node.

Each downlink interface is uniquely mapped to an operational uplink interface. All traffic from the node connected to the downlink interface is forwarded to the core switch through the uplink interface.

Uplink interface and uplink

An uplink interface, also known as an external interface, is the interface through which an NPV switch connects to the core switch. It must be a VFC interface operating in NP mode.

An uplink is a link from an NPV switch to the core switch.

When the uplink becomes operational, the NPV switch sends a fabric login (FLOGI) packet to the core switch for registration. The core switch assigns the uplink interface (NP_Port) an FC address. Then, the NPV switch registers itself with the name server on the core switch. When receiving a packet from a node, the NPV switch performs the following operations:

· Forwards the packet to the core switch through the mapped uplink interface.

· Passes the response packet from the core switch to the node through the downlink interface.

Downlink-to-uplink interface mappings

NPV switches automatically map downlink interfaces to uplink interfaces. Before a downlink interface is brought up, the NPV switch maps it to the uplink interface to which the minimum number of downlink interfaces is mapped.

Typically, automatic mapping can meet your requirements. When a downlink interface must be connected to a fabric through the specified uplink interfaces, you can manually map the downlink interface to the uplink interfaces. After you configure the mapping, the downlink interface can be mapped to only the configured uplink interfaces. If none of the configured uplink interfaces is operational, the downlink interface cannot be operational.

A configured mapping selects the uplink interface with the minimum load from configured uplink interfaces and then maps the downlink interface to it.

After a mapping is established, all traffic from the downlink interface is forwarded through the uplink interface.

Load balancing

Manual load balancing

When a new uplink interface becomes operational, the NPV switch does not perform a remapping for load balancing by default. In the event of remapping, the NPV switch reinitializes downlink interfaces and disrupts existing uplink-to-downlink interface mappings. Then, the nodes connected to downlink interfaces register with the core switch again. This causes traffic interruption to the nodes.

You can manually trigger a remapping for better load balancing when a new uplink interface becomes operational. In this case, the NPV switch reinitializes only some of the downlink interfaces.

The NPV switch uses the following process to select the downlink interfaces to be reinitialized:

1. The NPV switch calculates the average uplink interface load by using the formula: total number of downlink interfaces/ total number of uplink interfaces.

2. The NPV switch identifies the uplink interfaces that exceed the average uplink interface load.

3. The NPV switch reinitializes the first automatically mapped downlink interfaces of each identified uplink interface. The number of downlink interfaces to be reinitialized for an uplink interface is the total number of downlink interfaces for the uplink interface minus the average uplink interface load. If the average uplink interface load is not an integer, it is rounded down to the nearest integer.

4. If an uplink interface has no automatically mapped downlink interfaces, the NPV switch does not reinitialize its downlink interfaces.

Automatic load balancing

Automatic load balancing uses the same process used in manual load balancing to select the downlink interfaces to be reinitialized. After automatic load balancing is enabled, the system starts a delay timer when detecting that a new uplink interface becomes operational. When the timer expires, the system automatically redistributes downlink interfaces across uplink interfaces. If another uplink interface becomes operational before the timer expires, the system resets the timer. The delay timer mechanism reduces network flapping caused by up/down events of uplink interfaces.

NPV configuration task list

Tasks at a glance	Remarks
(Required.) Configuring the switch to operate in NPV mode	See "FCoE configuration restrictions and guidelines."
(Required.) Configuring uplink interfaces and downlink interfaces	N/A
(Optional.) Configuring downlink-to-uplink interface mappings	N/A
(Optional.) Manually initiating a load-balancing process	N/A
(Optional.) Configuring automatic load balancing	N/A

Configuring uplink interfaces and downlink interfaces

After configuring the switch to operate in NPV mode, configure the uplink interfaces and downlink interfaces.

Configuring uplink interfaces

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VFC interface view.	interface vfc interface-number	This VFC interface is connected to the core switch.
3. Set the mode of the VFC interface to NP.	fc mode np	The default setting is F mode.

Configuring downlink interfaces

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VFC interface view.	interface vfc interface-number	This VFC interface is connected to a node.
3. Set the mode of the VFC interface to F.	fc mode f	The default setting is F mode.

Configuring downlink-to-uplink interface mappings

CAUTION:

If an uplink interface mapped by a downlink interface is not in the configured mappings, the switch initializes the downlink interface, resulting in traffic interruption.

NPV switches automatically map downlink interfaces to uplink interfaces. Typically, automatic mapping can meet your requirements. When a downlink interface must be connected to a fabric through the specified uplink interfaces, you can manually map the downlink interface to the uplink interfaces.

After you configure the mapping, the downlink interface can be mapped to only the configured uplink interfaces. If none of the configured uplink interfaces is operational, the downlink interface cannot be operational. A configured mapping selects the uplink interface with the minimum load from configured uplink interfaces and then maps the downlink interface to it.

To configure a downlink-to-uplink interface mapping:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Configure a downlink-to-uplink interface mapping.	npv traffic-map server-interface interface-type interface-number external-interface interface-type interface-number	By default, no mapping is configured.

Manually initiating a load-balancing process

Step	Command
1. Enter system view.	system-view
2. Enter VSAN view.	vsan vsan-id
3. Manually initiate a load-balancing process.	npv load-balance disruptive

Configuring automatic load balancing

This feature might trigger a load balancing process when a new uplink interface become operational, which causes traffic disruption.

When this feature is disabled, downlink-to-uplink interface mappings are not affected.

If the link layer state of uplink interfaces is stable, set the delay timer to a smaller value. Otherwise, set the delay timer to a greater value.

To configure automatic load balancing:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VSAN view.	vsan vsan-id	N/A
3. Enable automatic load balancing.	npv auto-load-balance enable	By default, automatic load balancing is disabled.
4. Set the delay timer for automatic load balancing.	npv auto-load-balance interval interval	The default setting is 30 seconds.

Displaying and maintaining NPV

Execute display commands in any view.

Task	Command
Display the login information for interfaces.		display fc nport [ interface interface-type interface-number ]
Display the nodes on downlink interfaces and their mapped uplink interfaces.	display npv login [ vsan vsan-id ] [ interface interface-type interface-number ] display npv login [ vsan vsan-id ] count
Display the traffic mapping information.	display npv traffic-map [ vsan vsan-id ] [ interface interface-type interface-number ]
Display status information.	display npv status [ vsan vsan-id ]

NPV configuration example

Network requirements

As shown in Figure 29, configure the edge switch (Switch A) as an NPV switch to expand the network.

Figure 29 Network diagram

Configuration procedure

1. Configure Switch A:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchA> system-view

[SwitchA] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchA] save

[SwitchA] quit

<SwitchA> reboot

# Configure the switch to operate in NPV mode.

<SwitchA> system-view

[SwitchA] fcoe-mode npv

# Create VSAN 1.

[SwitchA] vsan 1

[SwitchA-vsan1] quit

# Create interface VFC 1.

[SwitchA] interface vfc 1

# Bind VFC 1 to interface Ten-GigabitEthernet 1/0/1.

[SwitchA-Vfc1] bind interface ten-gigabitethernet 1/0/1

# Assign VFC 1 to VSAN 1 as a trunk port.

[SwitchA-Vfc1] port trunk vsan 1

[SwitchA-Vfc1] quit

# Configure Ten-GigabitEthernet 1/0/1 as a trunk port, and assign the port to VLAN 10.

[SwitchA] interface ten-gigabitethernet 1/0/1

[SwitchA-Ten-GigabitEthernet1/0/1] port link-type trunk

[SwitchA-Ten-GigabitEthernet1/0/1] port trunk permit vlan 10

[SwitchA-Ten-GigabitEthernet1/0/1] quit

# Create interface VFC 2.

[SwitchA] interface vfc 2

# Bind VFC 2 to interface Ten-GigabitEthernet 1/0/2.

[SwitchA-Vfc2] bind interface ten-gigabitethernet 1/0/2

# Assign VFC 2 to VSAN 1 as a trunk port.

[SwitchA-Vfc2] port trunk vsan 1

[SwitchA-Vfc2] quit

# Configure Ten-GigabitEthernet 1/0/2 as a trunk port, and assign the port to VLAN 10.

[SwitchA] interface ten-gigabitethernet 1/0/2

[SwitchA-Ten-GigabitEthernet1/0/2] port link-type trunk

[SwitchA-Ten-GigabitEthernet1/0/2] port trunk permit vlan 10

[SwitchA-Ten-GigabitEthernet1/0/2] quit

# Create interface VFC 3.

[SwitchA] interface vfc 3

# Bind VFC 3 to interface Ten-GigabitEthernet 1/0/3.

[SwitchA-Vfc3] bind interface ten-gigabitethernet 1/0/3

# Assign VFC 3 to VSAN 1 as a trunk port.

[SwitchA-Vfc3] port trunk vsan 1

[SwitchA-Vfc3] quit

# Configure Ten-GigabitEthernet 1/0/3 as a trunk port, and assign the port to VLAN 10.

[SwitchA] interface ten-gigabitethernet 1/0/3

[SwitchA-Ten-GigabitEthernet1/0/3] port link-type trunk

[SwitchA-Ten-GigabitEthernet1/0/3] port trunk permit vlan 10

[SwitchA-Ten-GigabitEthernet1/0/3] quit

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 1.

[SwitchA] vlan 10

[SwitchA-vlan10] fcoe enable vsan 1

[SwitchA-vlan10] quit

# Configure the mode of the uplink port VFC 3 as NP.

[SwitchA] interface vfc 3

[SwitchA-Vfc3] fc mode np

[SwitchA-Vfc3] quit

# Configure the mode of the downlink ports VFC 1 and VFC 2 as F.

[SwitchA] interface vfc 1

[SwitchA-Vfc1] fc mode f

[SwitchA-Vfc1] quit

[SwitchA] interface vfc 2

[SwitchA-Vfc2] fc mode f

[SwitchA-Vfc2] quit

2. Configure Switch B:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchB> system-view

[SwitchB] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchB] save

[SwitchB] quit

<SwitchB> reboot

# Configure the switch to operate in FCF mode.

<SwitchB> system-view

[SwitchB] fcoe-mode fcf

# Create VSAN 1.

[SwitchB] vsan 1

[SwitchB-vsan1] quit

# Create interface VFC 3.

[SwitchB] interface vfc 3

# Configure the mode of VFC 3 as F.

[SwitchB-Vfc3] fc mode f

# Bind VFC 3 to interface Ten-GigabitEthernet 1/0/3.

[SwitchB-Vfc3] bind interface ten-gigabitethernet 1/0/3

# Assign VFC 3 to VSAN 1 as a trunk port.

[SwitchB-Vfc3] port trunk vsan 1

[SwitchB-Vfc3] quit

# Configure Ten-GigabitEthernet 1/0/3 as a trunk port, and assign the port to VLAN 10.

[SwitchB] interface ten-gigabitethernet 1/0/3

[SwitchB-Ten-GigabitEthernet1/0/3] port link-type trunk

[SwitchB-Ten-GigabitEthernet1/0/3] port trunk permit vlan 10

[SwitchB-Ten-GigabitEthernet1/0/3] quit

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 1.

[SwitchB] vlan 10

[SwitchB-vlan10] fcoe enable vsan 1

[SwitchB-vlan10] quit

Verifying the configuration

# Display the nodes on downlink interfaces and their mapped uplink interfaces.

[SwitchA] display npv login

Server External

Interface VSAN FCID Node WWN Port WWN Interface

Vfc1 1 0x010001 21:00:00:00:c8:00:e4:30 20:00:00:00:c8:60:e4:9a Vfc3

Vfc2 1 0x010002 21:00:00:00:c9:00:e4:30 20:00:00:00:c9:60:e4:9a Vfc3

# Display information about uplink and downlink interfaces on Switch A.

[SwitchA] display npv status

External Interfaces:

Interface: Vfc3 VSAN tagging mode: Tagging

VSAN State FCID

1 Up 0x010000

Number of External Interfaces: 1

Server Interfaces:

Interface : Vfc1 VSAN tagging mode: Tagging

VSAN State

1 Up

Interface : Vfc2 VSAN tagging mode: Tagging

VSAN State

1 Up

Number of Server Interfaces: 2

# Display the traffic mapping information on NPV switch Switch A.

[SwitchA] display npv traffic-map

NPV traffic map information of VSAN 1:

Server Interface External Interface

Vfc1 Vfc3

Vfc2 Vfc3

Configuring FIP snooping

Overview

To communicate with devices in the FC SAN, a node must register with an FC fabric. An FCF switch has point-to-point connections with nodes. An FCF switch brings up an interface connected to a node only after the node completes fabric login on the interface.

In an FCoE implementation, Transit switches can be present between ENodes and FCF switches, so the connections between ENodes and FCF switches are no longer point-to-point. In this case, a node that has not performed fabric login might communicate with the FC SAN. For example, two ENodes are connected to one FCF switch through a Transit switch. After one ENode has registered with the FCF switch and the corresponding interface is brought up, the other ENode can also communicate with the FC SAN.

FCoE Initialization Protocol Snooping (FIP snooping) is a security feature that can run only on Transit switches in an FCoE network. By checking source MAC addresses of FCoE frames, FIP snooping enables a Transit switch to forward FCoE frames only between the following elements:

· An ENode that has performed fabric login.

· The FCF switch that has accepted its fabric login.

FIP snooping network diagram

Figure 30 shows a typical FIP snooping network diagram.

Figure 30 Network diagram

Ethernet interfaces on a Transit switch can operate in ENode or FCF mode. An Ethernet interface connected to an ENode must be configured to operate in ENode mode. An Ethernet interface connected to an FCF switch must be configured to operate in FCF mode.

To control packet exchange between ENodes and FCF switches, perform the following tasks:

· Enable FIP snooping.

· Configure the Ethernet interfaces to operate in a correct mode on the Transit switch.

How FIP snooping works

After FIP snooping is enabled for a VLAN, Ethernet interfaces on the Transit switch establish FIP snooping rules according to FIP frames (with EtherType as 0x8914). Then, the Ethernet interfaces control the forwarding of FCoE frames (with EtherType as 0x8906) based on the FIP snooping rules.

To facilitate description, the following definitions are specified:

· FIP snooping rules generated on an Ethernet interface operating in FCF mode are called FCF FIP snooping rules.

· FIP snooping rules generated on an Ethernet interface operating in ENode mode are called ENode FIP snooping rules.

Establishing FIP snooping rules

FIP snooping rules are established when a virtual link is established between an ENode and an FCF switch. The following workflow is used to establish FIP snooping rules:

1. After receiving an unsolicited Discovery Advertisement from an FCF switch, the Ethernet interface in FCF mode on the Transit switch performs the following operations:

a. Generates an FCF FIP snooping rule based on the unsolicited Discovery Advertisement.

b. Forwards the unsolicited Discovery Advertisement to the ENode.

The FCF FIP snooping rule allows FCoE frames meeting the following requirements:

? The source MAC address is the MAC address in the unsolicited Discovery Advertisement (FCoE MAC address of the FCF switch).

? The 24 most significant bits of the destination MAC address is the FC-MAP value configured for the VLAN.

2. The Transit switch receives a Discovery Solicitation from the ENode on the Ethernet interface in ENode mode.

3. The Transit switch forwards the Discovery Solicitation to the FCF switch through the Ethernet interface in FCF mode.

4. The Transit switch receives a FIP FLOGI request from the ENode on the Ethernet interface in ENode mode.

5. The Transit switch forwards the FIP FLOGI request to the FCF switch through the Ethernet interface in FCF mode.

6. When forwarding the FLOGI LS_ACC packet from the FCF switch to the ENode, the Ethernet interface in ENode mode performs the following operations:

a. Obtains the FC address assigned by the FCF switch to the ENode and the FCoE MAC address of the FCF switch.

b. Generates an ENode FIP snooping rule.

The ENode FIP snooping rule allows FCoE frames meeting the following requirements to pass through:

? The source MAC address is the FPMA (composed of FC-MAP as the 24 most significant bits and FC address as the 24 least significant bits).

? The destination MAC address is the FCoE MAC address of the FCF switch.

FIP snooping rules exist as long as the virtual link is present, and they are deleted when you delete the virtual link.

Controlling forwarding of FCoE frames

After establishing FIP snooping rules, a Transit switch forwards FCoE frames that match FIP snooping rules and drops those that do not match FIP snooping rules. As a result, only successfully registered ENodes can communicate with FCF switches.

FIP snooping configuration task list

Tasks at a glance	Remarks
(Required.) Configuring the FCoE mode	Configure the switch to operate in Transit mode.
(Required.) Enabling FIP snooping	Only Transit switches support FIP snooping.
(Required.) Configuring the operating mode of an Ethernet interface	N/A
(Optional.) Setting the FC-MAP value	N/A

Enabling FIP snooping

FIP snooping is enabled on a per-VLAN basis.

