01-Fundamentals Configuration Guide

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12-Automatic configuration
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12-Automatic configuration 234.34 KB

Using automatic configuration

About automatic configuration

When the device starts up without a valid next-startup configuration file, the device searches the root directory of its default file system for the autocfg.py, autocfg.tcl, and autocfg.cfg files. Only one of files might exist in the root directory. If any one of the files exists, the device loads the file. If none of the files exists, the device uses the automatic configuration feature to obtain a set of configuration settings.

With the automatic configuration feature, the device can automatically obtain a set of configuration settings at startup. This feature simplifies network configuration and maintenance.

Automatic configuration can be implemented by using the implementation methods in Table 1.

Table 1 Automatic configuration implementation methods

Implementation method

Configuration file location

Application scenarios

Server-based automatic configuration

File server

A number of geographically distributed devices need to be configured.

 

Using server-based automatic configuration

About server-based automatic configuration

With server-based automatic configuration, a device without a configuration file can run the DHCP client to obtain a configuration file from a file server at startup.

You can deploy server-based automatic configuration on both IPv4 and IPv6 networks by using the same method. This chapter describes the tasks for deploying server-based automatic configuration on an IPv4 network.

Typical server-based automatic configuration network

As shown in Figure 1, a typical server-based automatic configuration network consists of the following servers:

·     DHCP server.

·     File server (TFTP or HTTP server).

·     (Optional.) DNS server.

Figure 1 Server-based automatic configuration network diagram

 

Server-based automatic configuration tasks at a glance

To configure server-based automatic configuration, perform the following tasks:

1.     Configuring the file server

2.     Prepare the files for automatic configuration:

¡     Preparing configuration files

¡     Preparing script files

3.     Configuring the DHCP server

4.     (Optional.) Configuring the DNS server

5.     (Optional.) Configuring the gateway

6.     Preparing the interface used for automatic configuration

7.     Starting and completing automatic configuration

Configuring the file server

For devices to obtain configuration information from a TFTP server, start TFTP service on the file server.

For devices to obtain configuration information from an HTTP server, start HTTP service on the file server.

Preparing configuration files

Configuration file types

The device supports the configuration file types listed in Table 2.

Table 2 Configuration file types

Configuration file type

Application objects

File name requirements

Supported file server types

Dedicated configuration file

Devices that require different settings

File name.cfg

For simple file name identification, use configuration file names that do not contain spaces.

·     TFTP server

·     HTTP server

Common configuration file

Devices that share all or some settings

File name.cfg

·     TFTP server

·     HTTP server

Default configuration file

Other devices.

The file contains only common configurations that devices use to start up.

device.cfg

TFTP server

 

Identifying requirements for and preparing configuration files

1.     Identify the requirements of the devices for configuration files.

2.     For devices that require different configurations, prepare a configuration file for each of them and save the file to the file server.

3.     For devices that share all or some configurations, save the common configurations to a .cfg file on the file server.

4.     If a TFTP file server is used, you can save the common configurations that devices use to start up to the device.cfg file on the server. The file is assigned to a device only when the device does not have any other configuration file to use.

Preparing the host name file on the TFTP server

If a TFTP server is used and the DHCP server does not assign configuration file names, you can configure a host name file on the TFTP server. The host name file contains the host name-IP address mappings of the devices to be automatically configured.

To prepare the host name file:

1.     Create a host name file named network.cfg.

2.     Add each mapping entry in the ip host host-name ip-address format on a separate line. For example:

ip host host1 101.101.101.101

ip host host2 101.101.101.102

ip host client1 101.101.101.103

ip host client2 101.101.101.104

 

IMPORTANT

IMPORTANT:

The host name for a device must be the same as the name of the configuration file configured for the device.

 

Preparing script files

About script files

Script files can be used for automatic software upgrade and automatic configuration.

The device supports Python scripts (.py files) and Tcl scripts (.tcl files). For more information about Python and Tcl scripts, see "Using Python" and "Using Tcl."

