HP 445946-001 User's Manual
Contents
1. Click Submit 102 Quality of Service 2 Map the 802 1p priority value to a COS queue a Click the Configure context button on the Toolbar b Open the 802 1p folder and select Priority CoS Open HP 10Gb Ethernet BL c Switch GM Switch Ports Port Based Port Mirroring 802 1p Select RPriority CoS ECoS Weight BPorts Priority Table Uplink Failure Detection c Select an 802 1p priority value Select d Select a Class of Service queue CoSQ to correlate with the 802 1p priority value e Click Submit 103 Quality of Service 3 Set the COS queue scheduling weight a Click the Configure context button on the Toolbar b Open the 802 1p folder and select CoS Weight Open HP 10Gb Ethernet BL c Switch GM System Switch Ports GA Port Based Port Mirroring 2 RMON Menu amp QoS 802 1p Priority CoS 2 CoS Weight H Pors Priority Table amp 2 Number of CoS Access Control Uplink Failure Detection c Select a Class of Service queue CoS Select 104 Quality of Service d Enter a value for the weight of the Class of Service queue e Click Submit 4 Apply verity and save the configuration h T S ip STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save Queuing and scheduling The switch can be configured with either two or eight output Class of Service queues2. e Click Submit 4 Apply verify and save the configuration h ip CONFIGURE STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save 96 Quality of Service Using DSCP values to provide QoS The six most significant bits in the TOS byte of the IP header are defined as DiffServ Code Points DSCP Packets are marked with a certain value depending on the type of treatment the packet must receive in the network device DSCP is a measure of the Quality of Service QoS level of the packet Differentiated Services concepts To differentiate between traffic flows packets can be classified by their DSCP value The Differentiated Services DS field in the IP header is an octet and the first six bits called the DS Code Point DSCP can provide QoS functions Each packet carries its own QoS state in the DSCP There are 64 possible DSCP values 0 63 Figure 12 Layer 3 IPv4 packet Version TE Length Proto Data ToS Length ID ose FCS SIP DIP T T T T T Differentiated Services Code Point DSCP unused 7 6 5 4 3 2 1 0 T The switch can perform the following actions to the DSCP e Read the DSCP value of ingress packets e Re mark the DSCP value to a new value e Map the DSCP value to an 802 1p priority Once the DSCP value is marked the switch can use it to direct traffic prioritization Per Hop Beha
3. Troubleshooting tools Introduction This appendix discusses some tools to help you use the Port Mirroring feature to troubleshoot common network problems on the switch Port Mirroring The Port Mirroring feature on the switch is very useful for troubleshooting any connection oriented problem Any traffic in or out of one or more ports can be mirrored to a single monitoring port to which a network monitor can be attached Port Mirroring can be used as a troubleshooting tool or to enhance the security of your network For example an Intrusion Detection Service IDS server can be connected to the monitor port to detect intruders attacking the network As shown in the following figure port 18 is monitoring ingress traffic traffic entering the switch on port 21 and egress traffic traffic leaving the switch on port 1 You can attach a device to port 18 to monitor the traffic on ports 21 and 1 Figure 28 Port Mirroring Monitoring 18 19 20 21 port 18 P 18 19 20 21 Switch 1 Switch 2 Egress traffic Legend Mirrored traffic Ingress traffic Egress traffic This figure shows two mirrored ports monitored by a single port Similarly you can have one mirrored port to one monitored port or many mirrored ports to one monitored port The switch does not support a single port being monitored by multiple ports because it supports only one monitored port configured at a time 191 Trouble
4. 60 VLANs Table 10 Multiple VLANs with tagging Component Blade Server 1 Description This high use blade server needs to be accessed from all VLANs and IP subnets The server has a VLAN tagging adapter installed with VLAN tagging turned on One adapter is attached to one of the switch s 10 Gbps ports that is configured for VLANs 1 and 2 One adapter is configured for VLANs 3 and 4 Because of the VLAN tagging capabilities of both the adapter and the switch the server is able to communicate on all four VLANs in this network while maintaining broadcast separation among all four VLANs and subnets Blade Server 2 This blade server belongs to VLAN 3 The port that the VLAN is attached to is configured only for VLAN 3 so VLAN tagging is off PC 1 This PC is a member of VLAN 2 and 3 Via VLAN 2 it can communicate with Server 1 PC 3 and PC 5 Using VLAN 3 it can communicate with Server 1 Server 2 and PC 4 PC 2 This PC is a member of VLAN 4 and can only communicate with Server 1 PC 3 This PC is a member of VLAN 1 and VLAN 2 Using VLAN 1 it can communicate with Server 1 and PC 5 Using VLAN 2 it can communicate with Server 1 PC 1 and PC 5 PC 4 This PC is a member of VLAN 3 and it can communicate with Server 1 Server 2 and PC 1 PC 5 This PC is a member of both VLAN 1 and VLAN 2 Using VLAN 1 it can communicate with Server 1 and PC 3 Using VLAN 2 it can communicate with Server 1 PC 1 an
5. If RADIUS authentication is used the user password on the Radius server will override the user password on the switch Also note that the password change command on the switch modifies only the use switch password and has no effect on the user password on the Radius server RADIUS authentication and user password cannot be used concurrently to access the switch 34 Accessing the switch Setting up user IDs The administrator can configure up to 10 user accounts To configure an end user account perform the following steps 1 4 Select a user ID to define gt gt cfg sys access user uid 1 Define the user name and password gt gt User ID 1 name jane Assign name jane to user ID 1 Current user name New user name jane Define the user access level By default the end user is assigned to the user access level To change the user s access level enter the user Class of Service cos command and select one of the available options gt gt User ID 1 cos lt user oper admin gt Enable the user ID gt gt cfg sys access user uid lt gt ena Once an end user account is configured and enabled the user can login to the switch using the username password combination The level of switch access is determined by the user CoS for the account The CoS corresponds to the user access levels described in the User access levels table 35 Ports and trunking Introduction The first pa