To enable FIP snooping for a VLAN:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VLAN view.	vlan vlan-id	N/A
3. Enable FIP snooping for the VLAN.	fip-snooping enable	By default, FIP snooping is disabled for each VLAN.

Configuring the operating mode of an Ethernet interface

Ethernet interfaces on a Transit switch can operate in ENode mode or FCF mode. An Ethernet interface connected to an ENode must be configured to operate in ENode mode. An Ethernet interface connected to an FCF switch must be configured to operate in FCF mode.

To configure the operating mode of an Ethernet interface:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter Layer 2 Ethernet interface view or Layer 2 aggregate interface view.	interface interface-type interface-number	N/A
3. Configure the operating mode of the interface.	fip-snooping port-mode { enode \| fcf }	The default setting is ENode mode.

Setting the FC-MAP value

The FC-MAP value identifies an FCoE network. Switches (including FCF switches and Transit switches) in the same FCoE network must have the same FC-MAP value.

You can use the fcoe fcmap command to set the FC-MAP value in frames sent out of an FCF switch. You can use the fip-snooping fc-map command to set an FC-MAP value for a VLAN on a Transit switch.

When an Ethernet interface in the FIP snooping VLAN receives a frame from the FCF switch, the following rules apply:

· If the FC-MAP value in the incoming frame is the same as that configured for the FIP snooping VLAN, the Ethernet interface forwards the frames.

· If the FC-MAP value in the incoming frame is different from that configured for the FIP snooping VLAN, the Ethernet interface drops the frames.

To set an FC-MAP value:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Enter VLAN view.	vlan vlan-id	N/A
3. Set an FC-MAP value.	fip-snooping fc-map fc-map	The default setting is 0x0efc00.

Displaying and maintaining FIP snooping

Execute display commands in any view.

Task	Command
Display ENode information obtained by a Transit switch.	display fip-snooping enode [ vlan vlan-id ]
Display FCF switch information obtained by a Transit switch.	display fip-snooping fcf [ vlan vlan-id ]
Display the FIP snooping rules that have been flushed (in standalone mode).	display fip-snooping rules [ enode \| fcf ] [ vlan vlan-id ] [ slot slot-number ]
Display the FIP snooping rules that have been flushed (in IRF mode).	display fip-snooping rules [ enode \| fcf ] [ vlan vlan-id ] [ chassis chassis-number slot slot-number ]
Display the FIP snooping rules that are being flushed.	display fip-snooping flushing-rules [ enode \| fcf ] [ vlan vlan-id ]
Display information about FIP snooping sessions (connections between ENodes and FCF switches).	display fip-snooping sessions [ vlan vlan-id ]

FIP snooping configuration example

Network requirements

As shown in Figure 31, enable FIP snooping on the Transit switch to achieve reliable communication between the ENode and FCF switch.

Figure 31 Network diagram

Configuration procedure

1. Configure the Transit switch:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<Transit> system-view

[Transit] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[Transit] save

[Transit] quit

<Transit> reboot

# Configure the switch to operate in Transit mode.

<Transit> system-view

[Transit] fcoe-mode transit

# Enable FIP snooping for VLAN 10.

[Transit] vlan 10

[Transit-vlan10] fip-snooping enable

# Set the FC-MAP value to 0x0EFC01 for VLAN 10.

[Transit-vlan10] fip-snooping fc-map 0efc01

Changing the FC-MAP will flap all interfaces. Continue? [Y/N]:y

[Transit-vlan10] quit

# Configure interface Ten-GigabitEthernet 1/0/1 to allow VLAN 10.

[Transit] interface ten-gigabitethernet 1/0/1

[Transit-Ten-GigabitEthernet1/0/1] port link-type trunk

[Transit-Ten-GigabitEthernet1/0/1] port trunk permit vlan 10

# Configure interface Ten-GigabitEthernet 1/0/1 to operate in ENode mode.

[Transit-Ten-GigabitEthernet1/0/1] fip-snooping port-mode enode

[Transit-Ten-GigabitEthernet1/0/1] quit

# Configure interface Ten-GigabitEthernet 1/0/2 to allow VLAN 10.

[Transit] interface ten-gigabitethernet 1/0/2

[Transit-Ten-GigabitEthernet1/0/2] port link-type trunk

[Transit-Ten-GigabitEthernet1/0/2] port trunk permit vlan 10

# Configure interface Ten-GigabitEthernet 1/0/2 to operate in FCF mode.

[Transit-Ten-GigabitEthernet1/0/2] fip-snooping port-mode fcf

[Transit-Ten-GigabitEthernet1/0/2] quit

2. Configure the FCF switch:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<FCF> system-view

[FCF] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[FCF] save

[FCF] quit

<FCF> reboot

# Configure the switch to operate in FCF mode.

<FCF> system-view

[FCF] fcoe-mode fcf

# Set the FC-MAP value to 0x0EFC01.

[FCF] fcoe fcmap 0efc01

Changing the FC-MAP will flap all VFC interfaces. Continue? [Y/N]:y

# Create VSAN 10.

[FCF] vsan 10

[FCF-vsan10] quit

# Create interface VFC 2.

[FCF] interface vfc 2

# Configure the mode of VFC 2 as F.

[FCF-vfc2] fc mode f

# Assign VFC 2 to VSAN 10.

[FCF-vfc2] port trunk vsan 10

# Bind VFC 2 to interface Ten-GigabitEthernet 1/0/2.

[FCF-vfc2] bind interface ten-gigabitethernet 1/0/2

[FCF-Vfc2] quit

# Configure Ten-GigabitEthernet 1/0/2 as a trunk port, and assign the port to VLAN 10.

[FCF] interface ten-gigabitethernet 1/0/2

[FCF-Ten-GigabitEthernet1/0/2] port link-type trunk

[FCF-Ten-GigabitEthernet1/0/2] port trunk permit vlan 10

[FCF-Ten-GigabitEthernet1/0/2] quit

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 10.

[FCF] vlan 10

[FCF-vlan10] fcoe enable vsan 10

Verifying the configuration

# Display ENode information obtained by the Transit switch.

[Transit] display fip-snooping enode

VLAN 10:

Interface ENode WWN ENode MAC

XGE1/0/1 10:00:00:11:22:00:0d:01 0000-1234-0d01

# Display FCF switch information obtained by the Transit switch.

[Transit] display fip-snooping fcf

VLAN 10:

Interface FCF MAC FCF WWN Fabric Name ENode

XGE1/0/2 0000-1234-0e01 10:00:00:11:22:00:0e:01 10:00:00:11:22:00:0e:01 1

# Display information about FIP snooping sessions.

[Transit] display fip-snooping sessions

VLAN 10:

FCF MAC ENode MAC VN_Port MAC VN_Port WWN

0000-1234-0e01 0000-1234-0d01 0efc-0001-0000 af:10:01:11:22:00:0d:01

# Display the FIP snooping rules that have been flushed.

Slot 1:

VLAN 10:

FCF rules information:

Interface Source MAC/Mask Destination MAC/Mask Context

XGE1/0/2 0000-1234-0e01/48 0efc-0000-0000/24 ffffffff

ENode rules information:

Interface Source MAC/Mask Destination MAC/Mask Context

XGE1/0/1 0efc-0001-0000/48 0000-1234-0e01/48 ffffffff

Configuring FCS

Only FCF switches support FCS. Switches described in this chapter refer to FCF switches.

Overview

The Fabric Configuration Server (FCS) feature provides discovery of topology information of a fabric, including switches in the fabric and ports on each switch. A management application (for example, SNMP NMS software) determines the physical and logical topologies of the fabric based on the FCS topology information. It also manages the switches in the fabric.

The FCS describes the topology of a fabric by using the following objects:

· Interconnect element (IE) object—Each switch in a fabric corresponds to an IE object. One or more IE objects are interconnected to form a fabric. An IE object has a set of attributes, as shown in Table 6.

· Port object—Each VFC interface on an IE object corresponds to a port object. An IE object has one or more port objects. A port object has a set of attributes, as shown in Table 7.

Table 6 IE object attributes

Attribute	Description
IE WWN	WWN of the IE.
IE type	The IE type can only be Switch.
Domain ID	Domain ID of the IE.
Fabric name	Name of the fabric where the IE resides.
Logical name	Device name of the IE, which can be configured by using the sysname command.
Management address list	Management protocol supported by the IE and management IP address. Only SNMP is supported. The management IP address is in the form of a URL. For example, snmp://192.168.6.100 indicates that the management protocol is SNMP and the management IP address is 192.168.6.100. An IE can have one or more management addresses.
Information list	Includes vendor name, product name/number, release code, and other vendor-specific information.

Table 7 Port object attributes

Attribute	Description
Port WWN	WWN of the port.
Port type	Port mode: E_Port or F_Port.
Tx type	Transmitter type of the port: · 10GBASE-CX4. · 10GBASE-ER 1550nm laser. · 10GBASE-EW 1550nm laser. · 10GBASE-LR 1310nm laser. · 10GBASE-LW 1310nm laser. · 10GBASE-LX4 WWDM 1300nm laser. · 10GBASE-SR 850nm laser. · 10GBASE-SW 850nm laser. · Electrical-EL. · Long wave laser cost reduced-LC(1310nm). · Long wave laser-LL(1550nm). · Short wave laser-SN(850nm).
Module type	Transceiver module type of the port: · GBIC with serial ID. · GBIC without serial ID. · GLM. · QSFP. · SFP-DWDM. · SFP with serial ID. · SFP without serial ID. · X2-DWDM. · X2 Medium. · X2 short. · X2 Tall. · XENPAK. · XFP. · XPAX Medium. · XPAX short. · XPAX Tall.
Port number	Port index.
Attached port WWNs	WWNs of connected ports. If the nodes are registered through an NPV switch, there might be multiple connected ports.
Port state	Current port status: · Online—The port link is connected. · Offline—The port link is not connected.
Port speed capability	The supported speed can be one or any combination of the following options: · 1 Gbps. · 2 Gbps. · 4 Gbps. · 8 Gbps. · 10 Gbps. · 16 Gbps. · 20 Gbps.
Port speed operation	The current speed can only be one of the following options: · 1 Gbps. · 2 Gbps. · 4 Gbps. · 8 Gbps. · 10 Gbps. · 16 Gbps. · 20 Gbps.
Port zoning enforcement status	Zoning type supported by the port: soft zoning or hard zoning.

Starting a topology discovery

You can start a topology discovery on any switch in a fabric. The process of topology discovery is as follows:

1. Each switch in a fabric maintains a list all IE objects in the fabric. When no topology discovery is started, the switch displays the topology discovery status as localOnly in the relevant VSAN. The switch stores all attributes of its own IE object and port information. The switch stores only attributes of IE WWN, type, and domain ID for the other IE objects.

2. When a topology discovery is started, the switch changes the topology discovery status in the relevant VSAN to inProgress. The switch obtains the latest IE attributes and port attributes of all other switches in the fabric. Then, the switch updates the IE and port information in the local FCS database.

3. When topology discovery is complete, the switch changes the topology discovery status in the relevant VSAN to completed. The switch starts an aging timer to specify the amount of time for the topology discovery information to stay effective before it is deleted.

4. When the aging timer expires, the switch performs the following operations:

? Deletes all topology discovery information except its own information.

? Changes the topology discovery status in the relevant VSAN to localOnly.

The fabric topology might change. During a topology discovery, the switch will not obtain IE attributes and port information of an IE in any of the following situations:

· A new IE joins the fabric when the switch has started obtaining the IE attributes and port attributes of other switches.

· The attributes of an IE changes after the switch finishes obtaining the attributes and port information of that IE. In this case, the switch will not obtain the changed attributes of the IE.

The switch processes local topology changes in real time, regardless of topology discovery.

To start a topology discovery:

Step	Command	Remarks
1. Enter system view.	system-view	N/A
2. Start a topology discovery in specified VSANs.	fcs discovery start [ age interval ] vsan vsan-list	You can start a second topology discovery for the same VSAN only after the first topology discovery is complete. Otherwise, the system displays the message "FCS discovery is being performed".

Stopping a topology discovery

Step

Command

Remarks

1. Enter system view.

system-view

N/A

2. Stop a topology discovery in specified VSANs.

fcs discovery stop vsan vsan-list

After you execute this command, the system performs the following operations:

· Stops the topology discovery in progress.

· Deletes the topology information obtained from non-local switches.

· Changes the topology discovery status back to localOnly.

Displaying and maintaining FCS

Execute display commands in any view.

Task	Command
Display the topology discovery status.	display fcs discovery status [ vsan vsan-id ]
Display the FCS database information.	display fcs database [ vsan vsan-id ]
Display IE information.	display fcs ie [ vsan vsan-id ] [ nwwn wwn ] [ verbose ]
Display port information.	display fcs port [ vsan vsan-id ] [ pwwn wwn ] [ verbose ]

FCS configuration example

Network requirements

As shown in Figure 32, start a topology discovery to obtain topology information in the fabric for the management application.

Figure 32 Network diagram

Configuration procedure

This section describes only FCS configurations.

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchA> system-view

[SwitchA] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchA] save

[SwitchA] quit

<SwitchA> reboot

# Configure the switch to operate in FCF mode.

<SwitchA> system-view

[SwitchA] fcoe-mode fcf

# Start a topology discovery in VSAN 1 on Switch A.

[SwitchA] fcs discovery start vsan 1

Verifying the configuration

# Display the FCS database information in VSAN 1 on Switch A.

[SwitchA] display fcs database vsan 1

FCS Local Database in VSAN 1:

IE WWN : 10:00:00:11:22:00:01:01

Domain ID : 0x01

Management address list : snmp://192.168.0.1

Fabric name : 10:00:00:11:22:00:01:01

Logical name : SwitchA

Information list : H3C#H3C S10508X-V#Version 7.1.045, Beta 7143

IE_Ports:

Interface Port WWN Port type Attached port WWNs

Vfc1 e1:01:00:11:22:00:01:01 E_Port e2:01:00:11:22:00:01:01

Vfc2 e1:01:00:11:22:00:01:02 E_Port e3:01:00:11:22:00:01:01

IE WWN : 10:00:00:11:22:00:01:02

Domain ID : 0x02

Management address list : snmp://192.168.0.2

Fabric name : 10:00:00:11:22:00:01:01

Logical name : SwitchB

Information list : H3C#H3C S10508X-V#Version 7.1.045, Beta 7143

IE_Ports:

Interface Port WWN Port type Attached port WWNs

- e2:01:00:11:22:00:01:01 E_Port e1:01:00:11:22:00:01:01

- e2:01:00:11:22:00:01:02 E_Port e3:01:00:11:22:00:01:02

- e2:01:00:11:22:00:01:03 E_Port e4:01:00:11:22:00:01:01

IE WWN : 10:00:00:11:22:00:01:03

Domain ID : 0x03

Management address list : snmp://192.168.0.3

Fabric name : 10:00:00:11:22:00:01:01

Logical name : SwitchC

Information list : H3C#H3C S10508X-V#Version 7.1.045, Beta 7143

IE_Ports:

Interface Port WWN Port type Attached port WWNs

- e3:01:00:11:22:00:01:01 E_Port e1:01:00:11:22:00:01:02

- e3:01:00:11:22:00:01:02 E_Port e2:01:00:11:22:00:01:02

- e3:01:00:11:22:00:01:03 F_Port 48:33:43:2d:46:43:1A:1A

IE WWN : 10:00:00:11:22:00:01:04

Domain ID : 0x04

Management address list : snmp://192.168.0.4

Fabric name : 10:00:00:11:22:00:01:01

Logical name : SwitchD

Information list : H3C#H3C S10508X-V#Version 7.1.045, Beta 7143

IE_Ports:

Interface Port WWN Port type Attached port WWNs

- e4:01:00:11:22:00:01:01 E_Port e2:01:00:11:22:00:01:03

- e4:01:00:11:22:00:01:02 F_Port 48:33:43:2d:46:43:1B:1B

# Display brief information about IEs in VSAN 1 on Switch A.

[SwitchA] display fcs ie vsan 1

IE List for VSAN 1:

IE WWN Domain ID Mgmt addr list Logical name

10:00:00:11:22:00:01:01 0x01 snmp://192.168.0.1 SwitchA

10:00:00:11:22:00:01:02 0x02 snmp://192.168.0.2 SwitchB

10:00:00:11:22:00:01:03 0x03 snmp://192.168.0.3 SwitchC

10:00:00:11:22:00:01:04 0x04 snmp://192.168.0.4 SwitchD

Total 4 IEs in Fabric.