The device supports dedicated script files and common dedicated script files. It does not support using a default script file. For information about dedicated script files and common dedicated script files, see Table 2.

When script files are used, you cannot use a host name file to provide the host name-IP address mappings for devices.

Restrictions and guidelines

To use a Tcl script, make sure all commands in the script are supported and correctly configured. Any error in a command causes the automatic configuration process to quit.

Procedure

·     For devices that share all or some configurations, create a script file that contains the common configurations.

·     For the other devices, create a separate script file for each of them.

Configuring the DHCP server

About the DHCP server

The DHCP server assigns the following items to devices that need to be automatically configured:

·     IP addresses.

·     Paths of the configuration or script files.

Restrictions and guidelines

When you configure the DHCP server, follow these guidelines:

·     For devices for which you have prepared different configuration files, perform the following tasks for each of the devices on the DHCP server:

¡     Create a DHCP address pool.

¡     Configure a static address binding.

¡     Specify a configuration file or script file.

Because an address pool can use only one configuration file, you can specify only one static address binding for an address pool.

·     For devices for which you have prepared the same configuration file, use either of the following methods:

¡     Method 1:

-     Create a DHCP address pool for the devices.

-     Configure a static address binding for each of the devices in the address pool.

-     Specify the configuration file for the devices.

¡     Method 2:

-     Create a DHCP address pool for the devices.

-     Specify the subnet for dynamic allocation.

-     Specify the TFTP server.

-     Specify the configuration file for the devices.

·     If all devices on a subnet share the same configuration file or script file, perform the following tasks on the DHCP server:

¡     Configure dynamic address allocation.

¡     Specify the configuration file or script file for the devices.

The configuration file can contain only the common settings for the devices. You can provide a method for the device administrators to change the configurations after their devices start up.

Configuring the DHCP server when an HTTP file server is used

1.     Enter system view.

system-view

2.     Enable DHCP.

dhcp enable

By default, DHCP is disabled.

3.     Create a DHCP address pool and enter its view.

dhcp server ip-pool pool-name

4.     Configure the address pool.

Choose the options to configure as needed:

¡     Specify the primary subnet for the address pool:

network network-address [ mask-length | mask mask ]

By default, no primary subnet is specified.

¡     Configure a static binding:

static-bind ip-address ip-address [ mask-length | mask mask ] { client-identifier client-identifier | hardware-address hardware-address [ ethernet | token-ring ] }

By default, no static binding is configured.

You can configure multiple static bindings. However, one IP address can be bound to only one client. To change the binding for a DHCP client, you must remove the binding and reconfigure a binding.

5.     Specify the URL of the configuration or script file.

bootfile-name url

By default, no configuration or script file URL is specified.

Configuring the DHCP server when a TFTP file server is used

1.     Enter system view.

system-view

2.     Enable DHCP.

dhcp enable

By default, DHCP is disabled.

3.     Create a DHCP address pool and enter its view.

dhcp server ip-pool pool-name

4.     Configure the address pool.

Choose the options to configure as needed:

¡     Specify the primary subnet for the address pool:

network network-address [ mask-length | mask mask ]

By default, no primary subnet is specified.

¡     Configure a static binding:

static-bind ip-address ip-address [ mask-length | mask mask ] { client-identifier client-identifier | hardware-address hardware-address [ ethernet | token-ring ] }

By default, no static binding is configured.

You can configure multiple static bindings. However, one IP address can be bound to only one client. To change the binding for a DHCP client, you must remove the binding and reconfigure a binding.

5.     Specify a TFTP server.

Choose one option as needed:

¡     Specify the IP address of the TFTP server:

tftp-server ip-address ip-address

By default, no TFTP server IP address is specified.

¡     Specify the name of the TFTP server:

tftp-server domain-name domain-name

By default, no TFTP server name is specified.

If you specify a TFTP server by its name, a DNS server is required on the network.

6.     Specify the name of the configuration or script file.

bootfile-name bootfile-name

By default, no configuration or script file name is specified.