6. Meters keep the sorted packets within certain parameters You can configure a meter on an ACL and perform actions on metered traffic such as packet re marking Re marking Re marking allows for the treatment of packets to be reset based on new network specifications or desired levels of service You can configure the ACL to re mark a packet as follows e Change the DSCP value of a packet used to specify the service level traffic should receive e Change the 802 1p priority of a packet Viewing ACL statistics ACL statistics display how many packets hit matched each ACL Up to 64 statistic counters can be displayed for each ACL Precedence Group Use ACL statistics to check filter performance and debug the ACL filters You must enable statistics cfg acl acl x stats ena for each ACL that you want to monitor 91 Quality of Service ACL configuration examples Configure Access Control Lists CLI example The following configuration examples illustrate how to use Access Control Lists ACLs to block traffic These basic configurations illustrate common principles of ACL filtering NOTE Each ACL filters traffic that ingresses on the port to which the ACL is added The egrport classifier filters traffic that ingresses the port to which the ACL is added and then egresses the port specitied by egrport In most common configurations egrport is not used e Example 1 Use this configuration to block traffic to a specific host
7. Confirm changing PVID from 1 to 3 y n y 2 Add IP interfaces to VLANs gt gt Main cfg 13 if 2 ena gt gt IP Interface 2 addr 102 1 1 1 gt gt IP Interface 2 vlan 2 gt gt IP Interface 2 cfg 13 if 3 ena gt gt IP Interface 3 addr 103 1 1 1 gt gt IP Interface 3 vlan 3 Enable interface 2 Define IP address for interface 2 Add interface 2 to VLAN 2 Enable interface 3 Define IP address for interface 3 Add interface 3 to VLAN 3 3 Turn on RIP globally and enable RIP for each interface IP Forwarding must be on cfg 13 frwd on before you turn RIP on gt gt Main cfg 13 rip on Turn on RIP globally gt gt Routing Information Protocol if 2 ena Enable RIP on IP interface 2 gt gt RIP Interface 2 gt gt Routing Information Protocol if 3 ena Enable RIP on IP interface 3 gt gt RIP Interface 3 apply Apply your changes gt gt RIP Interface 3 save Save the configuration Use the maint route dump command to check the current valid routes in the routing table of the switch For those RIP learned routes within the garbage collection period that are routes phasing out of the routing table with metric 16 use the info 13 rip routes command Locally configured static routes do not appear in the RIP Routes table 117 IGMP Snooping Introduction IGMP Snooping allows the switch to forward multicast traffic only to those ports tha
8. This configuration creates an RMON event that sends a SYSLOG message each time it is triggered by an alarm 165 Remote monitoring Configuring RMON Events BBI example 1 Configure an RMON Event group a Click the Configure context button b Open the Switch folder and select RMON gt Event gt Add Event Group Open HP 10Gb Ethernet BL c Switch E System GA Switch Ports Port Based Port Mirroring G Layer2 3 RMON Menu History E Alarm Select add Add Event Group Layer 3 E Qos Access Control Uplink Failure Detection c Configure RMON Event Group parameters This configuration creates an RMON event that sends a SYSLOG message each time it is triggered by an alarm Description SYSLOG generation event 2 Click Submit 3 Apply verify and save the configuration O STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save 166 High availability Introduction Switches support high availability network topologies This release provides information about Uplink Failure Detection and Virtual Router Redundancy Protocol VRRP Uplink Failure Detection Uplink Failure Detection UFD is designed to support Network Adapter Teaming on HP server blades For details about Network Adapter Teaming on HP ProLiant server blades see the white paper at the following location http h18004 www1 hp com products servers networkin
9. gt gt TACACS Server usermap 2 Current privilege mapping for remote privilege 2 not set Enter new local privilege mapping user gt gt TACACS Server usermap 3 user gt gt TACACS Server usermap 4 user gt gt TACACS Server usermap 5 oper 6 Apply and save the configuration 28 Accessing the switch Configuring TACACS authentication on the switch BBI example 1 Configure TACACS authentication for the switch a Click the Configure context button b Open the System folder and select Tacacs Open HP 10Gb Ethernet BL c Switch Select c Enter the IP address of the primary and secondary TACACS servers and enter the TACACS secret Enable TACACS d Click Submit 29 Accessing the switch e Ke custom privilege level mapping optional Click Submit to accept each mapping change STATISTICS DASHBOARD Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save Secure Shell and Secure Copy Secure Shell SSH and Secure Copy SCP use secure tunnels to encrypt and secure messages between a remote administrator and the switch Telnet does not provide this level of security The Telnet method of managing a switch does not provide a secure connection SSH is a protocol that enables remote administrators to log securely into the switch over a network to execute management commands By default SSH is disabled off on the switch SCP is typically used to copy files secure
10. 1 Enable OSPF authentication for Area O on switches 1 2 and 3 gt gt cfig 13 ospf aindex 0 auth password 2 Configure a simple text password up to eight characters for each OSPF IP interface in Area O on switches 1 2 and 3 gt gt cfg 13 ospf if 1 gt gt OSPF Interface 1 key test gt gt OSPF Interface 1 if 2 gt gt OSPF Interface 2 key test gt gt OSPF Interface 1 if 3 gt gt OSPF Interface 3 key test 3 Enable OSPF authentication for Area 2 on switch 4 gt gt cfg l3 ospf aindex 2 auth password 4 Configure a simple text password up to eight characters for the virtual link between Area 2 and Area 0 on switches 2 and 4 gt gt cfg l3 ospf virt 1 key packard 139 OSPF Use the following commands to configure MD5 authentication on the switches shown in the figure 1 Enable OSPF MD5 authentication for Area O on switches 1 2 and 3 gt gt cfg 13 ospf aindex 0 auth md5 2 Configure MD5 key ID for Area 0 on switches 1 2 and 3 gt gt cfig 13 ospf md5key 1 key test 3 Assign MD5 key ID to OSPF interfaces on switches 1 2 and 3 gt gt cfg 13 ospf if 1 gt gt OSPF Interface 1 mdkey gt gt OSPF Interface if gt gt OSPF Interface mdkey gt gt OSPF Interface if gt gt OSPF Interface mdkey 4 Enable OSPF MD5 authentication for Area 2 on switch 4 gt gt cfg 13 ospf aindex 2 auth md5 5
11. 5 RMON Menu GA History amp Alarm Select dd Add Alarm Group L Event E Layer 3 E QoS Access Control Uplink Failure Detection Open 162 Remote monitoring c Configure RMON Alarm Group parameters to check if InOctets on port 20 once every hour Enter a rising limit of two billion and a rising event index of 6 This configuration creates an RMON alarm that checks if InOctets on port 20 once every hour If the statistic exceeds two billion an alarm is generated that triggers event index 6 2 Click Submit 3 Apply verify and save the configuration O STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save 163 Remote monitoring Configure RMON Alarms BBI example 2 1 Configure an RMON Alarm group a Click the Configure context button b Open the Switch folder and select RMON gt Alarm gt Add Alarm Group HP 10Gb Ethernet BL c Switch i System gg Switch Ports i Port Based Port Mirroring Layer 2 5 RMON Menu History i Alarm Select add Add Alarm Group Eg Event fa Layer 3 Qos i Access Control Uplink Failure Detection c Configure RMON Alarm Group parameters to check icmpInEchos with a polling interval of 60 a rising limit of 200 and a rising event index of 5 This configuration creates an RMON alarm that checks icmpInEchos on the switch once every minute If the statistic exceeds 200 within a 60 second interval an