# Display brief information about ports in VSAN 1 on Switch A.

[SwitchA] display fcs port vsan 1

Port List for VSAN 1:

IE WWN: 10:00:00:11:22:00:01:01

Port WWN Port type Tx type Module type

e1:01:00:11:22:00:01:01 E_Port 10GBASE-CX4 SFP with serial ID

e1:01:00:11:22:00:01:02 E_Port 10GBASE-CX4 SFP with serial ID

Total 2 switch-ports in IE.

IE WWN: 10:00:00:11:22:00:01:02

Port WWN Port type Tx type Module type

e2:01:00:11:22:00:01:01 E_Port 10GBASE-CX4 SFP with serial ID

e2:01:00:11:22:00:01:02 E_Port 10GBASE-CX4 SFP with serial ID

e2:01:00:11:22:00:01:03 E_Port 10GBASE-CX4 SFP with serial ID

Total 3 switch-ports in IE.

IE WWN: 10:00:00:11:22:00:01:03

Port WWN Port type Tx type Module type

e3:01:00:11:22:00:01:01 E_Port 10GBASE-CX4 SFP with serial ID

e3:01:00:11:22:00:01:02 E_Port 10GBASE-CX4 SFP with serial ID

e3:01:00:11:22:00:01:03 F_Port 10GBASE-CX4 SFP with serial ID

Total 3 switch-ports in IE.

IE WWN: 10:00:00:11:22:00:01:04

Port WWN Port type Tx type Module type

e4:01:00:11:22:00:01:01 E_Port 10GBASE-CX4 SFP with serial ID

e4:01:00:11:22:00:01:02 F_Port 10GBASE-CX4 SFP with serial ID

Total 2 switch-ports in IE.

Configuring FDMI

Only FCF switches support FCS. Switches described in this chapter refer to FCF switches.

Overview

The Fabric Device Management Interface (FDMI) feature allows you to view information about host bus adapters (HBAs) on all registered nodes in a fabric. The HBA information includes HBAs and ports on each HBA.

Each switch obtains the HBA information of its directly connected and registered nodes and sends the information to other switches in the fabric. As a result, each switch has HBA information for all the nodes registered with the fabric.

An HBA is an FC storage network card. Each HBA appears as an object to the switch. An HBA object has a set of attributes, as shown in Table 8.

Each physical port on an HBA object corresponds to a port object. An HBA object can have a maximum of 256 port objects. A port object has a set of attributes, as shown in Table 9.

When RPRT or RPA packets from a port object include Smart SAN attributes, the following rules apply to displaying FDMI database information:

· If the switch is enabled with Smart SAN, Smart SAN attributes are displayed for the port object.

· If the switch is not enabled with Smart SAN, no information is displayed.

When RPRT or RPA packets from a port object do not include Smart SAN attributes, Smart SAN attributes are not displayed, regardless of whether the switch is enabled with Smart SAN.

The following are Smart SAN attributes:

· Smart SAN Service Category.

· Smart SAN globally unique identifier (GUID).

· Smart SAN Version.

· Smart SAN Product Name (Model).

· Smart SAN Port Info.

· Smart SAN QoS Support.

· Smart SAN Security Support.

· Smart SAN Connected Ports.

Table 8 HBA object attributes

Attribute	Description
HBA ID	An HBA ID identifies an HBA. If an HBA has only one physical interface, the WWN of the physical interface is used as the HBA ID. If the HBA has more than one physical interface, the WWN of one of the physical interfaces is selected as the HBA ID.
Manufacturer	Manufacturer of the HBA.
Serial Number	Serial number of the HBA.
Model	Model of the HBA.
Model Description	Model description for the HBA.
Node Name	WWN of the node where the HBA resides.
Node Symbolic Name	Symbolic name of the node where the HBA resides.
Hardware Version	Hardware version of the HBA.
Driver Version	Driver version of the HBA.
Option ROM Version	ROM version of the HBA.
Firmware Version	Firmware version of the HBA.
OS Name and Version	Operating system name and version number of the HBA.
Maximum CT Payload	Maximum length of CT payload allowed by the HBA. The CT payload includes the basic header and extended header of CT packets, but not the FC header.
Vendor Identifier	T10 code of the manufacturer or OEM for the HBA.
Vendor Specific Information	Vendor-defined information, which is hexadecimal.
Number of Ports	Number of ports on the HBA.
Fabric Name	Name of the fabric where the HBA resides.
Boot BIOS Version	Boot BIOS version of the HBA.
Boot BIOS State	Boot BIOS state for the HBA: Enabled or Disabled.

Table 9 Port object attributes

Field	Description
Port Name	WWN of the port.
Port Symbolic Name	Symbolic name of the port.
Port Identifier	FC address of the port.
Port Type	Port type.
Supported Class of Service	Class of service supported by the port: Class 2 or Class 3.
Supported FC-4 Types	FC-4 types supported by the port: · FCP. · GS3. · IP. · LLC/SNAP. · NPV. · SNMP. · SW-ILS. · VI. · NVMeoFC.
Port Active FC-4 Types	FC-4 types active on the port, which can be one or more of the following options: · FCP. · GS3. · IP. · LLC/SNAP. · NPV. · SNMP. · SW-ILS. · VI. · NVMeoFC.
Supported Speed	Speeds supported by the port: · 1 Gbps. · 2 Gbps. · 4 Gbps. · 8 Gbps. · 10 Gbps. · 16 Gbps. · 20 Gbps. · 32 Gbps. · 40 Gbps. This field displays Unknown for speeds other than the preceding ones. This field displays Speed not obtained when the supported speeds cannot be determined.
Current Speed	The current speed can only be one of the following options: · 1 Gbps. · 2 Gbps. · 4 Gbps. · 8 Gbps. · 10 Gbps. · 16 Gbps. · 20 Gbps. · 32 Gbps. · 40 Gbps. This field displays Unknown for speeds other than the preceding ones. This field displays Speed not obtained when the current speed cannot be determined.
OS Device Name	Operating system name for the port.
Maximum Frame Size	Maximum frame size supported by the port.
Host Name	Name of the node where the port resides.
Node Name	WWN of the node where the port resides.
Port Fabric Name	Name of the fabric where the port resides.
Port State	Current state of the port.
Number of Discovered Ports	Number of ports discovered by the port.
Smart SAN Service Category	Smart SAN service category: Smart SAN Initiator or Smart SAN Target.
Smart SAN GUID	Smart SAN GUID.
Smart SAN Version	Smart SAN version.
Smart SAN Product Name (Model)	Smart SAN product name (model).
Smart SAN Port Info	Port information: · 0x01 (Physical)—The port is a physical port. · 0x02 (NPIV)—The port supports NPIV. · 0x03 (SRIOV)—The port supports SRIOV.
Smart SAN QoS Support	QoS support of the port: 0x00 (Not supported) and 0x01 (Supported).
Smart SAN Security Support	Security types supported by the port: · 0x00 (Not Supported). · 0x01 (Tier-1). · 0x02 (Tier-2). · 0x03 (Tier-3).
Smart SAN Connected Ports	This field displays ports on remote nodes discovered by the port.

Displaying and maintaining FDMI

Execute display commands in any view.

Task	Command
Display the FDMI database information.	display fdmi database [ vsan vsan-id ] [ hba-id hba-id ] [ verbose ]

Configuring FC ping

Overview

In an FC SAN, use the fcping command to identify whether a destination address is reachable and to test network connectivity.

In an FC ping operation, the source device sends echo requests to the destination device. It determines whether the destination is reachable based on whether it receives echo replies. If the destination is reachable, the source device can perform the following operations:

· Determine the link quality based on the number of echo requests sent and the number of replies received.

· Determine the distance between the source and destination based on the round-trip time of FC ping packets.

A switch supports the following FC ping operations:

· FC ping an N_Port from the switch—Use the fcping command on the switch to ping an N_Port at the remote end. The destination address of the FC ping operation is the FC address of the N_Port.

· FC ping a switch from the current switch—The destination address is the destination switch's domain controller address FFFCxx (xx is the domain ID of the destination switch).

Configuration procedure

Task

Command

Remarks

Identify whether a destination address is reachable.

fcping [ -c count | -t timeout ] * fcid fcid vsan vsan-id

Available in any view.

To abort the FC ping operation during the execution of this command, press Ctrl+C.

FC ping configuration example

Network requirements

Identify whether Switch A and Switch B can reach each other.

Figure 33 Network diagram

Configuration procedure

1. Configure Switch A:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchA> system-view

[SwitchA] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchA] save

[SwitchA] quit

<SwitchA> reboot

# Configure the switch to operate in FCF mode.

<SwitchA> system-view

[SwitchA] fcoe-mode fcf

# Enable the fabric configuration feature for VSAN 1.

[SwitchA] vsan 1

[SwitchA-vsan1] domain configure enable

# Set the domain ID to 1.

[SwitchA-vsan1] domain-id 1 static

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

[SwitchA-vsan1] quit

# Create interface VFC 1.

[SwitchA] interface vfc 1

# Configure the mode of VFC 1 as E.

[SwitchA-Vfc1] fc mode e

# Bind VFC 1 to interface Ten-GigabitEthernet 1/0/1.

[SwitchA-Vfc1] bind interface ten-gigabitethernet 1/0/1

# Assign VFC 1 to VSAN 1 as a trunk port.

[SwitchA-Vfc1] port trunk vsan 1

[SwitchA-Vfc1] quit

# Configure Ten-GigabitEthernet 1/0/1 as a trunk port, and assign the port to VLAN 10.

[SwitchA] interface ten-gigabitethernet 1/0/1

[SwitchA-Ten-GigabitEthernet1/0/1] port link-type trunk

[SwitchA-Ten-GigabitEthernet1/0/1] port trunk permit vlan 10

[SwitchA-Ten-GigabitEthernet1/0/1] quit

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 1.

[SwitchA] vlan 10

[SwitchA-vlan10] fcoe enable vsan 1

[SwitchA-vlan10] quit

# Configure a static route.

[SwitchA] vsan 1

[SwitchA-vsan1] fc route-static 020000 8 vfc 1

[SwitchA-vsan1] quit

2. Configure Switch B:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchB> system-view

[SwitchB] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchB] save

[SwitchB] quit

<SwitchB> reboot

# Configure the switch to operate in FCF mode.

<SwitchB> system-view

[SwitchB] fcoe-mode fcf

# Enable the fabric configuration feature for VSAN 1.

[SwitchB] vsan 1

[SwitchB-vsan1] domain configure enable

# Set the domain ID to 2.

[SwitchB-vsan1] domain-id 2 static

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

[SwitchB-vsan1] quit

# Create interface VFC 1.

[SwitchB] interface vfc 1

# Configure the mode of VFC 1 as E.

[SwitchB-Vfc1] fc mode e

# Bind VFC 1 to interface Ten-GigabitEthernet 1/0/1.

[SwitchB-Vfc1] bind interface ten-gigabitethernet 1/0/1

# Assign VFC 1 to VSAN 1.

[SwitchB-Vfc1] port trunk vsan 1

[SwitchB-Vfc1] quit

# Configure Ten-GigabitEthernet 1/0/1 as a trunk port, and assign the port to VLAN 10.

[SwitchB] interface ten-gigabitethernet 1/0/1

[SwitchB-Ten-GigabitEthernet1/0/1] port link-type trunk

[SwitchB-Ten-GigabitEthernet1/0/1] port trunk permit vlan 10

[SwitchB-Ten-GigabitEthernet1/0/1] quit

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 1.

[SwitchB] vlan 10

[SwitchB-vlan10] fcoe enable vsan 1

[SwitchB-vlan10] quit

# Configure a static route.

[SwitchB] vsan 1

[SwitchB-vsan1] fc route-static 010000 8 vfc 1

[SwitchB-vsan1] quit

Verifying the configuration

# FCping a switch from another switch, for example, FCping Switch B from Switch A.

[SwitchA] fcping fcid fffc02 vsan 1

FCPING fcid 0xfffc02: 128 data bytes, press CTRL_C to break.

Reply from 0xfffc02: bytes = 128 time = 23 ms

Reply from 0xfffc02: bytes = 128 time = 9 ms

Reply from 0xfffc02: bytes = 128 time = 19 ms

Reply from 0xfffc02: bytes = 128 time = 14 ms

Reply from 0xfffc02: bytes = 128 time = 25 ms

--- 0xfffc02 fcping statistics ---

5 packet(s) transmitted

5 packet(s) received

0.00% packet loss

round-trip min/avg/max = 9/18/25 ms

Configuring FC tracert

Overview

In an FC SAN, use the fctracert command to obtain bidirectional routing information between source and destination, and check the network connectivity.

You can use this feature to identify failed nodes and test network connectivity.

FC tracert includes the following processes:

· Uplink process—Beginning from the source, each switch along the path sends the Switch Trace Route (STR) packet to its next hop until the STR packet reaches the destination switch. (If the destination of FC tracert is a node, the destination switch refers to the FCF switch directly connected to the node.) Each switch adds its uplink path information (including its WWN and domain ID) to the STR packet. After the STR packet reaches the destination switch, the downlink process starts.

· Downlink process—Beginning from the destination switch, each switch along the path sends the STR packet to its next hop until the STR packet reaches the source switch. Each switch adds its downlink path information (with the same content as the uplink path information) to the STR packet. When the source switch receives the STR packet, the FC tracert process ends. The source outputs information (in the STR packet) about all uplink and downlink switches along the path.

If an FCF switch fails to forward the STR packet, the switch performs the following operations:

· Sets an error reason in the packet.

· Sends the packet (containing information about switches the packet has passed through) directly to the source switch.

Figure 34 shows the FC tracert process.

Figure 34 FC tracert flowchart

The following describes the process of an FC tracert operation from Switch A to Switch C.

1. Uplink process

a. Switch A adds its uplink path information (including its WWN and domain ID) to the STR request packet and sends the packet to the next hop Switch B.

b. After receiving the packet, Switch B replies with an STR ACC packet to Switch A.

c. Switch B adds its uplink path information to the received STR packet and sends it to the destination switch, Switch C.

d. After receiving the packet, Switch C replies with an STR ACC packet to Switch B.

e. Switch C adds its uplink path information to the received packet. The collection of uplink path information is complete.

2. Downlink process

a. Switch C sends the STR request packet to Switch A hop by hop in the same way as in the uplink process.

b. After receiving the STR request packet with a downlink flag, Switch A outputs information about all uplink and downlink switches.

Configuration procedure

Task

Command

Remarks

Detect bidirectional routing information between source and destination.

fctracert [ -t timeout ] fcid fcid vsan vsan-id

Available in any view.

To abort the FC tracert operation during the execution of this command, press Ctrl+C.

FC tracert configuration example

Network requirements

As shown in Figure 35, detect bidirectional routing information between Switch A and Switch C, and identify the faulty node (if any).

Figure 35 Network diagram

Configuration procedure

1. Configure Switch A:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchA> system-view

[SwitchA] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchA] save

[SwitchA] quit

<SwitchA> reboot

# Configure the switch to operate in FCF mode.

<SwitchA> system-view

[SwitchA] fcoe-mode fcf

# Enable the fabric configuration feature for VSAN 1.

[SwitchA] vsan 1

[SwitchA-vsan1] domain configure enable

# Set the domain ID to 1.

[SwitchA-vsan1] domain-id 1 static

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

# Disable FSPF for VSAN 1.

[SwitchA-vsan1] undo fspf enable

# Configure static routes.

[SwitchA-vsan1] fc route-static 020000 8 vfc 1

[SwitchA-vsan1] fc route-static 030000 8 vfc 1

[SwitchA-vsan1] quit

# Create interface VFC 1.

[SwitchA] interface vfc 1

# Configure the mode of VFC 1 as E.

[SwitchA-Vfc1] fc mode e

# Bind VFC 1 to interface Ten-GigabitEthernet 1/0/1.

[SwitchA-Vfc1] bind interface ten-gigabitethernet 1/0/1

# Assign VFC 1 to VSAN 1 as a trunk port.

[SwitchA-Vfc1] port trunk vsan 1

[SwitchA-Vfc1] quit

# Configure Ten-GigabitEthernet 1/0/1 as a trunk port, and assign the port to VLAN 10.

[SwitchA] interface ten-gigabitethernet 1/0/1

[SwitchA-Ten-GigabitEthernet1/0/1] port link-type trunk

[SwitchA-Ten-GigabitEthernet1/0/1] port trunk permit vlan 10

[SwitchA-Ten-GigabitEthernet1/0/1] quit

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 1.