Configuring the DNS server

A DNS server is required in the following situations:

·     The TFTP server does not have a host name file.

Devices need to provide the DNS server with their IP addresses to obtain their host names. Then, the devices can obtain configuration files named in the host name.cfg format from the TFTP server.

·     The DHCP server assigns the TFTP server domain name through the DHCP reply message. Devices must use the domain name to obtain the IP address of the TFTP server.

Configuring the gateway

If the devices to be automatically configured and the servers for automatic configuration reside in different network segments, you must perform the following tasks:

·     Deploy a gateway and make sure the devices can communicate with the servers.

·     Configure the DHCP relay agent feature on the gateway.

·     Configure the UDP helper feature on the gateway.

This task is required if devices send requests to a TFTP server by using broadcast packets.  A device uses broadcast packets to send requests to a TFTP server in the following situations:

¡     The DHCP reply does not contain the IP address or domain name of the TFTP server.

¡     The IP address or domain name of the TFTP server is invalid.

The UDP helper transforms a broadcast packet into a unicast packet and forwards the unicast packet to the file server. For more information about UDP helper, see Layer 3—IP Services Configuration Guide.

Preparing the interface used for automatic configuration

The device uses the following steps to select the interface for automatic configuration:

1.     Identifies the status of the management Ethernet interface at Layer 2. If the status is up, the device uses the management Ethernet interface.

2.     Identifies the status of Layer 2 Ethernet interfaces. If one or more Layer 2 Ethernet interfaces are in up state, the device uses the VLAN interface of the default VLAN.

3.     Sorts all Layer 3 Ethernet interfaces in up state first in lexicographical order of interface types and then in ascending order of interface numbers. Uses the interface with the smallest interface number among the interfaces of the first interface type.

4.     If no Layer 3 Ethernet interfaces are in up state, the device waits 30 seconds and goes to step 1 to try again.

For fast automatic device configuration, connect only the management Ethernet interface on each device to the network.

Starting and completing automatic configuration

1.     Power on the devices to be automatically configured.

If a device does not find a next-start configuration file locally, it starts the automatic configuration process to obtain a configuration file.

¡     If the device obtains a configuration file and executes the file successfully, the automatic configuration process ends.

¡     If one attempt fails, the device tries again until the maximum number of attempts is reached. To stop the process, press Ctrl+C or Ctrl+D.

If the device fails to obtain a configuration file, the device starts up without loading any configuration.

2.     Save the running configuration.

save

The device does not save the obtained configuration file locally. If you do not save the running configuration, the device must use the automatic configuration feature again after a reboot.

For more information about the save command, see Fundamentals Command Reference.

Using USB-based automatic configuration

About USB-based automatic configuration

USB-based automatic configuration enables the device to obtain a configuration file from a connected USB disk at startup.

After obtaining a configuration file, the device compares the file with its main startup configuration file. If the two files have the same settings, the device loads its main startup configuration file. If the two files have different settings, the device performs the following operations:

1.     Identifies whether its main startup configuration file is using the same name as the obtained configuration file.

¡     If yes, the device renames its main startup configuration file by adding _bak to the base name of the file, and copies the obtained configuration file.

¡     If not, the system uses the obtained configuration file to overwrite its main startup configuration file.

2.     Loads the obtained configuration file.

¡     If all commands in the obtained configuration file are successfully loaded, the device sets the obtained configuration file as the main startup configuration file.

¡     If a command in the obtained configuration file fails, the device ignores all subsequent commands in the configuration file and quits the automatic configuration.

Restrictions and guidelines

This feature is supported only on devices that have USB interfaces.

Preparing the USB disk for automatic configuration

1.     Prepare a USB disk that has only one partition.

2.     Display the serial number of the device.

display device manuinfo

For more information about this command, see Fundamentals Command Reference.

3.     Create a configuration file named Device serial number.cfg or autodeploy.cfg, and save the file to the root directory of the file system on the USB disk.