12. Add port 21 to trunk group 5 Trunk group 5 ena Enable trunk group 5 Trunk group 5 apply Make your changes active cfg 12 trunk 3 Select trunk group 3 Trunk group 3 add 18 Add port 18 to trunk group 3 Trunk group 3 add 19 Add port 19 to trunk group 3 Trunk group 3 ena Enable trunk group 3 rm runk group 3 apply Make your changes active mm runk group 3 save Save for restore after reboot 2 On Switch 2 configure trunk groups 4 and 2 cfig 12 trunk 4 Select trunk group 4 Trunk group 4 add 20 Add port 20 to trunk group 4 Trunk group 4 add 21 Add port 21 to trunk group 4 Trunk group 4 ena Enable trunk group 4 Trunk group 4 apply Make your changes active cfg 12 trunk 2 Select trunk group 2 Trunk group 2 add 18 Add port 18 to trunk group 2 Trunk group 2 add 19 Add port 19 to trunk group 2 Trunk group 2 ena Enable trunk group 2 m runk group 2 apply Make your changes active m runk group 2 save Save for restore after reboot NOTE In this example two switches are used Any third party device supporting link aggregation should be configured manually Connection problems might arise when using automatic trunk group negotiation on the third party device 3 Examine the trunking information on each switch using the following command gt gt info 12 trunk View trunking information Information about each port in each configured trunk group is displaye
13. COSq into which each packet is placed Each packet s 802 1p priority determines its COSq except when an ACL action sets the COSq of the packet Each COS queue uses Weighted Round Robin WRR scheduling with user configurable weight from O to 15 The weight of O zero indicates strict priority which might starve the low priority queues You can configure the following attributes for COS queues e Map 802 1p priority value to a COS queue e Define the scheduling weight of each COS queue Use the 802 1p menu c g qos 8021p to configure Class of Service queues 105 Basic IP routing This chapter provides configuration background and examples for using the HP 10GbE switch to perform IP routing functions The following topics are addressed in this chapter IP Routing Benefits Routing Between IP Subnets Example of Subnet Routing Defining IP Address Ranges for the Local Route Cache Dynamic Host Configuration Protocol IP routing benefits The switch uses a combination of configurable IP switch interfaces and IP routing options The switch IP routing capabilities provide the following benefits Connects the server IP subnets to the rest of the backbone network Provides another means to invisibly introduce Jumbo frame technology into the server switched network by automatically fragmenting UDP Jumbo frames when routing to non Jumbo frame VLANs or subnets Provides the ability to route IP traffic between multiple Virtua
14. VLAN 3 add 18 Current ports for VLAN 3 2 Pending new ports for VLAN 3 18 gt gt cfg 12 vlan 4 gt gt VLAN 4 add 20 Port 20 is an UNTAGGED port and its current PVID is 1 Confirm changing PVID from 1 to 2 y n y Current ports for VLAN 4 empty Pending new ports for VLAN 4 20 gt gt apply Apply the port configurations gt gt save Save the port configurations The external Layer 2 switches should also be configured for VLANs and tagging 63 VLANs Configuring ports and VLANs on Switch 1 BBI example To configure ports and VLANs on Switch 1 do the following 1 On the switch 1 enable VLAN tagging on the necessary ports a Click the Configure context button on the Toolbar b Open the Switch folder and select Switch Ports click the underlined text not the folder Open 3 HP 10Gb Ethernet BL c Switch System Select Switch Ports GM Port Based Port Mirroring GA RMON Menu QoS Access Control Uplink Failure Detection c Click a port number to select it Select 64 VLANs d Enable the port and enable VLAN tagging e Click Submit 2 Configure the VLANs and their member ports a Open the Virtual LANs folder and select Add VLAN HP 10Gb Ethernet BL c Switch GA Switch Ports GA Port Based Port Mirroring Virtual LANs add Add VLAN i Spanning Tree Groups MSTP RSTP Select 65 VLANs b Enter the VLAN name VLAN ID
15. cfg 13 rtrid 10 10 14 1 Set static router ID Enable OSPF gt gt IP cfg 13 ospf on Define the backbone This version of switch software requires that a backbone index be configured on the non backbone end of the virtual link as follows gt gt Open Shortest Path First aindex 0 Select the menu for area index 0 gt gt OSPF Area index 0 areaid 0 0 0 0 Set the area ID for OSPF area 0 gt gt OSPF Area index 0 enable Enable the area 151 10 11 12 13 14 Define the transit area OSPF gt gt OSPF Area index 0 aindex 1 Select menu for area index 1 gt gt OSPF Area index 1 areaid 0 0 0 1 Set the area ID for OSPF area 1 gt gt OSPF Area index 1 type transit Define area as transit type gt gt OSPF Area index 1 enable Enable the area Define the stub area gt gt OSPF Area index 1 aindex 2 Select the menu for area index 2 gt gt OSPF Area index 2 areaid 0 0 0 2 Set the area ID for OSPF area 2 gt gt OSPF Area index 2 type stub Define area as stub type gt gt OSPF Area index 2 enable Enable the area Attach the network interface to the backbone gt gt OSPF Area index 2 if 1 Select OSPF menu for IP interface 1 gt gt OSPF Interface 1 aindex 1 Attach network to transit area index gt gt OSPF Interface 1 enable Enable the transit area interface Attach the network interfac
16. gt OSPF Area index 0 areaid 0 0 0 0 Set the area ID gt gt OSPF Area index 0 type transit Define backbone as transit type gt gt OSPF Area index 0 enable Enable the area 6 Define the transit area 7 The area that contains the virtual link must be configured as a transit area gt gt OSPF Area index 0 aindex 1 Select menu for area index 1 gt gt OSPF Area index 1 areaid 0 0 0 1 Set the area ID for OSPF area 1 gt gt OSPF Area index 1 type transit Define area as transit type gt gt OSPF Area index 1 enable Enable the area 150 10 11 12 Attach the network interface to the backbone OSPF gt gt OSPF Area index 1 if 1 gt gt OSPF Interface 1 aindex 0 gt gt OSPF Interface 1 enable Select OSPF menu for IP interface 1 Attach network to backbone index Enable the backbone interface Attach the network interface to the transit area gt gt OSPF Interface 1 if 2 gt gt OSPF Interface 2 aindex 1 gt gt OSPF Interface 2 enable Configure the virtual link Select OSPF menu for IP interface 2 Attach network to transit area index Enable the transit area interface The nbr router ID configured in this step must be the same as the router ID that will be configured for Switch B in step 2 Appl gt gt OSPF Interface 2 virt 1 gt gt OSPF Virtual Link 1 aindex 1 gt gt OSPF Virt