[SwitchA] vlan 10

[SwitchA-vlan10] fcoe enable vsan 1

[SwitchA-vlan10] quit

2. Configure Switch B:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchB> system-view

[SwitchB] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchB] save

[SwitchB] quit

<SwitchB> reboot

# Configure the switch to operate in FCF mode.

<SwitchB> system-view

[SwitchB] fcoe-mode fcf

# Enable the fabric configuration feature for VSAN 1.

[SwitchB] vsan 1

[SwitchB-vsan1] domain configure enable

# Set the domain ID to 2.

[SwitchB-vsan1] domain-id 2 static

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

# Disable FSPF for VSAN 1.

[SwitchB-vsan1] undo fspf enable

# Configure a static route.

[SwitchB-vsan1] fc route-static 010000 8 vfc 1

[SwitchB-vsan1] quit

# Create interface VFC 1.

[SwitchB] interface vfc 1

# Configure the mode of VFC 1 as E.

[SwitchB-Vfc1] fc mode e

# Bind VFC 1 to interface Ten-GigabitEthernet 1/0/1.

[SwitchB-Vfc1] bind interface ten-gigabitethernet 1/0/1

# Assign VFC 1 to VSAN 1 as a trunk port.

[SwitchB-Vfc1] port trunk vsan 1

[SwitchB-Vfc1] quit

# Configure Ten-GigabitEthernet 1/0/1 as a trunk port, and assign the port to VLAN 10.

[SwitchB] interface ten-gigabitethernet 1/0/1

[SwitchB-Ten-GigabitEthernet1/0/1] port link-type trunk

[SwitchB-Ten-GigabitEthernet1/0/1] port trunk permit vlan 10

[SwitchB-Ten-GigabitEthernet1/0/1] quit

# Create interface VFC 2.

[SwitchB] interface vfc 2

# Configure the mode of VFC 2 as E.

[SwitchB-Vfc2] fc mode e

# Bind VFC 2 to interface Ten-GigabitEthernet 1/0/2.

[SwitchB-Vfc2] bind interface ten-gigabitethernet 1/0/2

# Assign VFC 2 to VSAN 1 as a trunk port.

[SwitchB-Vfc2] port trunk vsan 1

[SwitchB-Vfc2] quit

# Configure Ten-GigabitEthernet 1/0/2 as a trunk port, and assign the port to VLAN 10.

[SwitchB] interface ten-gigabitethernet 1/0/2

[SwitchB-Ten-GigabitEthernet1/0/2] port link-type trunk

[SwitchB-Ten-GigabitEthernet1/0/2] port trunk permit vlan 10

[SwitchB-Ten-GigabitEthernet1/0/2] quit

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 1.

[SwitchB] vlan 10

[SwitchB-vlan10] fcoe enable vsan 1

[SwitchB-vlan10] quit

3. Configure Switch C:

# Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchC> system-view

[SwitchC] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the

system to make it effective.

[SwitchC] save

[SwitchC] quit

<SwitchC> reboot

# Configure the switch to operate in FCF mode.

<SwitchC> system-view

[SwitchC] fcoe-mode fcf

# Enable the fabric configuration feature for VSAN 1.

[SwitchC] vsan 1

[SwitchC-vsan1] domain configure enable

# Set the domain ID to 3.

[SwitchC-vsan1] domain-id 3 static

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

# Disable FSPF for VSAN 1.

[SwitchC-vsan1] undo fspf enable

[SwitchC-vsan1] quit

# Create interface VFC 2.

[SwitchC] interface vfc 2

# Configure the mode of VFC 2 as E.

[SwitchC-Vfc2] fc mode e

# Bind VFC 2 to interface Ten-GigabitEthernet 1/0/2.

[SwitchC-Vfc2] bind interface ten-gigabitethernet 1/0/2

# Assign VFC 2 to VSAN 1 as a trunk port.

[SwitchC-Vfc2] port trunk vsan 1

[SwitchC-Vfc2] quit

# Configure Ten-GigabitEthernet 1/0/2 as a trunk port, and assign the port to VLAN 10.

[SwitchC] interface ten-gigabitethernet 1/0/2

[SwitchC-Ten-GigabitEthernet1/0/2] port link-type trunk

[SwitchC-Ten-GigabitEthernet1/0/2] port trunk permit vlan 10

[SwitchC-Ten-GigabitEthernet1/0/2] quit

# Enable FCoE for VLAN 10 and map VLAN 10 to VSAN 1.

[SwitchC] vlan 10

[SwitchC-vlan10] fcoe enable vsan 1

[SwitchC-vlan10] quit

4. FCping Switch C from Switch A.

[SwitchA] fcping fcid fffc03 vsan 1

FCPING fcid 0xfffc03: 128 data bytes, press CTRL_C to break.

Request time out

--- 0xfffc03 fcping statistics ---

5 packet(s) transmitted

0 packet(s) received

100.00% packet loss

The output shows that Switch A cannot reach Switch C.

5. Use the fctracert command to identify the faulty node.

[SwitchA] fctracert fcid fffc03 vsan 1

Route present for: 0xfffc03, press CTRL_C to break

20:00:00:0b:46:00:02:82(0xfffc01)

20:00:00:05:30:00:18:db(0xfffc02)

Fctracert uncompleted: no route to destination port.

The output shows that:

? Switch A can reach Switch B.

? Switch B cannot reach Switch C.

Verifying the configuration

# Use the display fc routing-table command on Switch B to verify that there is not a route to Switch C. (Details not shown.)

Comprehensive FCoE configuration examples

FCoE configuration example (in standalone mode)

Network requirements

As shown in Figure 36:

· Switch A and Switch B are connected to an Ethernet switch, and operate at the access layer of the LAN.

· Switch A and Switch B are connected to Switch C and Switch D, respectively.

· The four switches operate as the FCF switches of the SANs.

Configure FCoE to meet the following requirements:

· The transmission network formed by Switch A, Switch B, and the Ethernet switch can use the server to provide services for the LAN. The transmission network formed by switches A through D can enable the server to access the disk device.

· Link backup is used to implement high availability for the packets to and from the server and disk device.

· The bandwidth is increased for the link between Switch A and Switch C and the link between Switch B and Switch D. Link backup and load sharing are implemented.

Figure 36 Network diagram

Requirements analysis

As a best practice to transmit the storage traffic over lossless Ethernet links in the SANs, perform the following tasks:

· Configure DCBX, PFC in auto mode, and ETS on the Ethernet interfaces connecting the switches to the server.

· Configure DCBX and PFC in auto mode on the Ethernet interfaces connecting the switches to the disk device.

· Enable PFC by force on the Ethernet interfaces connecting switches.

To implement link backup between the server and the disk device, use two separate SANs to provide connections between the server and the disk device. The two SANs can use the same VSAN. The two separate VSANs are as follows:

· One physical SAN is formed by the server, Switch A, Switch C, and the disk device.

· The other physical SAN is formed by the server, Switch B, Switch D, and the disk device.

To transmit the Ethernet traffic of the LAN in VLAN 1001, configure the following interfaces to allow VLAN 1001:

· The Ethernet interfaces connecting Switch A and Switch B to the LAN.

· The Ethernet interfaces connecting Switch A and Switch B to the server.

To transmit the storage traffic of the SANs in VSAN 100, configure the interfaces connecting the four FCF switches to the SANs to allow VSAN 100.

To transmit the storage traffic of VSAN 100 within VLAN 4001, map VLAN 4001 to VSAN 100.

To avoid physical loops in the LAN, enable STP on the Ethernet interfaces connecting Switch A and Switch B to the LAN and the server. To prevent STP from blocking the interfaces that are responsible for forwarding storage traffic on Switch A and Switch B, disable STP on the interfaces connecting the four FCF switches.

For the server to access the resources in the disk device, configure the members in the default zone to access each other.

To increase the bandwidth for the link between Switch A and Switch C and implement link backup and load sharing, configure Ethernet link aggregation group 1.

To increase the bandwidth for the link between Switch B and Switch D and implement link backup and load sharing, configure Ethernet link aggregation group 2.

Configuration restrictions and guidelines

As a best practice, build the fabric dynamically and use FSPF for FC routing when the SANs are complex.

Configuration procedures

Configuring Switch A

1. Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchA> system-view

[SwitchA] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the system to make it effective.

[SwitchA] save

The current configuration will be written to the device. Are you sure? [Y/N]:y

Please input the file name(*.cfg)[flash:/startup.cfg]

(To leave the existing filename unchanged, press the enter key):

Validating file. Please wait...

Saved the current configuration to mainboard device successfully.

Slot 1:

Save next configuration file successfully.

[SwitchA] quit

<SwitchA> reboot

Start to check configuration with next startup configuration file, please wait.........DONE!

Current configuration will be lost after the reboot, save current configuration? [Y/N]:y

Please input the file name(*.cfg)[flash:/startup.cfg]

(To leave the existing filename unchanged, press the enter key):

flash:/startup.cfg exists, overwrite? [Y/N]:y

Validating file. Please wait...

Configuration is saved to flash successfully.

This command will reboot the device. Continue? [Y/N]:y

Now rebooting, please wait...

2. Configure VLANs and interfaces:

# Create VLAN 1001 and 4001, which are intended to transmit Ethernet traffic and storage traffic, respectively.

<SwitchA> system-view

[SwitchA] vlan 1001

[SwitchA-vlan1001] description ToLAN

[SwitchA-vlan1001] quit

[SwitchA] vlan 4001

[SwitchA-vlan4001] description ToSAN

[SwitchA-vlan4001] quit

# Enable STP globally.

[SwitchA] stp global enable

# Configure interface Ten-GigabitEthernet 1/0/1 as a hybrid port.

[SwitchA] interface ten-gigabitethernet 1/0/1

[SwitchA-Ten-GigabitEthernet1/0/1] port link-type hybrid

# Assign Ten-GigabitEthernet 1/0/1 to VLAN 1001 as an untagged member.

[SwitchA-Ten-GigabitEthernet1/0/1] port hybrid vlan 1001 untagged

# Assign Ten-GigabitEthernet 1/0/1 to VLAN 4001 as a tagged member.

SwitchA-Ten-GigabitEthernet1/0/1] port hybrid vlan 4001 tagged

# Set the PVID to VLAN 1001 for the interface.

[SwitchA-Ten-GigabitEthernet1/0/1] port hybrid pvid vlan 1001

# Enable STP on Ten-GigabitEthernet 1/0/1.

[SwitchA-Ten-GigabitEthernet1/0/1] stp enable

[SwitchA-Ten-GigabitEthernet1/0/1] quit

# Configure interface Ten-GigabitEthernet 1/0/10 as a trunk port, and assign the interface to VLAN 1001.

[SwitchA] interface ten-gigabitethernet 1/0/10

[SwitchA-Ten-GigabitEthernet1/0/10] port link-type trunk

[SwitchA-Ten-GigabitEthernet1/0/10] port trunk permit vlan 1001

# Enable STP on Ten-GigabitEthernet 1/0/10.

[SwitchA-Ten-GigabitEthernet1/0/10] stp enable

[SwitchA-Ten-GigabitEthernet1/0/10] quit

# Create Layer 2 aggregate interface 1, and configure it to operate in dynamic aggregation mode.

[SwitchA] interface bridge-aggregation 1

[SwitchA-Bridge-Aggregation1] link-aggregation mode dynamic

# Disable STP on Layer 2 aggregate interface 1.

[SwitchA-Bridge-Aggregation1] undo stp enable

[SwitchA-Bridge-Aggregation1] quit

# Assign ports Ten-GigabitEthernet 1/0/5 through Ten-GigabitEthernet 1/0/8 to Layer 2 aggregation group 1.

[SwitchA] interface ten-gigabitethernet 1/0/5

[SwitchA-Ten-GigabitEthernet1/0/5] port link-aggregation group 1

[SwitchA-Ten-GigabitEthernet1/0/5] quit

[SwitchA] interface ten-gigabitethernet 1/0/6

[SwitchA-Ten-GigabitEthernet1/0/6] port link-aggregation group 1

[SwitchA-Ten-GigabitEthernet1/0/6] quit

[SwitchA] interface ten-gigabitethernet 1/0/7

[SwitchA-Ten-GigabitEthernet1/0/7] port link-aggregation group 1

[SwitchA-Ten-GigabitEthernet1/0/7] quit

[SwitchA] interface ten-gigabitethernet 1/0/8

[SwitchA-Ten-GigabitEthernet1/0/8] port link-aggregation group 1

[SwitchA-Ten-GigabitEthernet1/0/8] quit

# Configure Layer 2 aggregate interface 1 as a trunk port, and assign the aggregate interface to VLAN 4001.

[SwitchA] interface bridge-aggregation 1

[SwitchA-Bridge-Aggregation1] port link-type trunk

[SwitchA-Bridge-Aggregation1] port trunk permit vlan 4001

[SwitchA-Bridge-Aggregation1] quit

3. Configure DCBX:

# Enable LLDP globally.

[SwitchA] lldp global enable

# Create Layer 2 ACL 4000.

[SwitchA] acl mac 4000

# Configure the ACL to permit FCoE packets (protocol number is 0x8906) to pass through.

[SwitchA-acl-mac-4000] rule 0 permit type 8906 ffff

# Configure the ACL to permit FIP protocol packets (protocol number is 0x8914) to pass through.

[SwitchA-acl-mac-4000] rule 5 permit type 8914 ffff

[SwitchA-acl-mac-4000] quit

# Create a class named DCBX, configure the operator of the class as OR, and use ACL 4000 as the match criterion of the class.

[SwitchA] traffic classifier DCBX operator or

[SwitchA-classifier-DCBX] if-match acl 4000

[SwitchA-classifier-DCBX] quit

# Create a behavior named DCBX, and configure the behavior to mark packets with 802.1p priority value 3.

[SwitchA] traffic behavior DCBX

[SwitchA-behavior-DCBX] remark dot1p 3

[SwitchA-behavior-DCBX] quit

# Create a QoS policy named DCBX, associate class DCBX with traffic behavior DCBX in the QoS policy, and specify that the association apply to DCBX.

[SwitchA] qos policy DCBX

[SwitchA-qospolicy-DCBX] classifier DCBX behavior DCBX mode dcbx

[SwitchA-qospolicy-DCBX] quit

# Enable LLDP and DCBX TLV advertising on interface Ten-GigabitEthernet 1/0/1.

[SwitchA] interface ten-gigabitethernet 1/0/1

[SwitchA-Ten-GigabitEthernet1/0/1] lldp enable

[SwitchA-Ten-GigabitEthernet1/0/1] lldp tlv-enable dot1-tlv dcbx

# Apply QoS policy DCBX to the outgoing traffic of Ten-GigabitEthernet 1/0/1.

[SwitchA-Ten-GigabitEthernet1/0/1] qos apply policy DCBX outbound

4. Configure PFC:

# Enable PFC in auto mode on interface Ten-GigabitEthernet 1/0/1.

[SwitchA-Ten-GigabitEthernet1/0/1] priority-flow-control auto

# Enable PFC for 802.1p priority 3 on Ten-GigabitEthernet 1/0/1.

[SwitchA-Ten-GigabitEthernet1/0/1] priority-flow-control no-drop dot1p 3

# Configure Ten-GigabitEthernet 1/0/1 to trust the 802.1p priority carried in incoming packets.

[SwitchA-Ten-GigabitEthernet1/0/1] qos trust dot1p

[SwitchA-Ten-GigabitEthernet1/0/1] quit

# Enable PFC by force on Ten-GigabitEthernet 1/0/5.

[SwitchA] interface ten-gigabitethernet 1/0/5

[SwitchA-Ten-GigabitEthernet1/0/5] priority-flow-control enable

# Enable PFC for 802.1p priority 3 on Ten-GigabitEthernet 1/0/5.

[SwitchA-Ten-GigabitEthernet1/0/5] priority-flow-control no-drop dot1p 3

# Configure Ten-GigabitEthernet 1/0/5 to trust the 802.1p priority carried in incoming packets.

[SwitchA-Ten-GigabitEthernet1/0/5] qos trust dot1p

[SwitchA-Ten-GigabitEthernet1/0/5] quit

# Configure interfaces Ten-GigabitEthernet 1/0/6 through Ten-GigabitEthernet 1/0/8 in the same way Ten-GigabitEthernet 1/0/5 is configured.