If a configuration file named Device serial number.cfg coexists with configuration file autodeploy.cfg, the configuration file named Device serial number.cfg is used.

Configuring and using USB-based automatic configuration

1.     Enable USB-based automatic configuration on the device:

a.     Enter system view.

system-view

b.     Enable USB-based automatic configuration.

autodeploy udisk enable

By default, USB-based automatic configuration is enabled.

c.     Save the running configuration.

save

A device reboot is required for USB-based automatic configuration. Save the running configuration to ensure that the USB-based automatic configuration feature takes effect after a reboot.

2.     If the IRF fabric has two or more members, shut down the IRF physical interfaces to split the IRF fabric.

3.     Connect the USB disk to the USB1 interface on the master device.

The USB disk will be identified as usba0:.

4.     Reboot the master device.

5.     Use the display current-configuration command to verify that the configuration file has been loaded correctly.

If the automatic configuration fails, the device will log the event. Display the log file named Fully qualified configuration file name.log in the USB disk root directory to locate and resolve the issue.

6.     Remove the USB disk to make sure the device does not start USB-based automatic configuration at the next reboot.

7.     If you split the IRF fabric previously, bring up the IRF physical interfaces you have shut down. Verify that the subordinate members join the IRF fabric and run the running configuration of the master device.

Server-based automatic configuration examples

Example: Using a TFTP server for automatic configuration

Network configuration

As shown in Figure 2, two departments of a company are connected to the network through gateways (Switch B and Switch C). Access devices Switch D, Switch E, Switch F, and Switch G do not have a configuration file.

Configure the servers and gateways so the access devices can obtain a configuration file to complete the following configuration tasks:

·     Enable administrators of access devices to Telnet to and manage their respective access devices.

·     Require administrators to enter their respective usernames and passwords at login.

Figure 2 Network diagram

Procedure

1.     Configure the DHCP server:

# Create a VLAN interface and assign an IP address to the interface.

<SwitchA> system-view

[SwitchA] vlan 2

[SwitchA-vlan2] port ten-gigabitethernet 1/0/1

[SwitchA-vlan2] quit

[SwitchA] interface vlan-interface 2

[SwitchA-Vlan-interface2] ip address 192.168.1.42 24

[SwitchA-Vlan-interface2] quit

# Enable DHCP.

[SwitchA] dhcp enable

# Enable the DHCP server on VLAN-interface 2.

[SwitchA] interface vlan-interface 2

[SwitchA-Vlan-interface2] dhcp select server

[SwitchA-Vlan-interface2] quit

# Configure address pool market to assign IP addresses on the 192.168.2.0/24 subnet to clients in the Marketing department. Specify the TFTP server, gateway, and configuration file name for the clients.

[SwitchA] dhcp server ip-pool market

[SwitchA-dhcp-pool-market] network 192.168.2.0 24

[SwitchA-dhcp-pool-market] tftp-server ip-address 192.168.1.40

[SwitchA-dhcp-pool-market] gateway-list 192.168.2.1

[SwitchA-dhcp-pool-market] bootfile-name market.cfg

[SwitchA-dhcp-pool-market] quit

# Configure address pool rd to assign IP addresses on the 192.168.3.0/24 subnet to clients in the R&D department. Specify the TFTP server, gateway, and configuration file name for the clients.