17. gt gt Main cfg acl acl 255 Define ACL 255 gt gt ACL 255 ipv4 dip 100 10 1 116 255 255 255 255 gt gt Filtering IPv4 gt gt ACL 255 action deny gt gt ACL 255 cfg port 20 aclqos Add ACL to port 20 gt gt Port 20 ACL add acl 255 gt gt Port 20 ACL apply gt gt Port 20 ACL save In this example all traffic that ingresses on port 20 is denied if it is destined for the host at IP address 100 10 1 116 e Example 2 Use this configuration to block traffic from a network destined for a specific host address gt gt Main cfg acl acl 256 Define ACL 256 gt gt ACL 256 ipv4 sip 100 10 1 0 255 255 255 0 gt gt ACL 256 ipv4 dip 200 20 1 116 255 255 255 255 gt gt Filtering IPv4 gt gt ACL 256 action deny gt gt ACL 256 cfg port 20 aclqos Add ACL to port 20 gt gt Port 20 ACL add acl 256 gt gt Port 20 ACL apply gt gt Port 20 ACL save In this example all traffic that ingresses on port 20 with source IP from the class 100 10 1 0 24 and destination IP 200 20 1 116 is denied 92 Quality of Service e Example 3 Use this configuration to block traffic from a source that is destined for a specific egress port gt gt Main cfg acl acl 1 Define ACL 1 gt gt ACL 1 ethernet smac 00 21 00 00 00 00 ff ff ff ff ff ff gt gt Filtering Ethernet gt gt ACL 1 action deny gt gt ACL 1 stats e gt gt ACL 1 cfg acl acl 257 De
18. gt gt IGMP Port 21 apply Make your changes active Configuring a Static Mrouter CLI example 1 Configure a port to which the static Mrouter is connected and enter the appropriate VLAN 2 Appl gt gt cfg 13 igmp mrouter Select IGMP Mrouter menu gt gt Static Multicast Routert add 20 Add port 20 as Static Mrouter port Enter VLAN number 1 4094 1 Enter the VLAN number Enter the version number of mrouter 1 2 3 2 Enter the IGMP version number verify and save the configuration gt gt Static Multicast Router apply Apply the configuration gt gt Static Multicast Router cur View the configuration gt gt Static Multicast Router save Save the configuration 122 IGMP Snooping Configuring IGMP Snooping BBI example 1 Configure port and VLAN membership on the switch as described in the Configuring ports and VLANs BBI example section in the VLANs chapter 2 Configure IGMP Snooping a Click the Configure context button b Open the IGMP folder and select IGMP Snooping click the underlined text not the folder HP 10Gb Ethernet BL c Switch System Ga Switch Ports Port Based Port Mirroring E Layer 2 E RMON Menu Open Layer 3 IP Interfaces Default Gateways 53 IGMP Select IGMP Snooping IGMP Filters 9 IGMP Static Mrouter Domain Name System 123 IGMP Snooping c Enable IGMP Snoop
19. 1 Confirm changing PVID from 1 to 2 y n y Current ports for VLAN 2 1 18 Pending new ports for VLAN 2 20 gt gt VLAN 3 add 18 18 to VLAN 3 Current ports for VLAN 3 Pending new ports for VLAN 3 18 gt gt apply Apply the port configurations gt gt save Save the port configurations 62 VLANs Configuring ports and VLANs on Switch 2 CLI example To configure ports and VLANs on Switch 2 do the following 1 On Switch 2 enable VLAN tagging on the necessary ports Port 4 connection to server 2 remains untagged so it is not configured below Main cfg port 2 Select port 2 connection to server 1 gt gt Port 2 tage Current VLAN tag support disabled New VLAN tag support enabled Port 2 changed to tagged Main cfg port 18 Select uplink port 18 gt gt Port 18 tag e Enable tagging Current VLAN tag support disabled New VLAN tag support enabled Port 18 changed to tagged gt gt Port 18 apply Apply the port configurations 2 Configure the VLANs and their member ports Since all ports are by default configured for VLAN 1 configure only those ports that belong to other VLANs gt gt cfg 12 vlan 3 gt gt VLAN 3 add 2 Current ports for VLAN 3 empty Pending new ports for VLAN 3 2 gt gt VLAN 3 add 4 Port 4 is an UNTAGGED port and its current PVID is 1 Confirm changing PVID from 1 to 2 y n y Current ports for VLAN 3 2 Pending new ports for VLAN 3 gt gt
20. 1 2 Primary Default Router 1 18 2 Secondary Default Router 1 19 2 3 Common Servers 1 4 1 3 Common Servers 2 4 2 3 3 Add the switch ports to their respective VLANs 110 4 The VLANs shown in the table above are configured as follows gt gt cfg 12 vlan 1 Select VLAN 1 gt gt VLAN 1 add port 20 9 10 Examine the resulting information If any settings are incorrect make the appropriate changes 11 Each Basic IP routing gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt c lt lt lt lt lt eee LAN 1 ena LAN 2 ena gt gt VLAN 3 ena LAN 1 add port 21 LAN 1 VLAN 2 LAN 2 add port 18 LAN 2 add port 19 LAN 2 VLAN 3 LAN 3 add port 1 LAN 3 add port 2 Add port for Add port for Enable VLAN 1 Select VLAN 2 Add port for Add port for Enable VLAN 2 Add port for Select VLAN 3 Select port f Enable VLAN 3 1st floor to VLAN 1 2nd floor to VLAN 1 default router 1 default router 2 default router 3 or common server 1 time you add a port to a VLAN you may get the following prom pt Port 4 is an untagged port and its current PVID is 1 Confirm changing PVID from 1 to 2 y n Enter y to set the default Port VLAN ID PVID for the port Add each IP interface to the appropriate VLAN Now that the ports are separated into three VLANs the IP interface for each subne
21. 127 The following source IP addresses are granted or not granted access to the switch A host with a source IP address of 192 192 192 21 falls within the defined range and would be allowed to access the switch A host with a source IP address of 192 192 192 192 falls outside the defined range and is not granted access To make this source IP address valid you would need to shift the host to an IP address within the valid range specified by the mnet and mmask or modify the mnet to be 192 192 192 128 and the mmask to be 255 255 255 128 This would put the 192 192 192 192 host within the valid range allowed by the mnet and mmask 192 192 192 128 255 RADIUS authentication and authorization The switch supports the Remote Authentication Dial in User Service RADIUS method to authenticate and authorize remote administrators for managing the switch This method is based on a client server model The Remote Access Server RAS the switch is a client to the back end database server A remote user the remote administrator interacts only with the RAS not the back end server and database RADIUS authentication consists of the following components A protocol with a frame format that utilizes User Datagram Protocol UDP over IP based on Request For Comments RFC 2138 and 2866 A centralized server that stores all the user authorization information A client in this case the switch The switch acting as the RADIUS client communicates to t