[SwitchA] interface ten-gigabitethernet 1/0/6

[SwitchA-Ten-GigabitEthernet1/0/6] priority-flow-control enable

[SwitchA-Ten-GigabitEthernet1/0/6] priority-flow-control no-drop dot1p 3

[SwitchA-Ten-GigabitEthernet1/0/6] qos trust dot1p

[SwitchA-Ten-GigabitEthernet1/0/6] quit

[SwitchA] interface ten-gigabitethernet 1/0/7

[SwitchA-Ten-GigabitEthernet1/0/7] priority-flow-control enable

[SwitchA-Ten-GigabitEthernet1/0/7] priority-flow-control no-drop dot1p 3

[SwitchA-Ten-GigabitEthernet1/0/7] qos trust dot1p

[SwitchA-Ten-GigabitEthernet1/0/7] quit

[SwitchA] interface ten-gigabitethernet 1/0/8

[SwitchA-Ten-GigabitEthernet1/0/8] priority-flow-control enable

[SwitchA-Ten-GigabitEthernet1/0/8] priority-flow-control no-drop dot1p 3

[SwitchA-Ten-GigabitEthernet1/0/8] qos trust dot1p

[SwitchA-Ten-GigabitEthernet1/0/8] quit

5. Configure ETS:

# Configure the 802.1p-local priority mapping table to:

? Map 802.1p priority value 3 to local precedence 1.

? Map the other 802.1p priority values to local precedence 0.

[SwitchA] qos map-table dot1p-lp

[SwitchA-maptbl-dot1p-lp] import 3 export 1

[SwitchA-maptbl-dot1p-lp] import 0 export 0

[SwitchA-maptbl-dot1p-lp] import 1 export 0

[SwitchA-maptbl-dot1p-lp] import 2 export 0

[SwitchA-maptbl-dot1p-lp] import 4 export 0

[SwitchA-maptbl-dot1p-lp] import 5 export 0

[SwitchA-maptbl-dot1p-lp] import 6 export 0

[SwitchA-maptbl-dot1p-lp] import 7 export 0

[SwitchA-maptbl-dot1p-lp] quit

# Configure WRR on interface Ten-GigabitEthernet 1/0/1 as follows:

? Assign 50% of the interface bandwidth to the FCoE traffic (traffic assigned to queue 1).

? Assign 50% of the interface bandwidth to the LAN traffic (traffic assigned to queue 0).

[SwitchA] interface ten-gigabitethernet 1/0/1

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr byte-count

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr 1 group 1 byte-count 1

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr 0 group 1 byte-count 1

# Assign the other queues to the SP group on interface Ten-GigabitEthernet 1/0/1.

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr 2 group sp

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr 3 group sp

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr 4 group sp

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr 5 group sp

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr 6 group sp

[SwitchA-Ten-GigabitEthernet1/0/1] qos wrr 7 group sp

[SwitchA-Ten-GigabitEthernet1/0/1] quit

6. Configure FCoE:

# Configure the switch to operate in FCF mode.

[SwitchA] fcoe-mode fcf

# Enable the fabric configuration feature for VSAN 100. By default, the fabric configuration feature is enabled.

[SwitchA] vsan 100

[SwitchA-vsan100] domain configure enable

# Set the domain ID to 2.

[SwitchA-vsan100] domain-id 2 preferred

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

# Enable FSPF.

[SwitchA-vsan100] fspf enable

[SwitchA-vsan100] quit

# Create interface VFC 1.

[SwitchA] interface vfc 1

# Configure the mode of VFC 1 as F.

[SwitchA-Vfc1] fc mode f

# Bind VFC 1 to interface Ten-GigabitEthernet 1/0/1.

[SwitchA-Vfc1] bind interface ten-gigabitethernet 1/0/1

# Assign VFC 1 to VSAN 100 as a trunk port.

[SwitchA-Vfc1] port trunk vsan 100

[SwitchA-Vfc1] quit

# Create interface VFC 10.

[SwitchA] interface vfc 10

# Configure the mode of VFC 10 as E.

[SwitchA-Vfc10] fc mode e

# Bind VFC 10 to Layer 2 aggregate interface 1.

[SwitchA-Vfc10] bind interface bridge-aggregation 1

# Assign VFC 10 to VSAN 100 as a trunk port.

[SwitchA-Vfc10] port trunk vsan 100

# Enable FSPF for VFC 10.

[SwitchA-Vfc10] undo fspf silent vsan 100

[SwitchA-Vfc10] quit

# Enable FCoE for VLAN 4001 and map VLAN 4001 to VSAN 100.

[SwitchA] vlan 4001

[SwitchA-vlan4001] fcoe enable vsan 100

[SwitchA-vlan4001] quit

# Enter the view of VSAN 100, and configure the members in the default zone to access each other.

[SwitchA] vsan 100

[SwitchA-vsan100] zone default-zone permit

[SwitchA-vsan100] quit

Configuring Switch B

Configure Switch B in the same way Switch A is configured. On Switch B, the Layer 2 aggregate interface is Bridge-Aggregation2.

Configuring Switch C

1. Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchC> system-view

[SwitchC] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the system to make it effective.

[SwitchC] save

The current configuration will be written to the device. Are you sure? [Y/N]:y

Please input the file name(*.cfg)[flash:/startup.cfg]

(To leave the existing filename unchanged, press the enter key):

Validating file. Please wait...

Saved the current configuration to mainboard device successfully.

Slot 1:

Save next configuration file successfully.

[SwitchC] quit

<SwitchC> reboot

Start to check configuration with next startup configuration file, please wait.........DONE!

Current configuration will be lost after the reboot, save current configuration? [Y/N]:y

Please input the file name(*.cfg)[flash:/startup.cfg]

(To leave the existing filename unchanged, press the enter key):

flash:/startup.cfg exists, overwrite? [Y/N]:y

Validating file. Please wait...

Configuration is saved to flash successfully.

This command will reboot the device. Continue? [Y/N]:y

Now rebooting, please wait...

2. Configure VLANs and interfaces:

# Create 4001, which is intended to transmit storage traffic.

<SwitchC> system-view

[SwitchC] vlan 4001

[SwitchC-vlan4001] description ToSAN

[SwitchC-vlan4001] quit

# Configure interface Ten-GigabitEthernet 1/0/1 as a hybrid port.

[SwitchC] interface ten-gigabitethernet 1/0/1

[SwitchC-Ten-GigabitEthernet1/0/1] port link-type hybrid

# Assign the interface to VLAN 4001 as a tagged member.

[SwitchC-Ten-GigabitEthernet1/0/1] port hybrid vlan 4001 tagged

# Set the PVID to VLAN 4001 for Ten-GigabitEthernet 1/0/1.

[SwitchC-Ten-GigabitEthernet1/0/1] port hybrid pvid vlan 4001

[SwitchC-Ten-GigabitEthernet1/0/1] quit

# Create Layer 2 aggregate interface 1, and configure it to operate in dynamic aggregation mode.

[SwitchC] interface bridge-aggregation 1

[SwitchC-Bridge-Aggregation1] link-aggregation mode dynamic

[SwitchC-Bridge-Aggregation1] quit

# Assign ports Ten-GigabitEthernet 1/0/5 through Ten-GigabitEthernet 1/0/8 to Layer 2 aggregation group 1.

[SwitchC] interface ten-gigabitethernet 1/0/5

[SwitchC-Ten-GigabitEthernet1/0/5] port link-aggregation group 1

[SwitchC-Ten-GigabitEthernet1/0/5] quit

[SwitchC] interface ten-gigabitethernet 1/0/6

[SwitchC-Ten-GigabitEthernet1/0/6] port link-aggregation group 1

[SwitchC-Ten-GigabitEthernet1/0/6] quit

[SwitchC] interface ten-gigabitethernet 1/0/7

[SwitchC-Ten-GigabitEthernet1/0/7] port link-aggregation group 1

[SwitchC-Ten-GigabitEthernet1/0/7] quit

[SwitchC] interface ten-gigabitethernet 1/0/8

[SwitchC-Ten-GigabitEthernet1/0/8] port link-aggregation group 1

[SwitchC-Ten-GigabitEthernet1/0/8] quit

# Configure Layer 2 aggregate interface 1 as a trunk port, and assign the aggregate interface to VLAN 4001.

[SwitchC] interface bridge-aggregation 1

[SwitchC-Bridge-Aggregation1] port link-type trunk

[SwitchC-Bridge-Aggregation1] port trunk permit vlan 4001

[SwitchC-Bridge-Aggregation1] quit

3. Configure DCBX:

# Enable LLDP globally.

[SwitchC] lldp global enable

# Create Layer 2 ACL 4000.

[SwitchC] acl mac 4000

# Configure the ACL to permit FCoE packets (protocol number is 0x8906) to pass through.

[SwitchC-acl-mac-4000] rule 0 permit type 8906 ffff

# Configure the ACL to permit FIP protocol packets (protocol number is 0x8914) to pass through.

[SwitchC-acl-mac-4000] rule 5 permit type 8914 ffff

[SwitchC-acl-mac-4000] quit

# Create a class named DCBX, configure the operator of the class as OR, and use ACL 4000 as the match criterion of the class.

[SwitchC] traffic classifier DCBX operator or

[SwitchC-classifier-DCBX] if-match acl 4000

[SwitchC-classifier-DCBX] quit

# Create a behavior named DCBX, and configure the behavior to mark packets with 802.1p priority value 3.

[SwitchC] traffic behavior DCBX

[SwitchC-behavior-DCBX] remark dot1p 3

[SwitchC-behavior-DCBX] quit

# Create a QoS policy named DCBX, associate class DCBX with traffic behavior DCBX in the QoS policy, and specify that the association apply to DCBX.

[SwitchC] qos policy DCBX

[SwitchC-qospolicy-DCBX] classifier DCBX behavior DCBX mode dcbx

[SwitchC-qospolicy-DCBX] quit

# Enable LLDP and DCBX TLV advertising on interface Ten-GigabitEthernet 1/0/1.

[SwitchC] interface ten-gigabitethernet 1/0/1

[SwitchC-Ten-GigabitEthernet1/0/1] lldp enable

[SwitchC-Ten-GigabitEthernet1/0/1] lldp tlv-enable dot1-tlv dcbx

# Apply QoS policy DCBX to the outgoing traffic of Ten-GigabitEthernet 1/0/1.

[SwitchC-Ten-GigabitEthernet1/0/1] qos apply policy DCBX outbound

4. Configure PFC:

# Enable PFC in auto mode on interface Ten-GigabitEthernet 1/0/1.

[SwitchC-Ten-GigabitEthernet1/0/1] priority-flow-control auto

# Enable PFC for 802.1p priority 3 on Ten-GigabitEthernet 1/0/1.

[SwitchC-Ten-GigabitEthernet1/0/1] priority-flow-control no-drop dot1p 3

# Configure Ten-GigabitEthernet 1/0/1 to trust the 802.1p priority carried in incoming packets.

[SwitchC-Ten-GigabitEthernet1/0/1] qos trust dot1p

[SwitchC-Ten-GigabitEthernet1/0/1] quit

# Enable PFC by force on Ten-GigabitEthernet 1/0/5.

[SwitchC] interface ten-gigabitethernet 1/0/5

[SwitchC-Ten-GigabitEthernet1/0/5] priority-flow-control enable

# Enable PFC for 802.1p priority 3 on Ten-GigabitEthernet 1/0/5.

[SwitchC-Ten-GigabitEthernet1/0/5] priority-flow-control no-drop dot1p 3

# Configure Ten-GigabitEthernet 1/0/5 to trust the 802.1p priority carried in incoming packets.

[SwitchC-Ten-GigabitEthernet1/0/5] qos trust dot1p

[SwitchC-Ten-GigabitEthernet1/0/5] quit

# Configure interfaces Ten-GigabitEthernet 1/0/6 through Ten-GigabitEthernet 1/0/8 in the same way Ten-GigabitEthernet 1/0/5 is configured.

[SwitchC] interface ten-gigabitethernet 1/0/6

[SwitchC-Ten-GigabitEthernet1/0/6] priority-flow-control enable

[SwitchC-Ten-GigabitEthernet1/0/6] priority-flow-control no-drop dot1p 3

[SwitchC-Ten-GigabitEthernet1/0/6] qos trust dot1p

[SwitchC-Ten-GigabitEthernet1/0/6] quit

[SwitchC] interface ten-gigabitethernet 1/0/7

[SwitchC-Ten-GigabitEthernet1/0/7] priority-flow-control enable

[SwitchC-Ten-GigabitEthernet1/0/7] priority-flow-control no-drop dot1p 3

[SwitchC-Ten-GigabitEthernet1/0/7] qos trust dot1p

[SwitchC-Ten-GigabitEthernet1/0/7] quit

[SwitchC] interface ten-gigabitethernet 1/0/8

[SwitchC-Ten-GigabitEthernet1/0/8] priority-flow-control enable

[SwitchC-Ten-GigabitEthernet1/0/8] priority-flow-control no-drop dot1p 3

[SwitchC-Ten-GigabitEthernet1/0/8] qos trust dot1p

[SwitchC-Ten-GigabitEthernet1/0/8] quit

5. Configure FCoE:

# Configure the switch to operate in FCF mode.

[SwitchC] fcoe-mode fcf

# Enable the fabric configuration feature for VSAN 100. By default, the fabric configuration feature is enabled.

[SwitchC] vsan 100

[SwitchC-vsan100] domain configure enable

# Set the switch priority to 1, so the switch can be selected as the principal switch.

[SwitchC-vsan100] priority 1

# Set the domain ID to 1.

[SwitchC-vsan100] domain-id 1 preferred

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

# Enable FSPF.

[SwitchC-vsan100] fspf enable

[SwitchC-vsan100] quit

# Create interface VFC 1.

[SwitchC] interface vfc 1

# Configure the mode of VFC 1 as F.

[SwitchC-Vfc1] fc mode f

# Bind VFC 1 to interface Ten-GigabitEthernet 1/0/1.

[SwitchC-Vfc1] bind interface ten-gigabitethernet 1/0/1

# Assign VFC 1 to VSAN 100 as a trunk port.

[SwitchC-Vfc1] port trunk vsan 100

[SwitchC-Vfc1] quit

# Create interface VFC 10.

[SwitchC] interface vfc 10

# Configure the mode of VFC 10 as E.

[SwitchC-Vfc10] fc mode e

# Bind VFC 10 to Layer 2 aggregate interface 1.

[SwitchC-Vfc10] bind interface bridge-aggregation 1

# Assign VFC 10 to VSAN 100 as a trunk port.

[SwitchC-Vfc10] port trunk vsan 100

# Enable FSPF for VFC 10.

[SwitchC-Vfc10] undo fspf silent vsan 100

[SwitchC-Vfc10] quit

# Enable FCoE for VLAN 4001 and map VLAN 4001 to VSAN 100.

[SwitchC] vlan 4001

[SwitchC-vlan4001] fcoe enable vsan 100

[SwitchC-vlan4001] quit

# Enter the view of VSAN 100, and configure the members in the default zone to access each other.

[SwitchC] vsan 100

[SwitchC-vsan100] zone default-zone permit

[SwitchC-vsan100] quit

Configuring Switch D

Configure Switch D in the same way Switch C is configured. On Switch D, the Layer 2 aggregate interface is Bridge-Aggregation2.

Verifying the configurations

Verifying the configuration on Switch A and Switch B

Verify the configuration on Switch A and Switch B, for example, Switch A.

# Display the domain information of VSAN 100.

[SwitchA] display fc domain vsan 100

Domain Information of VSAN 100:

Running time information:

State: Stable

Switch WWN: 48:33:43:2d:46:43:1A:1A

Fabric name: 48:33:43:2d:46:43:1C:1C

Priority: 128

Domain ID: 2

Configuration information:

Domain configure: Enabled

Domain auto-reconfigure: Disabled

Fabric name: 48:33:43:2d:46:43:1A:1A

Priority: 128

Domain ID: 2 (preferred)

Principal switch running time information:

Priority: 1

Path Interface

Upstream Vfc10

The output shows that the domain configuration is complete on Switch A, and the principal switch assigns domain ID 2 to Switch A.

# Display the domain ID list of VSAN 100.

[SwitchA] display fc domain-list vsan 100

Domain list of VSAN 100:

Number of domains: 2

Domain ID WWN

0x01(1) 48:33:43:2d:46:43:1C:1C [Principal]

0x02(2) 48:33:43:2d:46:43:1A:1A [Local]

The output shows that Switch C is elected as the principal switch, and the principal switch assigns the configured domain ID (ID 1) to itself.

# Display the routing table information for Switch A.

[SwitchA] display fc routing-table vsan 100

Routing Table: VSAN 100

Destinations : 5 Routes : 5

Destination/mask Protocol Preference Cost Interface

0x010000/8 FSPF 20 100 Vfc10

0xfffc01/24 DIRECT 0 0 InLoop0

0xfffffa/24 DIRECT 0 0 InLoop0

0xfffffc/24 DIRECT 0 0 InLoop0

0xfffffd/24 DIRECT 0 0 InLoop0

The output shows that an FSPF route from Switch A to Switch C exists, with the outgoing interface VFC 10.