[SwitchA] dhcp server ip-pool rd

[SwitchA-dhcp-pool-rd] network 192.168.3.0 24

[SwitchA-dhcp-pool-rd] tftp-server ip-address 192.168.1.40

[SwitchA-dhcp-pool-rd] gateway-list 192.168.3.1

[SwitchA-dhcp-pool-rd] bootfile-name rd.cfg

[SwitchA-dhcp-pool-rd] quit

# Configure static routes to the DHCP relay agents.

[SwitchA] ip route-static 192.168.2.0 24 192.168.1.41

[SwitchA] ip route-static 192.168.3.0 24 192.168.1.43

[SwitchA] quit

2.     Configure the gateway Switch B:

# Create VLAN interfaces and assign IP addresses to the interfaces.

<SwitchB> system-view

[SwitchB] vlan 2

[SwitchB-vlan2] port ten-gigabitethernet 1/0/3

[SwitchB-vlan2] quit

[SwitchB] interface vlan-interface 2

[SwitchB-Vlan-interface2] ip address 192.168.1.41 24

[SwitchB-Vlan-interface2] quit

[SwitchB] vlan 3

[SwitchB-vlan3] port ten-gigabitethernet 1/0/1

[SwitchB-vlan3] port ten-gigabitethernet 1/0/2

[SwitchB-vlan3] quit

[SwitchB] interface vlan-interface 3

[SwitchB-Vlan-interface3] ip address 192.168.2.1 24

[SwitchB-Vlan-interface3] quit

# Enable DHCP.

[SwitchB] dhcp enable

# Enable the DHCP relay agent on VLAN-interface 3.

[SwitchB] interface vlan-interface 3

[SwitchB-Vlan-interface3] dhcp select relay

# Specify the DHCP server address.

[SwitchB-Vlan-interface3] dhcp relay server-address 192.168.1.42

3.     Configure the gateway Switch C:

# Create VLAN interfaces and assign IP addresses to the interfaces.

<SwitchC> system-view

[SwitchC] vlan 2

[SwitchC-vlan2] port ten-gigabitethernet 1/0/3

[SwitchC-vlan2] quit

[SwitchC] interface vlan-interface 2

[SwitchC-Vlan-interface2] ip address 192.168.1.43 24

[SwitchC-Vlan-interface2] quit

[SwitchC] vlan 3

[SwitchC-vlan3] port ten-gigabitethernet 1/0/1

[SwitchC-vlan3] port ten-gigabitethernet 1/0/2

[SwitchC-vlan3] quit

[SwitchC] interface vlan-interface 3

[SwitchC-Vlan-interface3] ip address 192.168.3.1 24

[SwitchC-Vlan-interface3] quit

# Enable DHCP.

[SwitchC] dhcp enable

# Enable the DHCP relay agent on VLAN-interface 3.

[SwitchC] interface vlan-interface 3

[SwitchC-Vlan-interface3] dhcp select relay

# Specify the DHCP server address.

[SwitchC-Vlan-interface3] dhcp relay server-address 192.168.1.42

4.     Configure the TFTP server:

# On the TFTP server, create a configuration file named market.cfg.

#

 sysname Market

#

 telnet server enable

#

vlan 3

#

local-user market

 password simple market

 service-type telnet

 quit

#

interface Vlan-interface3

 ip address dhcp-alloc

 quit

#

interface ten-gigabitethernet 1/0/1

 port access vlan 3

 quit

#

user-interface vty 0 63

 authentication-mode scheme

 user-role network-admin

#

return

# On the TFTP server, create a configuration file named rd.cfg.

#

 sysname RD

#

 telnet server enable

#

vlan 3

#

local-user rd

 password simple rd

 service-type telnet

 quit

#

interface Vlan-interface3

 ip address dhcp-alloc

 quit

#

interface ten-gigabitethernet 1/0/1

 port access vlan 3

 quit

#

user-interface vty 0 63

 authentication-mode scheme

 user-role network-admin

#

return

# Start TFTP service software, and specify the folder where the two configuration files reside as the working directory. (Details not shown.)

# Verify that the TFTP server and DHCP relay agents can reach each other. (Details not shown.)

Verifying the configuration

1.     Power on Switch D, Switch E, Switch F, and Switch G.

2.     After the access devices start up, display assigned IP addresses on Switch A.

<SwitchA> display dhcp server ip-in-use

IP address       Client-identifier/    Lease expiration      Type

                 Hardware address

192.168.2.2      3030-3066-2e65-3233-  May 6 05:21:25 2013   Auto(C)

                 642e-3561-6633-2d56-

                 6c61-6e2d-696e-7465-

                 7266-6163-6533

192.168.2.3      3030-3066-2e65-3230-  May 6 05:22:50 2013   Auto(C)