22. 2 100 Select Define Assign Enable Select Define vlan 20 Assign ena Enable Select addr 10 0 1 101 Define mask ena addr mask ena 255 255 255 0 10 0 2 100 255 255 255 0 Define Enable Select Define Define Enable interface 1 IP address for interface 1 VLAN 10 to interface 1 interface 1 interface 2 IP address for interface 2 VLAN 20 to interface 2 interface 2 interface 3 IP address for interface 3 subnet mask for interface 3 interface 3 interface 4 IP address for interface 4 subnet mask for interface 4 interface 4 3 Configure the default gateways Each default gateway points to one of the Layer 2 routers 4 Turn gt gt gt gt gt gt gt gt gt gt gt gt cfg 13 9w 1 Default gateway Default gateway Default gateway Layer 3 gw 2 Default gateway Default gateway 1 addr 192 168 2 1 1 ena 1 1 addr 192 168 1 1 1 ena Select default gateway 1 Point gateway to the first L2 router Enable the default gateway Select default gateway 2 Point gateway to the second router Enable the default gateway on VRRP and configure two Virtual Interface Routers Virtual Router Redundancy Protocol vr 1 cfg 13 vrrp on gt gt gt gt VRRP Virtual Router 1 gt gt VRRP Virtual Router 1 gt gt VRRP Virtual Router 1 gt gt VRRP Virtual Router 1 gt gt
23. 3 uname usr gname usrgrp c sys ssnmp snmpv3 view 6 Create views for user name usr tree 14356 LI4s1 11425347 IL3IILL ZL Agent statistics c sys ssnmp snmpv3 view 7 name usr tre 1 13 61 45 15112307 Opi ieee Ue Agent information c sys ssnmp snmpv3 view 8 name usr tree 2 3 26 edo Sh z Pr eee statistics c sys ssnmp snmpv3 view 9 name usr tree 236 144 LILT x e e information c sys ssnmp snmpv3 view 10 name usr tree 1 3 6 1 4 1 11 2 3 7 11 33 1 2 3 statistics c sys ssnmp snmpv3 view 11 name usr tree 1 436 L1144La 1ls2434 75 MERET information 16 Accessing the switch CLI oper equivalent To configure an SNMP user equivalent to the CLI oper use the following configuration c sys ssnmp snmpv3 usm 5 name oper Configure the oper c sys ssnmp snmpv3 access 4 name opergrp Configure access group 4 rview oper wview oper nview oper c sys ssnmp snmpv3 group 4 Assign oper to access group 4 uname oper gname opergrp c sys ssnmp snmpv3 view 20 Create views for oper name oper tree 1 3 6 1 4 1 11 42 3 7 11 333 1 2 14 Agent statistics c sys ssnmp snmpv3 view 21 name oper tree 1 3 6 1 4 1 11 2 3 7 p els 2 edie Agent information c sys ssnmp snmpv3 view 22 name oper tree T 1 3 6 1 4 1 11 2 3 7 3 ae ee ae statistics c sys ssnmp snmpv3 view 23 name oper tree 1 3 6 1 4 1 11 2 3 7 P ine eee information c sys ssnmp snmpv3 view
24. ASBRs such as area O and area 2 in the figure there are multiple routes leading from the area In such areas traffic for unrecognized destinations cannot tell which route leads upstream without further configuration To resolve the situation and select one default route among multiple choices in an area you can manually configure a metric value on each ABR The metric assigns a priority to the ABR for its selection as the priority default route in an area The following command is used for setting the metric value gt gt cfg 13 ospf default lt metric value gt lt metric type 1 or 2 gt where lt metric values sets the priority for choosing this switch for default route The value none sets no default and 1 sets the highest priority for default route Metric type determines the method for influencing routing decisions for external routes To clear a default route metric from the switch use the following command gt gt cfg 13 ospf default none Virtual links Usually all areas in an OSPF AS are physically connected to the backbone In some cases where this is not possible you can use a virtual link Virtual links are created to connect one area to the backbone through another non backbone area The area which contains a virtual link must be a transit area and have full routing information Virtual links cannot be configured inside a stub area or NSSA The area type must be defined as transit using the
25. LACP trunk group with Partner switch ports 1 and 2 At the same time Actor switch ports 20 and 21 form a different LACP trunk group with a different partner LACP automatically determines which member links can be aggregated and then aggregates them It provides for the controlled addition and removal of physical links for the link aggregation Each port in the HP 1OGbE switch can have one of the following LACP modes e off default The user can configure this port in to a regular static trunk group e active The port is capable of forming an LACP trunk This port sends LACPDU packets to partner system ports e passive The port is capable of forming an LACP trunk This port only responds to the LACPDU packets sent from an LACP active port Each active LACP port transmits LACP data units LACPDUs while each passive LACP port listens for LACPDUs During LACP negotiation the admin key is exchanged The LACP trunk group is enabled as long as the information matches at both ends of the link If the admin key value changes for a port at either end of the link that port s association with the LACP trunk group is lost When the system is initialized all ports by default are in LACP of mode and are assigned unique admin keys To make a group of ports aggregatable you assign them all the same admin key You must set the port s LACP mode to active to activate LACP negotiation You can set other port s LACP mode to passive to
26. Ports GA Port Based Port Mirroring Layer 2 Ga 802 1x 9 Spanning Tree Groups 53 MSTP RSTP E General ECIST Bridge i BCIsT Prs Select BupLink Fast b Enter the Bridge Priority Maximum Age and Forward Delay values Vian ID Name Vlan ID Name T Default VLAN c Click Submit 83 RSTP and MSTP 4 Configure Common Internal Spanning Tree CIST port parameters a Open the MSTP RSTP folder and select CIST Ports HP 10Gb Ethernet BL c Switch System GM Switch Ports GA Port Based Port Mirroring Layer 2 802 1x GA Virtual LANs GM Spanning Tree Groups 5 MSTP RSTP E General i BCIST Bridge Select A CIST Parts yTrunk Groups Open 84 RSTP and MSTP c Enter the Port Priority Path Cost and select the Link Type Set the CIST Port State to ON d Click Submit 5 Apply verify and save the configuration O STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save 85 Quality of Service Introduction Quality of Service features allow you to allocate network resources to mission critical applications at the expense of applications that are less sensitive to such factors as time delays or network congestion You can configure your network to prioritize specific types of traffic ensuring that each type receives the appropriate Quality of Service QoS level The following topics