# Display the node login information for VSAN 100.

[SwitchA] display fc login vsan 100

Interface VSAN FCID Node WWN Port WWN

Vfc1 100 0x020000 21:01:00:1b:32:a0:fa:12 21:01:00:1b:32:a0:fa:11

# Display the brief information about the name server database in VSAN 100.

[SwitchA] display fc name-service database vsan 100

VSAN 100:

FCID Type PWWN(vendor) FC4-type:feature

0x010000 0x01(N) 10:00:00:05:30:00:25:a3 SCSI-FCP:Target

0x020000 0x01(N) 21:01:00:1b:32:a0:fa:11 SCSI-FCP:Initiator

Verifying the configuration on Switch C and Switch D

Verify the configuration on Switch C and Switch D, for example, Switch D.

# Display the node login information for VSAN 100.

[SwitchC] display fc login vsan 100

Interface VSAN FCID Node WWN Port WWN

Vfc1 100 0x010000 10:00:00:05:30:00:25:a4 10:00:00:05:30:00:25:a3

FCoE configuration example (in IRF mode)

Network requirements

As shown in Figure 37:

· Switch A and Switch B are connected to an Ethernet switch, and operate at the access layer of the LAN.

· Switch A and Switch B are connected to Switch C and Switch D, respectively.

· The four switches operate as the FCF switches of the SANs.

Configure FCoE to meet the following requirements:

· Link backup is used to implement high availability for the packets to and from the server and disk device.

· The bandwidth is increased for the link between Switch A and Switch C and the link between Switch B and Switch D. Link backup and load sharing are implemented.

· Switch A and Switch B are uniformly managed, and the hardware resources and software processing capabilities of the two switches are integrated. When one switch fails, the other switch can quickly take over to avoid service interruption.

Figure 37 Network diagram

Requirements analysis

To uniformly manage Switch A and Switch B and implement backup between them, configure Switch A and Switch B to form an IRF fabric. The IRF fabric uses Switch A as the master device. The IRF fabric operates at the access layer of the LAN and operates as the FCF switch of the SANs.

To increase the bandwidth for the link between the IRF fabric and the Ethernet switch, aggregate the links from the Ethernet switch to Switch A and Switch B.

To transmit the storage traffic over lossless Ethernet links in the SANs, perform the following tasks:

· Configure DCBX, PFC in auto mode, and ETS on the Ethernet interfaces connecting the switches to the server.

· Configure DCBX and PFC in auto mode on the Ethernet interfaces connecting the switches to the disk device.

· Enable PFC by force on the Ethernet interfaces connecting switches.

To implement link backup between the server and the disk device, use two separate SANs to provide connections between the server and the disk device. The two separate VSANs are as follows:

· One physical SAN is formed by the server, the IRF fabric, Switch C, and the disk device.

· The other physical SAN is formed by the server, the IRF fabric, Switch D, and the disk device.

To transmit the Ethernet traffic of the LAN in VLAN 1001, configure the Ethernet interfaces connecting the IRF fabric to the LAN and the server to allow VLAN 1001.

To transmit the storage traffic of the SANs in VSAN 100 and VSAN 200, perform the following tasks:

· Configure the interfaces connecting Switch A and Switch C to the SANs to allow VSAN 100.

· Configure the interfaces connecting Switch B and Switch D to the SANs to allow VSAN 200.

To transmit the storage traffic of VSAN 100 within VLAN 4001, map VLAN 4001 to VSAN 100.

To transmit the storage traffic of VSAN 200 within VLAN 4002, map VLAN 4002 to VSAN 200.

To avoid physical loops in the LAN, enable STP on the Ethernet interfaces connecting the IRF fabric to the LAN and the server. To prevent STP from blocking the interfaces that are responsible for forwarding storage traffic on the IRF fabric, disable STP on the interfaces connecting the IRF fabric to Switch C and Switch D.

For the server to access the resources in the disk device, configure the members in the default zone to access each other.

To increase the bandwidth for the link between the IRF fabric and Switch C and implement link backup and load sharing, configure Ethernet link aggregation group 1.

To increase the bandwidth for the link between the IRF fabric and Switch D and implement link backup and load sharing, configure Ethernet link aggregation group 2.

Configuration restrictions and guidelines

When you configure FCoE in IRF mode, follow these restrictions and guidelines:

· As a best practice, build the fabric dynamically and use FSPF for FC routing when the SANs are complex.

· Because the server is connected to the same IRF fabric rather than two separate devices in the two SANs, follow these guidelines:

? The two SANs must use different VSANs (for example, VSAN 100 and VSAN 200).

? The IRF fabric must connect to the two VSANs.

· An IRF port is a logical interface connecting IRF member devices. To use an IRF port, you must bind at least one physical port to it. A link formed by IRF ports is called an IRF link.

Configuration prerequisites

Before you configure FCoE in IRF mode, complete the following tasks:

· Configure Switch A and Switch B to form an IRF fabric. You can configure the IRF fabric on any IRF member device.

· Aggregate the four physical links connecting Switch A to Switch B into an IRF link, with ports IRF-port 1/1 and IRF-port 2/2 at the two ends, respectively.

For information about configuring IRF, see the Virtual Technologies Configuration Guide.

Configuration procedures

This section describes only FCoE configurations.

Configuring Switch A

1. Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchA> system-view

[SwitchA] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the system to make it effective.

[SwitchA] save

The current configuration will be written to the device. Are you sure? [Y/N]:y

Please input the file name(*.cfg)[flash:/startup.cfg]

(To leave the existing filename unchanged, press the enter key):

Validating file. Please wait...

Saved the current configuration to mainboard device successfully.

Slot 1:

Save next configuration file successfully.

[SwitchA] quit

<SwitchA> reboot

Start to check configuration with next startup configuration file, please wait.........DONE!

Current configuration will be lost after the reboot, save current configuration? [Y/N]:y

Please input the file name(*.cfg)[flash:/startup.cfg]

(To leave the existing filename unchanged, press the enter key):

flash:/startup.cfg exists, overwrite? [Y/N]:y

Validating file. Please wait...

Configuration is saved to flash successfully.

This command will reboot the device. Continue? [Y/N]:y

Now rebooting, please wait...

2. Configure VLANs and interfaces:

# Create VLAN 1001, 4001, and 4002 which are intended to transmit Ethernet traffic, storage traffic, and storage traffic, respectively.

<SwitchA> system-view

[SwitchA] vlan 1001

[SwitchA-vlan1001] description ToLAN

[SwitchA-vlan1001] quit

[SwitchA] vlan 4001

[SwitchA-vlan4001] description ToSAN_A

[SwitchA-vlan4001] quit

[SwitchA] vlan 4002

[SwitchA-vlan4002] description ToSAN_B

[SwitchA-vlan4002] quit

# Enable STP globally.

[SwitchA] stp global enable

# Configure interface Ten-GigabitEthernet 1/1/0/1 as a hybrid port.

[SwitchA] interface ten-gigabitethernet 1/1/0/1

[SwitchA-Ten-GigabitEthernet1/1/0/1] port link-type hybrid

# Assign Ten-GigabitEthernet 1/1/0/1 to VLAN 1001 as an untagged member.

[SwitchA-Ten-GigabitEthernet1/1/0/1] port hybrid vlan 1001 untagged

# Assign Ten-GigabitEthernet 1/1/0/1 to VLAN 4001 as a tagged member.

[SwitchA-Ten-GigabitEthernet1/1/0/1] port hybrid vlan 4001 tagged

# Set the PVID to VLAN 1001 for Ten-GigabitEthernet 1/1/0/1.

[SwitchA-Ten-GigabitEthernet1/1/0/1] port hybrid pvid vlan 1001

# Enable STP on Ten-GigabitEthernet 1/1/0/1.

[SwitchA-Ten-GigabitEthernet1/1/0/1] stp enable

[SwitchA-Ten-GigabitEthernet1/1/0/1] quit

# Configure interface Ten-GigabitEthernet 2/1/0/1 as a hybrid port.

[SwitchA] interface ten-gigabitethernet 2/1/0/1

[SwitchA-Ten-GigabitEthernet2/1/0/1] port link-type hybrid

# Assign Ten-GigabitEthernet 2/1/0/1 to VLAN 1001 as an untagged member.

[SwitchA-Ten-GigabitEthernet2/1/0/1] port hybrid vlan 1001 untagged

# Assign Ten-GigabitEthernet 2/1/0/1 to VLAN 4002 as a tagged member.

[SwitchA-Ten-GigabitEthernet2/1/0/1] port hybrid vlan 4002 tagged

# Set the PVID to VLAN 1001 for Ten-GigabitEthernet 2/1/0/1.

[SwitchA-Ten-GigabitEthernet2/1/0/1] port hybrid pvid vlan 1001

# Enable STP on Ten-GigabitEthernet 2/1/0/1.

[SwitchA-Ten-GigabitEthernet2/1/0/1] stp enable

[SwitchA-Ten-GigabitEthernet2/1/0/1] quit

# Configure interface Ten-GigabitEthernet 1/1/0/10 as a trunk port, and assign the interface to VLAN 1001.

[SwitchA] interface ten-gigabitethernet 1/1/0/10

[SwitchA-Ten-GigabitEthernet1/1/0/10] port link-type trunk

[SwitchA-Ten-GigabitEthernet1/1/0/10] port trunk permit vlan 1001

# Enable STP on Ten-GigabitEthernet 1/1/0/10.

[SwitchA-Ten-GigabitEthernet1/1/0/10] stp enable

[SwitchA-Ten-GigabitEthernet1/1/0/10] quit

# Configure interface Ten-GigabitEthernet 2/1/0/10 as a trunk port, and assign the interface to VLAN 1001.

[SwitchA] interface ten-gigabitethernet 2/1/0/10

[SwitchA-Ten-GigabitEthernet2/1/0/10] port link-type trunk

[SwitchA-Ten-GigabitEthernet2/1/0/10] port trunk permit vlan 1001

# Enable STP on Ten-GigabitEthernet 2/1/0/10.

[SwitchA-Ten-GigabitEthernet2/1/0/10] stp enable

[SwitchA-Ten-GigabitEthernet2/1/0/10] quit

# Create Layer 2 aggregate interface 1, and configure it to operate in dynamic aggregation mode.

[SwitchA] interface bridge-aggregation 1

[SwitchA-Bridge-Aggregation1] link-aggregation mode dynamic

# Disable STP on Layer 2 aggregate interface 1.

[SwitchA-Bridge-Aggregation1] undo stp enable

[SwitchA-Bridge-Aggregation1] quit

# Assign ports Ten-GigabitEthernet 1/1/0/5 through Ten-GigabitEthernet 1/1/0/8 to Layer 2 aggregation group 1.

[SwitchA] interface ten-gigabitethernet 1/1/0/5

[SwitchA-Ten-GigabitEthernet1/1/0/5] port link-aggregation group 1

[SwitchA-Ten-GigabitEthernet1/1/0/5] quit

[SwitchA] interface ten-gigabitethernet 1/1/0/6

[SwitchA-Ten-GigabitEthernet1/1/0/6] port link-aggregation group 1

[SwitchA-Ten-GigabitEthernet1/1/0/6] quit

[SwitchA] interface ten-gigabitethernet 1/1/0/7

[SwitchA-Ten-GigabitEthernet1/1/0/7] port link-aggregation group 1

[SwitchA-Ten-GigabitEthernet1/1/0/7] quit

[SwitchA] interface ten-gigabitethernet 1/1/0/8

[SwitchA-Ten-GigabitEthernet1/1/0/8] port link-aggregation group 1

[SwitchA-Ten-GigabitEthernet1/1/0/8] quit

# Configure Layer 2 aggregate interface 1 as a trunk port, and assign the aggregate interface to VLAN 4001.

[SwitchA] interface bridge-aggregation 1

[SwitchA-Bridge-Aggregation1] port link-type trunk

[SwitchA-Bridge-Aggregation1] port trunk permit vlan 4001

[SwitchA-Bridge-Aggregation1] quit

# Create Layer 2 aggregate interface 2, and configure it to operate in dynamic aggregation mode.

[SwitchA] interface bridge-aggregation 2

[SwitchA-Bridge-Aggregation2] link-aggregation mode dynamic

# Disable STP on Layer 2 aggregate interface 2.

[SwitchA-Bridge-Aggregation2] undo stp enable

[SwitchA-Bridge-Aggregation2] quit

# Assign ports GigabitEthernet 2/1/0/5 through GigabitEthernet 2/1/0/8 to Layer 2 aggregation group 2.

[SwitchA] interface ten-gigabitethernet 2/1/0/5

[SwitchA-Ten-GigabitEthernet2/1/0/5] port link-aggregation group 2

[SwitchA-Ten-GigabitEthernet2/1/0/5] quit

[SwitchA] interface ten-gigabitethernet 2/1/0/6

[SwitchA-Ten-GigabitEthernet2/1/0/6] port link-aggregation group 2

[SwitchA-Ten-GigabitEthernet2/1/0/6] quit

[SwitchA] interface ten-gigabitethernet 2/1/0/7

[SwitchA-Ten-GigabitEthernet2/1/0/7] port link-aggregation group 2

[SwitchA-Ten-GigabitEthernet2/1/0/7] quit

[SwitchA] interface ten-gigabitethernet 2/1/0/8

[SwitchA-Ten-GigabitEthernet2/1/0/8] port link-aggregation group 2

[SwitchA-Ten-GigabitEthernet2/1/0/8] quit

# Configure Layer 2 aggregate interface 2 as a trunk port, and assign the aggregate interface to VLAN 4002.

[SwitchA] interface bridge-aggregation 2

[SwitchA-Bridge-Aggregation2] port link-type trunk

[SwitchA-Bridge-Aggregation2] port trunk permit vlan 4002

[SwitchA-Bridge-Aggregation2] quit

# Create Layer 2 aggregate interface 3, and configure it to operate in dynamic aggregation mode.

[SwitchA] interface bridge-aggregation 3

[SwitchA-Bridge-Aggregation3] link-aggregation mode dynamic

# Enable STP on Layer 2 aggregate interface 3.

[SwitchA-Bridge-Aggregation3] stp enable

# Enable LACP MAD for Layer 2 aggregate interface 3.

[SwitchA-Bridge-Aggregation3] mad enable

You need to assign a domain ID (range: 0-4294967295)

[Current domain is: 1]:

The assigned domain ID is: 1

Info: MAD LACP only enable on dynamic aggregation interface.

[SwitchA-Bridge-Aggregation3] quit

# Assign ports Ten-GigabitEthernet 1/1/0/10 and Ten-GigabitEthernet 2/1/0/10 to Layer 2 aggregation group 3.

[SwitchA] interface ten-gigabitethernet 1/1/0/10

[SwitchA-Ten-GigabitEthernet1/1/0/10] port link-aggregation group 3

[SwitchA-Ten-GigabitEthernet1/1/0/10] quit

[SwitchA] interface ten-gigabitethernet 2/1/0/10

[SwitchA-Ten-GigabitEthernet2/1/0/10] port link-aggregation group 3

[SwitchA-Ten-GigabitEthernet2/1/0/10] quit

# Configure Layer 2 aggregate interface 3 as a trunk port, and assign the aggregate interface to VLAN 1001.

[SwitchA] interface bridge-aggregation 3

[SwitchA-Bridge-Aggregation3] port link-type trunk

[SwitchA-Bridge-Aggregation3] port trunk permit vlan 1001

[SwitchA-Bridge-Aggregation3] quit

3. Configure DCBX:

# Enable LLDP globally.

[SwitchA] lldp global enable

# Create Layer 2 ACL 4000.

[SwitchA] acl mac 4000

# Configure the ACL to permit FCoE packets (protocol number is 0x8906) to pass through.

[SwitchA-acl-mac-4000] rule 0 permit type 8906 ffff

# Configure the ACL to permit FIP protocol packets (protocol number is 0x8914) to pass through.

[SwitchA-acl-mac-4000] rule 5 permit type 8914 ffff

[SwitchA-acl-mac-4000] quit

# Create a class named DCBX, configure the operator of the class as OR, and use ACL 4000 as the match criterion of the class.

[SwitchA] traffic classifier DCBX operator or

[SwitchA-classifier-DCBX] if-match acl 4000

[SwitchA-classifier-DCBX] quit

# Create a behavior named DCBX, and configure the behavior to mark packets with 802.1p priority value 3.

[SwitchA] traffic behavior DCBX

[SwitchA-behavior-DCBX] remark dot1p 3

[SwitchA-behavior-DCBX] quit

# Create a QoS policy named DCBX, associate class DCBX with traffic behavior DCBX in the QoS policy, and specify that the association apply to DCBX.