                 302e-3232-3033-2d56-

                 6c61-6e2d-696e-7465-

                 7266-6163-6533

192.168.3.2      3030-6530-2e66-6330-  May 6 05:23:15 2013   Auto(C)

                 302e-3335-3131-2d56-

                 6c61-6e2d-696e-7465-

                 7266-6163-6531

192.168.3.3      3030-6530-2e66-6330-  May 6 05:24:10 2013   Auto(C)

                 302e-3335-3135-2d56-

                 6c61-6e2d-696e-7465-

                 7266-6163-6532

3.     Telnet to 192.168.2.2 from Switch A.

<SwitchA> telnet 192.168.2.2

4.     Enter username market and password market as prompted. (Details not shown.)

You are logged in to Switch D or Switch E.

Example: Using an HTTP server and Tcl scripts for automatic configuration

Network configuration

As shown in Figure 3, Switch A does not have a configuration file.

Configure the servers so Switch A can obtain a Tcl script to complete the following configuration tasks:

·     Enable the administrator to Telnet to Switch A to manage Switch A.

·     Require the administrator to enter the correct username and password at login.

Figure 3 Network diagram

Procedure

1.     Configure the DHCP server:

# Enable DHCP.

<DeviceA> system-view

[DeviceA] dhcp enable

# Configure address pool 1 to assign IP addresses on the 192.168.1.0/24 subnet to clients.

[DeviceA] dhcp server ip-pool 1

[DeviceA-dhcp-pool-1] network 192.168.1.0 24

# Specify the URL of the script file for the clients.

[DeviceA-dhcp-pool-1] bootfile-name http://192.168.1.40/device.tcl

2.     Configure the HTTP server:

# Create a configuration file named device.tcl on the HTTP server.

system-view

telnet server enable

local-user user

password simple abcabc

service-type telnet

quit

user-interface vty 0 63

authentication-mode scheme

user-role network-admin

quit

 

interface ten-gigabitethernet 1/0/1

port link-mode route

ip address dhcp-alloc

return

# Start HTTP service software and enable HTTP service. (Details not shown.)

Verifying the configuration

1.     Power on Switch A.

2.     After Switch A starts up, display assigned IP addresses on Device A.

<DeviceA> display dhcp server ip-in-use

IP address       Client identifier/    Lease expiration      Type

                 Hardware address

192.168.1.2      0030-3030-632e-3239-  Dec 12 17:41:15 2013  Auto(C)

                 3035-2e36-3736-622d-

                 4574-6830-2f30-2f32

3.     Telnet to 192.168.1.2 from Device A.

<DeviceA> telnet 192.168.1.2

4.     Enter username user and password abcabc as prompted. (Details not shown.)

You are logged in to Switch A.

Example: Using an HTTP server and Python scripts for automatic configuration

Network configuration

As shown in Figure 4, Switch A does not have a configuration file.

Configure the servers so Switch A can obtain a Python script to complete the following configuration tasks:

·     Enable the administrator to Telnet to Switch A to manage Switch A.

·     Require the administrator to enter the correct username and password at login.

Figure 4 Network diagram

Procedure

1.     Configure the DHCP server:

# Enable DHCP.

<DeviceA> system-view

[DeviceA] dhcp enable

# Configure address pool 1 to assign IP addresses on the 192.168.1.0/24 subnet to clients.

[DeviceA] dhcp server ip-pool 1

[DeviceA-dhcp-pool-1] network 192.168.1.0 24

# Specify the URL of the script file for the clients.

[DeviceA-dhcp-pool-1] bootfile-name http://192.168.1.40/device.py

2.     Configure the HTTP server:

# Create a configuration file named device.py on the HTTP server.

#!usr/bin/python

 

import comware

comware.CLI(‘system-view ;telnet server enable ;local-user user ;password simple abcabc ;service-type telnet ;quit ;user-interface vty 0 63 ;authentication-mode scheme ;user-role network-admin ;quit ;interface ten-gigabitethernet 1/0/1 ;port link-mode route ;ip address dhcp-alloc ;return’)