27. This section provides steps to configure IGMP Snooping on the switch using the Command Line Interface CLI or the Browser based Interface BBI Configuring IGMP Snooping CLI example 1 Configure port and VLAN membership on the switch as described in the Configuring ports and VLANs CLI example section in the VLANs chapter 2 Add VLANs to IGMP Snooping and enable the feature gt gt cfg 13 igmp on Globally turn IGMP on gt gt IGMP snoop Select IGMP Snooping menu gt gt IGMP Snoop add 1 Add VLAN 1 to IGMP Snooping gt gt IGMP Snoop apply 3 Enable IGMPv3 Snooping optional gt gt IGMP Snoop igmpv3 Select IGMPv3 menu gt gt IGMP V3 Snoop ena Enable IGMPv3 Snooping Make your changes active 4 Apply and save the configuration gt gt IGMP V3 Snoop apply Apply the configuration gt gt IGMP V3 Snoop save Save your changes 5 View dynamic IGMP information gt gt info 13 igmp Select IGMP Information menu gt gt IGMP Multicast dump Show IGMP Group information Note Local groups 224 0 0 x are not snooped and will not appear Source Group VLAN Port Version Mode Expires Fwd 224 10 2 0 232 1 0 0 2 18 V3 INC 4 17 Yes 228 12 1 0 232 1 0 4 2 18 V3 INC 4 18 Yes 235 2 0 1 3 21 V3 INC No 236 1 0 2 3 21 V3 EXC Yes gt gt info 13 igmp mrouter Access Mrouter information menu gt gt Mrouter dump Show IGMP Group information VLAN P
28. a DHCP server that also does BOOTP you do not have to configure the MAC address If you do not have a BOOTP server you must manually configure an IP address Accessing the switch The following example shows how to manually configure an IP address on the switch 1 2 Configure an IP interface for the Telnet connection using the sample IP address of 205 21 17 3 The pending subnet mask address and broadcast address are automatically calculated gt gt cfg 13 if 1 Select IP interface 1 gt gt IP Interface 1 addr 205 21 17 3 Assign IP address for the interface Current IP address 0 0 0 0 New pending IP address 205 21 17 3 Pending new subnet mask 255 255 255 0 gt gt IP Interface 1 ena Enable IP interface 1 If necessary configure up to two default gateways Configuring the default gateways allows the switch to send outbound traffic to the routers gt gt IP Interface 5 gw 1 Select primary default gateway gt gt Default gateway 1 addr 205 21 17 1 Assign IP address for primary router gt gt Default gateway 1 ena Enable primary default gateway Default gateway 1 gw 2 Select secondary default gateway Default gateway 2 addr 205 21 17 2 Assign address for secondary router Default gateway 2 ena Enable secondary default gateway Apply verify and save the configuration gt gt Default gateway 2 apply Apply the configuration gt gt Default gateway 2 save Save the configurat
29. a given destination are calculated and the next hops for all equal cost paths are inserted into the routing table If redundant routes via multiple routing processes such as OSPF RIP BGP or static routes exist on your network the switch defaults to the OSPF derived route 140 OSPF OSPF features not supported in this release The following OSPF features are not supported in this release Summarizing external routes Filtering OSPF routes Using OSPF to forward multicast routes Configuring OSPF on non broadcast multi access networks such as frame relay X 25 and ATM OSPF configuration examples A summary of the basic steps for configuring OSPF on the switch is listed here Detailed instructions for each of the steps are covered in the following sections Configure IP interfaces One IP interface is required for each desired network range of IP addresses being assigned to an OSPF area on the switch Optional Configure the router ID The router ID is required only when configuring virtual links on the switch Enable OSPF on the switch Define the OSPF areas Configure OSPF interface parameters IP interfaces are used for attaching networks to the various areas Optional Configure route summarization between OSPF areas Optional Configure virtual links Optional Configure host routes Example 1 Simple OSPF domain CLI example In this example two OSPF areas are defined one area is the backbone and th
30. address Built in fault tolerance Since each trunk group is composed of multiple physical links the trunk group is inherently fault tolerant As long as even one physical link between the switches is available the trunk remains active Statistical load distribution is maintained whenever a link in a trunk group is lost or returned to service Before you configure trunks When you create and enable a trunk the trunk members switch ports take on certain settings necessary for correct operation of the trunking feature Before you configure your trunk you must consider these settings along with specific configuration rules as follows 37 6 Ports and trunking Read the configuration rules provided in the Trunk group configuration rules section Determine which switch ports up to six are to become trunk members the specific ports making up the trunk Ensure that the chosen switch ports are set to enabled using the following command cfg port x cur Trunk member ports must have the same VLAN configuration Consider how the existing spanning tree will react to the new trunk configuration See the Spanning Tree Protocol chapter for spanning tree group configuration guidelines Consider how existing VLANs will be affected by the addition of a trunk Trunk group configuration rules The trunking feature operates according to specific configuration rules When creating trunks consider the following rules
31. alarm is generated that triggers event index 5 Open Alam foriemplnEchos 2 Click Submit 164 3 Apply verify and save the configuration O Remote monitoring STATISTICS DASHBOARD RMON group 9 events Apply Save Revert Diff Dump 2 Verify 3 Save The RMON Event group allows you to define events that are triggered by alarms An event can be a log message an SNMP trap message or both When an alarm is generated it triggers a corresponding event notification Use the cfg rmon alarm x revtidx and fevtidx commands to correlate an event index to an alarm RMON events use SNMP and syslogs to send notifications Therefore an SNMP trap host must be configured for trap event notification to work properly RMON uses a SYSLOG host to send syslog messages Therefore an existing SYSLOG host c g sys syslog must be configured for event log notification to work properly Each log event generates a SYSLOG of type RMON that corresponds to the event Configuring RMON Events CLI example 1 Configure the RMON Event parameters 2 Appl gt gt cfg rmon event 5 gt gt RMON Event 5 descn SYSLOG generation event gt gt RMON Event 5 type log gt gt RMON Event 5 owner Owner event 5 Select RMON Event 5 and save the configuration gt gt RMON Alarm 5 apply gt gt RMON Alarm 5 save Make your changes active Save for restore after reboot
32. area IDs e Area index and area ID agree cfg 13 ospf aindex 0 areaid 0 0 0 0 Use index O to set area O in ID octet format cfg 13 ospf aindex 1 areaid 0 0 0 1 Use index 1 to set area 1 in ID octet format e Area index set to an arbitrary value cfg 13 ospf aindex 1 areaid 0 0 0 0 Use index 1 to set area O in ID octet format cfg 13 ospf aindex 2 areaid 0 0 0 1 Use index 2 to set area 1 in ID octet format 135 OSPF Using the area ID to assign the OSPF area number The OSPF area number is defined in the areaid lt IP address gt option The octet format is used in order to be compatible with two different systems of notation used by other OSPF network vendors There are two valid ways to designate an area ID e Placing the area number in the last octet 0 0 0 n Most common OSPF vendors express the area ID number as a single number For example the Cisco IOS based router command network 1 1 1 0 0 0 0 255 area 1 defines the area number simply as area 1 On the switch using the last octet in the area ID area 1 is equivalent to areaid 0 0 0 1 e Multioctet IP address Some OSPF vendors express the area ID number in multi octet format For example area 2 2 2 2 represents OSPF area 2 and can be specified directly on the switch as areaid 2 2 2 2 NOTE Although both types of area ID formats are supported be sure that the area IDs are in the same format throughout an area Attaching an area to a network Once an OSPF