[SwitchA] qos policy DCBX

[SwitchA-qospolicy-DCBX] classifier DCBX behavior DCBX mode dcbx

[SwitchA-qospolicy-DCBX] quit

# Enable LLDP and DCBX TLV advertising on interface Ten-GigabitEthernet 1/1/0/1.

[SwitchA] interface ten-gigabitethernet 1/1/0/1

[SwitchA-Ten-GigabitEthernet1/1/0/1] lldp enable

[SwitchA-Ten-GigabitEthernet1/1/0/1] lldp tlv-enable dot1-tlv dcbx

# Apply QoS policy DCBX to the outgoing traffic of Ten-GigabitEthernet 1/1/0/1.

[SwitchA-Ten-GigabitEthernet1/1/0/1] qos apply policy DCBX outbound

[SwitchA-Ten-GigabitEthernet1/1/0/1] quit

# Enable LLDP and DCBX TLV advertising on interface Ten-GigabitEthernet 2/1/0/1.

[SwitchA] interface ten-gigabitethernet 2/1/0/1

[SwitchA-Ten-GigabitEthernet2/1/0/1] lldp enable

[SwitchA-Ten-GigabitEthernet2/1/0/1] lldp tlv-enable dot1-tlv dcbx

# Apply QoS policy DCBX to the outgoing traffic of Ten-GigabitEthernet 2/1/0/1.

[SwitchA-Ten-GigabitEthernet2/1/0/1] qos apply policy DCBX outbound

[SwitchA-Ten-GigabitEthernet2/1/0/1] quit

4. Configure PFC:

# Enable PFC in auto mode on Ten-GigabitEthernet 1/1/0/1.

[SwitchA] interface ten-gigabitethernet 1/1/0/1

[SwitchA-Ten-GigabitEthernet1/1/0/1] priority-flow-control auto

# Enable PFC for 802.1p priority 3 on Ten-GigabitEthernet 1/1/0/1.

[SwitchA-Ten-GigabitEthernet1/1/0/1] priority-flow-control no-drop dot1p 3

# Configure Ten-GigabitEthernet 1/1/0/1 to trust the 802.1p priority carried in incoming packets.

[SwitchA-Ten-GigabitEthernet1/1/0/1] qos trust dot1p

[SwitchA-Ten-GigabitEthernet1/1/0/1] quit

# Configure Ten-GigabitEthernet 2/1/0/1 in the same way Ten-GigabitEthernet 1/1/0/1 is configured.

[SwitchA] interface ten-gigabitethernet 2/1/0/1

[SwitchA-Ten-GigabitEthernet2/1/0/1] priority-flow-control auto

[SwitchA-Ten-GigabitEthernet2/1/0/1] priority-flow-control no-drop dot1p 3

[SwitchA-Ten-GigabitEthernet2/1/0/1] qos trust dot1p

[SwitchA-Ten-GigabitEthernet2/1/0/1] quit

# Enable PFC by force on Ten-GigabitEthernet 1/1/0/5.

[SwitchA] interface ten-gigabitethernet 1/1/0/5

[SwitchA-Ten-GigabitEthernet1/1/0/5] priority-flow-control enable

# Enable PFC for 802.1p priority 3 on Ten-GigabitEthernet 1/1/0/5.

[SwitchA-Ten-GigabitEthernet1/1/0/5] priority-flow-control no-drop dot1p 3

# Configure Ten-GigabitEthernet 1/1/0/5 to trust the 802.1p priority carried in incoming packets.

[SwitchA-Ten-GigabitEthernet1/1/0/5] qos trust dot1p

[SwitchA-Ten-GigabitEthernet1/1/0/5] quit

# Configure the following interfaces in the same way Ten-GigabitEthernet 1/1/0/5 is configured:

? Ten-GigabitEthernet 1/1/0/6 through Ten-GigabitEthernet 1/1/0/8.

? Ten-GigabitEthernet 2/1/0/5 through Ten-GigabitEthernet 2/1/0/8.

[SwitchA] interface ten-gigabitethernet 1/1/0/6

[SwitchA-Ten-GigabitEthernet1/1/0/6] priority-flow-control enable

[SwitchA-Ten-GigabitEthernet1/1/0/6] priority-flow-control no-drop dot1p 3

[SwitchA-Ten-GigabitEthernet1/1/0/6] qos trust dot1p

[SwitchA-Ten-GigabitEthernet1/1/0/6] quit

[SwitchA] interface ten-gigabitethernet 1/1/0/7

[SwitchA-Ten-GigabitEthernet1/1/0/7] priority-flow-control enable

[SwitchA-Ten-GigabitEthernet1/1/0/7] priority-flow-control no-drop dot1p 3

[SwitchA-Ten-GigabitEthernet1/1/0/7] qos trust dot1p

[SwitchA-Ten-GigabitEthernet1/1/0/7] quit

[SwitchA] interface ten-gigabitethernet 1/1/0/8

[SwitchA-Ten-GigabitEthernet1/1/0/8] priority-flow-control enable

[SwitchA-Ten-GigabitEthernet1/1/0/8] priority-flow-control no-drop dot1p 3

[SwitchA-Ten-GigabitEthernet1/1/0/8] qos trust dot1p

[SwitchA-Ten-GigabitEthernet1/1/0/8] quit

[SwitchA] interface ten-gigabitethernet 2/1/0/5

[SwitchA-Ten-GigabitEthernet2/1/0/5] priority-flow-control enable

[SwitchA-Ten-GigabitEthernet2/1/0/5] priority-flow-control no-drop dot1p 3

[SwitchA-Ten-GigabitEthernet2/1/0/5] qos trust dot1p

[SwitchA-Ten-GigabitEthernet2/1/0/5] quit

[SwitchA] interface ten-gigabitethernet 2/1/0/6

[SwitchA-Ten-GigabitEthernet2/1/0/6] priority-flow-control enable

[SwitchA-Ten-GigabitEthernet2/1/0/6] priority-flow-control no-drop dot1p 3

[SwitchA-Ten-GigabitEthernet2/1/0/6] qos trust dot1p

[SwitchA-Ten-GigabitEthernet2/1/0/6] quit

[SwitchA] interface ten-gigabitethernet 2/1/0/7

[SwitchA-Ten-GigabitEthernet2/1/0/7] priority-flow-control enable

[SwitchA-Ten-GigabitEthernet2/1/0/7] priority-flow-control no-drop dot1p 3

[SwitchA-Ten-GigabitEthernet2/1/0/7] qos trust dot1p

[SwitchA-Ten-GigabitEthernet2/1/0/7] quit

[SwitchA] interface ten-gigabitethernet 2/1/0/8

[SwitchA-Ten-GigabitEthernet2/1/0/8] priority-flow-control enable

[SwitchA-Ten-GigabitEthernet2/1/0/8] priority-flow-control no-drop dot1p 3

[SwitchA-Ten-GigabitEthernet2/1/0/8] qos trust dot1p

[SwitchA-Ten-GigabitEthernet2/1/0/8] quit

5. Configure ETS:

# Configure the 802.1p-local priority mapping table as follows:

? Map 802.1p priority value 3 to local precedence 1.

? Map the other 802.1p priority values to local precedence 0.

[SwitchA] qos map-table dot1p-lp

[SwitchA-maptbl-dot1p-lp] import 3 export 1

[SwitchA-maptbl-dot1p-lp] import 0 export 0

[SwitchA-maptbl-dot1p-lp] import 1 export 0

[SwitchA-maptbl-dot1p-lp] import 2 export 0

[SwitchA-maptbl-dot1p-lp] import 4 export 0

[SwitchA-maptbl-dot1p-lp] import 5 export 0

[SwitchA-maptbl-dot1p-lp] import 6 export 0

[SwitchA-maptbl-dot1p-lp] import 7 export 0

[SwitchA-maptbl-dot1p-lp] quit

# Configure WRR on interface Ten-GigabitEthernet 1/1/0/1 as follows:

? Assign 50% of the interface bandwidth to the FCoE traffic (traffic assigned to queue 1).

? Assign 50% of the interface bandwidth to the LAN traffic (traffic assigned to queue 0).

[SwitchA] interface ten-gigabitethernet 1/1/0/1

[SwitchA-Ten-GigabitEthernet1/1/0/1] qos wrr byte-count

[SwitchA-Ten-GigabitEthernet1/1/0/1] qos wrr af1 group 1 byte-count 1

[SwitchA-Ten-GigabitEthernet1/1/0/1] qos wrr be group 1 byte-count 1

# Assign the other queues to the SP group on interface Ten-GigabitEthernet 1/1/0/1.

[SwitchA-Ten-GigabitEthernet1/1/0/1] qos wrr af2 group sp

[SwitchA-Ten-GigabitEthernet1/1/0/1] qos wrr af3 group sp

[SwitchA-Ten-GigabitEthernet1/1/0/1] qos wrr af4 group sp

[SwitchA-Ten-GigabitEthernet1/1/0/1] qos wrr ef group sp

[SwitchA-Ten-GigabitEthernet1/1/0/1] qos wrr cs6 group sp

[SwitchA-Ten-GigabitEthernet1/1/0/1] qos wrr cs7 group sp

[SwitchA-Ten-GigabitEthernet1/1/0/1] quit

# Configure WRR on interface Ten-GigabitEthernet 2/1/0/1 as follows:

? Assign 50% of the interface bandwidth to the FCoE traffic (traffic assigned to queue 1).

? Assign 50% of the interface bandwidth to the LAN traffic (traffic assigned to queue 0).

[SwitchA] interface ten-gigabitethernet 2/1/0/1

[SwitchA-Ten-GigabitEthernet2/1/0/1] qos wrr af1 group 1 byte-count 1

[SwitchA-Ten-GigabitEthernet2/1/0/1] qos wrr be group 1 byte-count 1

# Assign the other queues to the SP group on interface Ten-GigabitEthernet 2/1/0/1.

[SwitchA-Ten-GigabitEthernet2/1/0/1] qos wrr af2 group sp

[SwitchA-Ten-GigabitEthernet2/1/0/1] qos wrr af3 group sp

[SwitchA-Ten-GigabitEthernet2/1/0/1] qos wrr af4 group sp

[SwitchA-Ten-GigabitEthernet2/1/0/1] qos wrr ef group sp

[SwitchA-Ten-GigabitEthernet2/1/0/1] qos wrr cs6 group sp

[SwitchA-Ten-GigabitEthernet2/1/0/1] qos wrr cs7 group sp

[SwitchA-Ten-GigabitEthernet2/1/0/1] quit

6. Configure FCoE:

# Configure the switch to operate in FCF mode.

[SwitchA] fcoe-mode fcf

# Create VSAN 100. Enable the fabric configuration feature for VSAN 100. By default, the fabric configuration feature is enabled.

[SwitchA] vsan 100

[SwitchA-vsan100] domain configure enable

# Set the domain ID to 2.

[SwitchA-vsan100] domain-id 2 preferred

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

# Enable FSPF for VSAN 100.

[SwitchA-vsan100] fspf enable

[SwitchA-vsan100] quit

# Create VSAN 200. Enable the fabric configuration feature for VSAN 200. By default, the fabric configuration feature is enabled.

[SwitchA] vsan 200

[SwitchA-vsan200] domain configure enable

# Set the domain ID to 3.

[SwitchA-vsan200] domain-id 3 preferred

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

# Enable FSPF for VSAN 200.

[SwitchA-vsan200] fspf enable

[SwitchA-vsan200] quit

# Create interface VFC 1.

[SwitchA] interface vfc 1

# Configure the mode of VFC 1 as F.

[SwitchA-Vfc1] fc mode f

# Bind VFC 1 to interface Ten-GigabitEthernet 1/1/0/1.

[SwitchA-Vfc1] bind interface ten-gigabitethernet 1/1/0/1

# Assign VFC 1 to VSAN 100 as a trunk port.

[SwitchA-Vfc1] port trunk vsan 100

[SwitchA-Vfc1] quit

# Create interface VFC 2.

[SwitchA] interface vfc 2

# Configure the mode of VFC 2 as F.

[SwitchA-Vfc2] fc mode f

# Bind VFC 2 to interface Ten-GigabitEthernet 2/1/0/1.

[SwitchA-Vfc2] bind interface ten-gigabitethernet 2/1/0/1

# Assign VFC 2 to VSAN 200 as a trunk port.

[SwitchA-Vfc2] port trunk vsan 200

[SwitchA-Vfc2] quit

# Create interface VFC 10.

[SwitchA] interface vfc 10

# Configure the mode of VFC 10 as E.

[SwitchA-Vfc10] fc mode e

# Bind VFC 10 to Layer 2 aggregate interface 1.

[SwitchA-Vfc10] bind interface bridge-aggregation 1

# Assign VFC 10 to VSAN 100 as a trunk port.

[SwitchA-Vfc10] port trunk vsan 100

# Enable FSPF for VFC 10.

[SwitchA-Vfc10] undo fspf silent vsan 100

[SwitchA-Vfc10] quit

# Create interface VFC 11.

[SwitchA] interface vfc 11

# Configure the mode of VFC 11 as E.

[SwitchA-Vfc11] fc mode e

# Bind VFC 11 to Layer 2 aggregate interface 2.

[SwitchA-Vfc11] bind interface bridge-aggregation 2

# Assign VFC 11 to VSAN 200 as a trunk port.

[SwitchA-Vfc11] port trunk vsan 200

# Enable FSPF for VFC 11.

[SwitchA-Vfc11] undo fspf silent vsan 200

[SwitchA-Vfc11] quit

# Enable FCoE for VLAN 4001 and map VLAN 4001 to VSAN 100.

[SwitchA] vlan 4001

[SwitchA-vlan4001] fcoe enable vsan 100

[SwitchA-vlan4001] quit

# Enable FCoE for VLAN 4002 and map VLAN 4002 to VSAN 200.

[SwitchA] vlan 4002

[SwitchA-vlan4002] fcoe enable vsan 200

[SwitchA-vlan4002] quit

# Enter the view of VSAN 100, and configure the members in the default zone to access each other.

[SwitchA] vsan 100

[SwitchA-vsan100] zone default-zone permit

[SwitchA-vsan100] quit

# Enter the view of VSAN 200, and configure the members in the default zone to access each other.

[SwitchA] vsan 200

[SwitchA-vsan200] zone default-zone permit

[SwitchA-vsan200] quit

Configuring Switch C

1. Configure the switch to operate in advanced mode, save the configuration, and reboot the switch. (Skip this step if the switch is operating in advanced mode.)

<SwitchC> system-view

[SwitchC] system-working-mode advance

Do you want to change the system working mode? [Y/N]:y

The system working mode is changed, please save the configuration and reboot the system to make it effective.

[SwitchC] save

The current configuration will be written to the device. Are you sure? [Y/N]:y

Please input the file name(*.cfg)[flash:/startup.cfg]

(To leave the existing filename unchanged, press the enter key):

Validating file. Please wait...

Saved the current configuration to mainboard device successfully.

Slot 1:

Save next configuration file successfully.

[SwitchC] quit

<SwitchC> reboot

Start to check configuration with next startup configuration file, please wait.........DONE!

Current configuration will be lost after the reboot, save current configuration? [Y/N]:y

Please input the file name(*.cfg)[flash:/startup.cfg]

(To leave the existing filename unchanged, press the enter key):

flash:/startup.cfg exists, overwrite? [Y/N]:y

Validating file. Please wait...

Configuration is saved to flash successfully.

This command will reboot the device. Continue? [Y/N]:y

Now rebooting, please wait...