# Start HTTP service software and enable HTTP service. (Details not shown.)

Verifying the configuration

1.     Power on Switch A.

2.     After Switch A starts up, display assigned IP addresses on Device A.

<DeviceA> display dhcp server ip-in-use

IP address       Client identifier/    Lease expiration      Type

                 Hardware address

192.168.1.2      0030-3030-632e-3239-  Dec 12 17:41:15 2013  Auto(C)

                 3035-2e36-3736-622d-

                 4574-6830-2f30-2f32

3.     Telnet to 192.168.1.2 from Device A.

<DeviceA> telnet 192.168.1.2

4.     Enter username user and password abcabc as prompted. (Details not shown.)

You are logged in to Switch A.

Example: Setting up an IRF fabric

Network configuration

As shown in Figure 5, Switch A and Switch B do not have a configuration file.

Configure the servers so the switches can obtain a Python script to complete their respective configurations and form an IRF fabric.

Figure 5 Network diagram

Procedure

1.     Assign IP addresses to the interfaces. Make sure the devices can reach each other. (Details not shown.)

2.     Configure the following files on the HTTP server:

 

File

Content

Remarks

.cfg configuration file

Commands required for IRF setup.

You can create a configuration file by copying and modifying the configuration file of an existing IRF fabric.

sn.txt

Serial numbers of the member switches.

Each SN uniquely identifies a switch.

These SNs will be used for assigning a unique IRF member ID to each member switch.

(Optional.) .ipe or .bin software image file

Software images.

If the member switches are running different software versions, you must prepare the software image file used for software upgrade.

.py Python script file

Python commands that complete the following tasks:

a     (Optional.) Verify that the flash memory has sufficient space for the files to be downloaded.

b     Download the configuration file and sn.txt.

c     (Optional.) Download the software image file and specify it as the main startup image file.

d     Resolve sn.txt and assign a unique IRF member ID to each SN.

e     Specify the configuration file as the main next-startup configuration file.

f     Reboot the member switches.

For more information about Python script configuration, see "Using Python."

 

3.     Configure Device A as the DHCP server:

# Enable DHCP.

<DeviceA> system-view

[DeviceA] dhcp enable

# Configure address pool 1 to assign IP addresses on the 192.168.1.0/24 subnet to clients.

[DeviceA] dhcp server ip-pool 1

[DeviceA-dhcp-pool-1] network 192.168.1.0 24

# Specify the URL of the script file for the clients.

[DeviceA-dhcp-pool-1] bootfile-name http://192.168.1.40/device.py

[DeviceA-dhcp-pool-1] quit

# Enable the DHCP server on Ten-GigabitEthernet 1/0/1.

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

[DeviceA-Ten-GigabitEthernet1/0/1] dhcp select server

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

4.     Power on Switch A and Switch B.

Switch A and Switch B will obtain the Python script file from the DHCP server and execute the script. After completing the IRF configuration, Switch A and Switch B reboot.

5.     After Switch A and Switch B start up again, use a cable to connect Switch A and Switch B through their IRF physical ports.

Switch A and Switch B will elect a master member. The subordinate member will reboot to join the IRF fabric.

Verifying the configuration

# On Switch A, display IRF member devices. You can also use the display irf command on Switch B to display IRF member devices.

<Switch A> display irf

MemberID  Slot  Role    Priority  CPU-Mac         Description

   1      1     Standby 1         00e0-fc0f-8c02  ---

 *+2      1     Master  30        00e0-fc0f-8c14  ---

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

 * indicates the device is the master.

 + indicates the device through which the user logs in.

 

 The Bridge MAC of the IRF is: 000c-1000-1111

 Auto upgrade                : yes

 Mac persistent              : always

 Domain ID                   : 0

 Auto merge                  : yes

The output shows that the switches have formed an IRF fabric.

 

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