33. area has been defined it must be associated with a network To attach the area to a network you must assign the OSPF area index to an IP interface that participates in the area The format for the command is as follows gt gt cfg 13 ospf if lt interface number gt aindex lt area index gt For example the following commands could be used to configure IP interface 14 for a presence on the 10 10 10 1 24 network to define OSPF area 1 and to attach the area to the network gt gt cfg 13 if 14 Select menu for IP interface 14 gt gt IP Interface 14 addr 10 10 10 1 Define IP address on backbone network gt gt IP Interface 14 mask 255 255 255 0 Define IP mask on backbone gt gt IP Interface 14 ena Enable IP interface 14 gt gt IP Interface 14 ospf aindex 1 Select menu for area index 1 gt gt OSPF Area index 1 areaid 0 0 0 1 Define area ID as OSPF area 1 gt gt OSPF Area index 1 ena Enable area index 1 gt gt OSPF Area index 1 if 14 Select OSPF menu for interface 14 gt gt OSPF Interface 14 aindex 1 Attach area to network on interface 14 gt gt OSPF Interface 14 enable Enable interface 14 for area index 1 Interface cost The OSPF link state algorithm Dijkstra s algorithm places each routing device at the root of a tree and determines the cumulative cost required to reach each destination Usually the cost is inversely proportional to the ba
34. availability A backup router can stop receiving advertisements for one of two reasons the master can be down or all communications links between the master and the backup can be down If the master has failed it is clearly desirable for the backup or one of the backups if there is more than one to become the master NOTE If the master is healthy but communication between the master and the backup has failed there will then be two masters within the virtual router To prevent this from happening configure redundant links to be used between the switches that form a virtual router Failover methods With service availability becoming a major concern on the Internet service providers are increasingly deploying Internet traffic control devices such as application switches in redundant configurations Traditionally these configurations have been hot standby configurations where one switch is active and the other is in a standby mode A non VRRP hotstandby configuration is shown in the figure below Figure 25 Non VRRP hotstandby configuration Intranet Clients Active Links Primary Switch IP 200 200 200 100 A Internet B Servers NFS Server Secondary Switch IP 200 200 200 101 Backup Links While hotstandby configurations increase site availability by removing single points of failure service providers increasingly view them as an inefficient use of network resources because one functional application switch
35. each port PVID is configurable to any VLAN number between 1 and 4094 The default configuration settings for switches have all ports set as untagged members of VLAN 1 with all ports configured as PVID 1 In the default configuration example shown in the following figure all incoming packets are assigned to VLAN 1 by the default port VLAN identifier PVID 1 Viewing and configuring PVIDs You can view PVIDs from the following CLI commands Port information gt gt info port Port Tag RMON PVID VLAN s Downlink1 Downlink2 Downlink3 Downlink4 Downlink5 Downlink6 Downlink7 Port configuration gt gt cfg port 21 pvid 21 Current port VLAN ID 1 New pending port VLAN ID 21 gt gt Port 21 Each port on the switch can belong to one or more VLANs and each VLAN can have any number of switch ports in its membership Any port that belongs to multiple VLANs however must have VLAN tagging enabled See the VLAN tagging section in this chapter Any untagged frames those with no VLAN specified are classified with the PVID of the sending port 54 VLANs VLAN tagging The switch supports IEEE 802 1Q VLAN tagging providing standards based VLAN support for Ethernet systems Tagging places the VLAN identifier in the frame header allowing each port to belong to multiple VLANs When you configure multiple VLANs on a port you must also enable tagging on that port Since tagging fundamentally change
36. each port is in the expected state 43 Ports and trunking Configurable Trunk Hash algorithm Link This feature allows you to configure the particular parameters for the HP 10GbE switch Trunk Hash algorithm instead of having to utilize the defaults You can configure new default behavior for Layer 2 traffic and Layer 3 traffic using the CLI menu cfg 12 thash You can select a minimum of one or a maximum of two parameters to create one of the following configurations e Source IP SIP e Destination IP DIP e Source MAC SMAC e Destination MAC DMAC e Source IP SIP Destination IP DIP e Source MAC SMAC Destination MAC DMAC Aggregation Control Protocol Link Aggregation Control Protocol LACP is an IEEE 802 3ad standard for grouping several physical ports into one logical port known as a dynamic trunk group or Link Aggregation group with any device that supports the standard Refer to the IEEE 802 3ad 2002 for a full description of the standard The 802 3ad standard allows standard Ethernet links to form a single Layer 2 link using the Link Aggregation Control Protocol LACP Link aggregation is a method of grouping physical link segments of the same media type and speed in full duplex and treating them as if they were part of a single logical link segment If a link in a LACP trunk group fails traffic is reassigned dynamically to the remaining link s of the dynamic trunk group NOTE Currently LACP i
37. following command gt gt cfig 13 ospf aindex lt area index gt type transit The virtual link must be configured on the routing devices at each endpoint of the virtual link though they may traverse multiple routing devices To configure a switch as one endpoint of a virtual link use the following command gt gt cfg 13 ospf virt lt link number gt aindex lt area index gt nbr lt router ID gt where lt link numbers is a value between 1 and 3 lt area index gt is the OSPF area index of the transit area and lt router ID is the IP address of the virtual neighbor nbr the routing device at the target endpoint Another router ID is needed when configuring a virtual link in the other direction To provide the switch with a router ID see Router ID For a detailed configuration example on Virtual Links see Example 2 Virtual Links Router ID Routing devices in OSPF areas are identified by a router ID The router ID is expressed in IP address format The IP address of the router ID is not required to be included in any IP interface range or in any OSPF area The router ID can be configured in one of the following two ways e Dynamically OSPF protocol configures the lowest IP interface IP address as the router ID This is the default e Statically Use the following command to manually configure the router ID gt gt cfg 13 rtrid lt IP address gt To modify