2. Configure VLANs and interfaces:

# Create 4001, which is intended to transmit storage traffic.

<SwitchC> system-view

[SwitchC] vlan 4001

[SwitchC-vlan4001] description ToSAN_A

[SwitchC-vlan4001] quit

# Configure interface Ten-GigabitEthernet 1/0/1 as a hybrid port.

[SwitchC] interface ten-gigabitethernet 1/0/1

[SwitchC-Ten-GigabitEthernet1/0/1] port link-type hybrid

# Assign Ten-GigabitEthernet 1/0/1 to VLAN 4001 as a tagged member.

[SwitchC-Ten-GigabitEthernet1/0/1] port hybrid vlan 4001 tagged

# Set the PVID to VLAN 4001 for Ten-GigabitEthernet 1/0/1.

[SwitchC-Ten-GigabitEthernet1/0/1] port hybrid pvid vlan 4001

[SwitchC-Ten-GigabitEthernet1/0/1] quit

# Create Layer 2 aggregate interface 1, and configure it to operate in dynamic aggregation mode.

[SwitchC] interface bridge-aggregation 1

[SwitchC-Bridge-Aggregation1] link-aggregation mode dynamic

[SwitchC-Bridge-Aggregation1] quit

# Assign ports Ten-GigabitEthernet 1/0/5 through Ten-GigabitEthernet 1/0/8 to Layer 2 aggregation group 1.

[SwitchC] interface ten-gigabitethernet 1/0/5

[SwitchC-Ten-GigabitEthernet1/0/5] port link-aggregation group 1

[SwitchC-Ten-GigabitEthernet1/0/5] quit

[SwitchC] interface ten-gigabitethernet 1/0/6

[SwitchC-Ten-GigabitEthernet1/0/6] port link-aggregation group 1

[SwitchC-Ten-GigabitEthernet1/0/6] quit

[SwitchC] interface ten-gigabitethernet 1/0/7

[SwitchC-Ten-GigabitEthernet1/0/7] port link-aggregation group 1

[SwitchC-Ten-GigabitEthernet1/0/7] quit

[SwitchC] interface ten-gigabitethernet 1/0/8

[SwitchC-Ten-GigabitEthernet1/0/8] port link-aggregation group 1

[SwitchC-Ten-GigabitEthernet1/0/8] quit

# Configure Layer 2 aggregate interface 1 as a trunk port, and assign the aggregate interface to VLAN 4001.

[SwitchC] interface bridge-aggregation 1

[SwitchC-Bridge-Aggregation1] port link-type trunk

[SwitchC-Bridge-Aggregation1] port trunk permit vlan 4001

[SwitchC-Bridge-Aggregation1] quit

3. Configure DCBX:

# Enable LLDP globally.

[SwitchC] lldp global enable

# Create Layer 2 ACL 4000.

[SwitchC] acl mac 4000

# Configure the ACL to permit FCoE packets (whose protocol number is 0x8906) to pass through.

[SwitchC-acl-mac-4000] rule 0 permit type 8906 ffff

# Configure the ACL to permit FIP protocol packets (whose protocol number is 0x8914) to pass through.

[SwitchC-acl-mac-4000] rule 5 permit type 8914 ffff

[SwitchC-acl-mac-4000] quit

# Create a class named DCBX, configure the operator of the class as OR, and use ACL 4000 as the match criterion of the class.

[SwitchC] traffic classifier DCBX operator or

[SwitchC-classifier-DCBX] if-match acl 4000

[SwitchC-classifier-DCBX] quit

# Create a behavior named DCBX, and configure the behavior to mark packets with 802.1p priority value 3.

[SwitchC] traffic behavior DCBX

[SwitchC-behavior-DCBX] remark dot1p 3

[SwitchC-behavior-DCBX] quit

# Create a QoS policy named DCBX, associate class DCBX with traffic behavior DCBX in the QoS policy, and specify that the association apply to DCBX.

[SwitchC] qos policy DCBX

[SwitchC-qospolicy-DCBX] classifier DCBX behavior DCBX mode dcbx

[SwitchC-qospolicy-DCBX] quit

# Enable LLDP and DCBX TLV advertising on interface Ten-GigabitEthernet 1/0/1.

[SwitchC] interface ten-gigabitethernet 1/0/1

[SwitchC-Ten-GigabitEthernet1/0/1] lldp enable

[SwitchC-Ten-GigabitEthernet1/0/1] lldp tlv-enable dot1-tlv dcbx

# Apply QoS policy DCBX to the outgoing traffic of Ten-GigabitEthernet 1/0/1.

[SwitchC-Ten-GigabitEthernet1/0/1] qos apply policy DCBX outbound

4. Configure PFC:

# Enable PFC in auto mode on interface Ten-GigabitEthernet 1/0/1.

[SwitchC-Ten-GigabitEthernet1/0/1] priority-flow-control auto

# Enable PFC for 802.1p priority 3 on Ten-GigabitEthernet 1/0/1.

[SwitchC-Ten-GigabitEthernet1/0/1] priority-flow-control no-drop dot1p 3

# Configure Ten-GigabitEthernet 1/0/1 to trust the 802.1p priority carried in incoming packets.

[SwitchC-Ten-GigabitEthernet1/0/1] qos trust dot1p

[SwitchC-Ten-GigabitEthernet1/0/1] quit

# Enable PFC by force on Ten-GigabitEthernet 1/0/5.

[SwitchC] interface ten-gigabitethernet 1/0/5

[SwitchC-Ten-GigabitEthernet1/0/5] priority-flow-control enable

# Enable PFC for 802.1p priority 3 on Ten-GigabitEthernet 1/0/5.

[SwitchC-Ten-GigabitEthernet1/0/5] priority-flow-control no-drop dot1p 3

# Configure Ten-GigabitEthernet 1/0/5 to trust the 802.1p priority carried in incoming packets.

[SwitchC-Ten-GigabitEthernet1/0/5] qos trust dot1p

[SwitchC-Ten-GigabitEthernet1/0/5] quit

# Configure interfaces Ten-GigabitEthernet 1/0/6 through Ten-GigabitEthernet 1/0/8 in the same way Ten-GigabitEthernet 1/0/5 is configured.

[SwitchC] interface ten-gigabitethernet 1/0/6

[SwitchC-Ten-GigabitEthernet1/0/6] priority-flow-control enable

[SwitchC-Ten-GigabitEthernet1/0/6] priority-flow-control no-drop dot1p 3

[SwitchC-Ten-GigabitEthernet1/0/6] qos trust dot1p

[SwitchC-Ten-GigabitEthernet1/0/6] quit

[SwitchC] interface ten-gigabitethernet 1/0/7

[SwitchC-Ten-GigabitEthernet1/0/7] priority-flow-control enable

[SwitchC-Ten-GigabitEthernet1/0/7] priority-flow-control no-drop dot1p 3

[SwitchC-Ten-GigabitEthernet1/0/7] qos trust dot1p

[SwitchC-Ten-GigabitEthernet1/0/7] quit

[SwitchC] interface ten-gigabitethernet 1/0/8

[SwitchC-Ten-GigabitEthernet1/0/8] priority-flow-control enable

[SwitchC-Ten-GigabitEthernet1/0/8] priority-flow-control no-drop dot1p 3

[SwitchC-Ten-GigabitEthernet1/0/8] qos trust dot1p

[SwitchC-Ten-GigabitEthernet1/0/8] quit

5. Configure FCoE:

# Configure the switch to operate in FCF mode.

[SwitchC] fcoe-mode fcf

# Enable the fabric configuration feature for VSAN 100. By default, the fabric configuration feature is enabled.

[SwitchC] vsan 100

[SwitchC-vsan100] domain configure enable

# Set the switch priority to 1, so the switch can be selected as the principal switch.

[SwitchC-vsan100] priority 1

# Set the domain ID to 1.

[SwitchC-vsan100] domain-id 1 preferred

Nondisruptive reconfiguration might be performed or the switch might be isolated. Continue? [Y/N]:y

# Enable FSPF.

[SwitchC-vsan100] fspf enable

[SwitchC-vsan100] quit

# Create interface VFC 1.

[SwitchC] interface vfc 1

# Configure the mode of VFC 1 as F.

[SwitchC-Vfc1] fc mode f

# Bind VFC 1 to interface Ten-GigabitEthernet 1/0/1.

[SwitchC-Vfc1] bind interface ten-gigabitethernet 1/0/1

# Assign VFC 1 to VSAN 100 as a trunk port.

[SwitchC-Vfc1] port trunk vsan 100

[SwitchC-Vfc1] quit

# Create interface VFC 10.

[SwitchC] interface vfc 10

# Configure the mode of VFC 10 as E.

[SwitchC-Vfc10] fc mode e

# Bind VFC 10 to Layer 2 aggregate interface 1.

[SwitchC-Vfc10] bind interface bridge-aggregation 1

# Assign VFC 10 to VSAN 100 as a trunk port.

[SwitchC-Vfc10] port trunk vsan 100

# Enable FSPF for VFC 10.

[SwitchC-Vfc10] undo fspf silent vsan 100

[SwitchC-Vfc10] quit

# Enable FCoE for VLAN 4001 and map VLAN 4001 to VSAN 100.

[SwitchC] vlan 4001

[SwitchC-vlan4001] fcoe enable vsan 100

[SwitchC-vlan4001] quit

# Enter the view of VSAN 100, and configure the members in the default zone to access each other.

[SwitchC] vsan 100

[SwitchC-vsan100] zone default-zone permit

[SwitchC-vsan100] quit

Configuring Switch D

Configure Switch D in the same way Switch C is configured. On Switch D, the VLAN, VSAN, and Layer 2 aggregate interface are VLAN 4002, VSAN 200, and Bridge-Aggregation2, respectively.

Verifying the configuration

Verifying the configuration on Switch A

1. Display information for VSAN 100:

# Display the domain information of VSAN 100.

[SwitchA] display fc domain vsan 100

Domain Information of VSAN 100:

Running time information:

State: Stable

Switch WWN: 48:33:43:2d:46:43:1A:1A

Fabric name: 48:33:43:2d:46:43:1C:1C

Priority: 128

Domain ID: 2

Configuration information:

Domain configure: Enabled

Domain auto-reconfigure: Disabled

Fabric name: 48:33:43:2d:46:43:1A:1A

Priority: 128

Domain ID: 2 (preferred)

Principal switch running time information:

Priority: 1

Path Interface

Upstream Vfc10

The output shows that the domain configuration is complete on Switch A, and the principal switch assigns domain ID 2 to Switch A.

# Display the domain list of VSAN 100.

[SwitchA] display fc domain-list vsan 100

Domain list of VSAN 100:

Number of domains: 2

Domain ID WWN

0x01(1) 48:33:43:2d:46:43:1C:1C [Principal]

0x02(2) 48:33:43:2d:46:43:1A:1A [Local]

The output shows that Switch C is elected as the principal switch, and the principal switch assigns the configured domain ID (ID 1) to itself.

# Display the routing table information for VSAN 100.

[SwitchA] display fc routing-table vsan 100

Routing Table: VSAN 100

Destinations : 5 Routes : 5

Destination/mask Protocol Preference Cost Interface

0x010000/8 FSPF 20 100 Vfc10

0xfffc01/24 DIRECT 0 0 InLoop0

0xfffffa/24 DIRECT 0 0 InLoop0

0xfffffc/24 DIRECT 0 0 InLoop0

0xfffffd/24 DIRECT 0 0 InLoop0

The output shows that an FSPF route from Switch A to Switch C exists, with the outgoing interface VFC 10.

# Display the node login information for VSAN 100.

[SwitchA] display fc login vsan 100

Interface VSAN FCID Node WWN Port WWN

Vfc1 100 0x020000 21:01:00:1b:32:a0:fa:12 21:01:00:1b:32:a0:fa:11

# Display the brief information about the name server database in VSAN 100.

[SwitchA] display fc name-service database vsan 100

VSAN 100:

FCID Type PWWN(vendor) FC4-type:feature

0x010000 0x01(N) 10:00:00:05:30:00:25:a3 SCSI-FCP:Target

0x020000 0x01(N) 21:01:00:1b:32:a0:fa:11 SCSI-FCP:Initiator

2. Display information for VSAN 200:

# Display the domain information of VSAN 200.

[SwitchA] display fc domain vsan 200

Domain Information of VSAN 200:

Running time information:

State: Stable

Switch WWN: 48:33:43:2d:46:43:1B:1B

Fabric name: 48:33:43:2d:46:43:1D:1D

Priority: 128

Domain ID: 2

Configuration information:

Domain configure: Enabled

Domain auto-reconfigure: Disabled

Fabric name: 48:33:43:2d:46:43:1B:1B

Priority: 128

Domain ID: 2 (preferred)

Principal switch running time information:

Priority: 1

Path Interface

Upstream Vfc11

The output shows that the domain configuration is complete on Switch A, and the principal switch assigns domain ID 2 to Switch A.

# Display the domain list of VSAN 200.

[SwitchA] display fc domain-list vsan 200

Domain list of VSAN 200:

Number of domains: 2

Domain ID WWN

0x01(1) 48:33:43:2d:46:43:1D:1D [Principal]

0x02(2) 48:33:43:2d:46:43:1B:1B [Local]

The output shows that Switch D is elected as the principal switch, and the principal switch assigns the configured domain ID (ID 1) to itself.

# Display the routing table information for VSAN 200.

[SwitchA] display fc routing-table vsan 200

Routing Table: VSAN 200

Destinations : 5 Routes : 5

Destination/mask Protocol Preference Cost Interface

0x010000/8 FSPF 20 100 Vfc10

0xfffc01/24 DIRECT 0 0 InLoop0

0xfffffa/24 DIRECT 0 0 InLoop0

0xfffffc/24 DIRECT 0 0 InLoop0

0xfffffd/24 DIRECT 0 0 InLoop0

The output shows that an FSPF route from Switch A to Switch C exists, with the outgoing interface VFC 10.

# Display the node login information for VSAN 200.

[SwitchA] display fc login vsan 200

Interface VSAN FCID Node WWN Port WWN

Vfc1 200 0x020000 21:01:00:1b:32:a0:fa:12 21:01:00:1b:32:a0:fa:13

# Display the brief information about the name server database in VSAN 200.

[SwitchA] display fc name-service database vsan 200

VSAN 200:

FCID Type PWWN(vendor) FC4-type:feature

0x010000 0x01(N) 10:00:00:05:30:00:25:a5 SCSI-FCP:Target

0x020000 0x01(N) 21:01:00:1b:32:a0:fa:13 SCSI-FCP:Initiator

Verifying the configuration on Switch C and Switch D

This example uses Switch C.

# Display the node login information for VSAN 100.

[SwitchC] display fc login vsan 100

Interface VSAN FCID Node WWN Port WWN

Vfc1 100 0x010000 10:00:00:05:30:00:25:a4 10:00:00:05:30:00:25:a3

Appendixes

Appendix A Fabric address assignment

Table 10 Fabric address assignment

FC address	Description
0x000000	Undefined (when an N_Port uses FLOGI to request for an address, an all-zero FC address is used).
0x000001–0x00ffff	Reserved.
0x010000–0xefffff	N_Port address.
0xf00000–0xfff9ff	Reserved.
0xfffa00–0xfffa0f	Reserved for internal loopback.
0xfffa10–0xfffa1f	Reserved for external loopback.
0xfffa20–0xfffaff	Reserved.
0xfffb00–0xfffbff	Reserved for multicast.
0xfffc00	Reserved.
0xfffc01–0xfffcef	Domain controller addresses.
0xfffcf0–0xfffef	Reserved.
0xfffff0–0xfffffc	Well-known addresses.
0xfffffd	Fabric controller address, representing all E_Ports.
0xfffffe	F_Port controller address, representing all F_Ports.
0xffffff	Broadcast address.

Appendix B Well-known fabric addresses

Table 11 Purposes of well-known fabric addresses

FC address	Description
0xfffff0	N_Port controller, representing all N_Ports.
0xfffff1–0xfffff3	Reserved.
0xfffff4	Event services.
0xfffff5	Multicast server.
0xfffff6	Clock synchronization services.
0xfffff7	Security key distribution services.
0xfffff8	Alias services.
0xfffff9	Reserved.
0xfffffa	Management services.
0xfffffb	Time services.
0xfffffc	Path services (name services).

15-FCoE Configuration Guide

FCoE overview

FC protocol

WWN

FC address

Port modes

VFC interface and VN interface

FIP protocol

FCoE frames

Procedure for receiving and sending FC frames over Ethernet

How FIP works

Configuring VFC interfaces

Configuring basic FCoE

Setting the FC-MAP value of the FCoE network

Setting the FKA advertisement interval value of the FCoE network

Setting the FCF priority of the FCoE network

Displaying and maintaining basic FCoE

Trunk VSAN in an FC network

Trunk VSAN in an FCoE network

Building a fabric

Overview

Setting the switch priority

Configuring the allowed domain ID list

Configuring a VFC interface to reject incoming RCF requests

Enabling SCSI-FCP information autodiscovery

Configuring Smart SAN

Network requirements

Configuration procedure

Verifying the configuration

Network requirements

Configuration procedure

Verifying the configuration

Configuring FC routing and forwarding

Routing table contents

FIB table contents

Basic concepts

FSPF packet types

How FSPF works

Setting the minimum LSR refresh interval

Setting the FSPF cost for an interface

Setting the hello interval for an interface

Setting the dead interval for an interface

Configuring the GR restarter

Configuring the GR helper

Displaying and maintaining FC routing and forwarding

Static FC routing configuration example

Network requirements

Configuration procedure

Verifying the configuration

Network requirements

Configuration procedure

Verifying the configuration

Configuring FC zones

Zone database structure

Active zone set

Default zone