38. gt gt Default gateway 1 addr 192 168 1 1 Point gateway to the first L2 router gt gt Default gateway 1 ena Enable the default gateway gt gt Default gateway 1 gt gt Layer 3 gw 2 Select default gateway 2 gt gt Default gateway 1 addr 192 168 2 1 Point gateway to the second router gt gt Default gateway 1 ena Enable the default gateway 4 Turn on VRRP and configure two Virtual Interface Routers cfg 13 vrrp on Turn VRRP on gt gt Virtual Router Redundancy Protocol vr 1 Select virtual router 1 gt gt VRRP Virtual Router 1 vrid 1 Set VRID to 1 gt gt VRRP Virtual Router 1 if 1 Set interface 1 gt gt VRRP Virtual Router 1 addr 192 168 1 200 Define IP address gt gt VRRP Virtual Router 1 ena Enable virtual router 1 gt gt VRRP Virtual Router 1 Enable virtual router 1 gt gt Virtual Router Redundancy Protocol vr 2 Select virtual router 2 gt gt VRRP Virtual Router 2 vrid 2 Set VRID to 2 gt gt VRRP Virtual Router 2 if 2 Set interface 2 gt gt VRRP Virtual Router 2 addr 192 168 2 200 Define IP address gt gt VRRP Virtual Router 2 ena Enable virtual router 2 5 Enable tracking on ports Set the priority of Virtual Router 1 to 101 so that it becomes the Master cfg 13 vrrp vr 1 Select VRRP virtual router 1 gt gt VRRP Virtual Router 1 track ports ena Set tracking on ports gt gt VRRP Virtual Router 1 Priority Trackin
39. it to the backbone area 0 Click Submit Select Add OSPF Interface 3 OSPF Routing Protocol Select Add Add OSPF Interface OSPF Hue Redistribution 148 e Configure the OSPF Interface 2 and attach it to the stub area 1 OSPF Interface Configuration OSPF IP Interface Identifier 1 255 Enabled Area Number 0 2 Router Priority 0 255 Output Cost 1 65535 Hello Interval 1 65535 sec Dead Interval 1 65535 sec Transit Delay 1 3600 sec Retransmit Interval 1 3600 sec LOU MD5 Key ID 1 255 Authentication Key I Delete f Click Submit 6 Apply verify and save the configuration LA invent CONFIGURE STATISTICS DASHBOARD Apply Save 1 Apply 3 Save Revert Diff Dump 2 Verify 149 OSPF Example 2 Virtual links In the example shown in the following figure area 2 is not physically connected to the backbone as is usually required Instead area 2 will be connected to the backbone via a virtual link through area 1 The virtual link must be configured at each endpoint Figure 22 Configuring a virtual link Backbone Transit Area Stub Area 7 Area Ore nme oa Reet oo 10GbE z Brea2 7 0000 VEN 0 0 0 1 s 10 7 aw 10 10 12 1 10 10 12 2 I Virtual Link 1 l N 10 10 7 0 24 _ Router ID N 10 10 12 0 24 7 N 10GbE 10 10 24 0 24 N Net
40. log in to the switch ssh lt user gt lt switch IP address gt For example gt gt ssh admin 205 178 15 157 Downloading configuration from the switch using SCP Enter the following command to download the switch configuration using SCP You will be prompted for a password scp lt user gt lt switch IP address gt getcfg lt local filename gt For example gt gt scp scpadmin 205 178 15 157 getcfg ad4 cfg The switch prompts you for the scpadmin password Uploading configuration to the switch using SCP Enter the following command to upload configuration to the switch You will be prompted for a password scp lt local filename gt lt user gt lt switch IP address gt putcfg For example gt gt scp ad4 cfg admin 205 178 15 157 putcfg Ne N Accessing the switch Applying and saving configuration Enter the apply and save commands after the command above scp ad4 cfg 205 178 15 157 putcfg or use the following commands You will be prompted for a password gt gt scp lt local filename gt lt user gt lt switch IP addr gt putcfg apply gt gt scp lt local filename gt lt user gt lt switch IP addr gt putcfg apply save For example gt gt scp ad4 cfg admin 205 178 15 157 putcfg apply gt gt scp ad4 cfg admin 205 178 15 157 putcfg apply save NOTE e The diff command is automatically executed at the end of put cfg to notify the remote client of the difference between the ne
41. number and enable the VLAN To add ports select each port in the Ports Available list and click Add Since all ports are configured for VLAN 1 by default configure only those ports that belong to VLAN 2 VLAN New Configuration VLAN ID 1 4095 From h VLAN State Spanning Tree Group Ports Available Ports in Vlan TU o a w gt a Oone MN c Click Submit The external Layer 2 switches should also be configured for VLANs and tagging 3 Apply verify and save the configuration h po T SE if CONFIGURE STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save FDB static entries Static entries in the Forwarding Database FDB allow the switch to forward packets without flooding ports to perform a lookup A FDB static entry is a MAC address associated with a specific port and VLAN The switch supports 128 static entries Static entries are manually configured using the following command cfg 12 fdb static 66 VLANs FDB static entries are permanent so the FDB Aging value does not apply to them Static entries are manually added to the FDB and manually deleted from the FDB Incoming frames that contain the static entry as the source MAC can use only ports configured for the static entry Trunking support for FDB static entries A FDB static entry can be added to a port that is a member of a trunk group as follows e Static ma
42. reduce the amount of LACPDU traffic at the initial trunk forming stage Use the info 12 trunk command or the info 12 lacp dump command to check whether the ports are trunked NOTE If you configure LACP on ports with 802 1x network access control make sure the ports on both sides of the connection are properly configured for both LACP and 802 Ix 45 Ports and trunking Configuring LACP Use the following procedure to configure LACP for port 20 and port 21 to participate in link aggregation 1 Set the LACP mode on port 20 gt gt cfg 12 lacp port 20 Select port 20 gt gt LACP port 20 mode active Set port 20 to LACP active mode 2 Define the admin key on port 20 Only ports with the same admin key can form a LACP trunk group gt gt LACP port 20 adminkey 100 Set port 20 adminkey to 100 Current LACP port adminkey 17 New pending LACP port adminkey 100 3 Set the LACP mode on port 21 gt gt cfg 12 lacp port 21 Select port 21 gt gt LACP port 21 mode active Set port 21 to LACP active mode 4 Define the admin key on port 21 gt gt LACP port 21 adminkey 100 Set port 21 adminkey to 100 Current LACP port adminkey 18 New pending LACP port adminkey 100 5 Apply and verify the configuration gt gt LACP port 21 apply Make your changes active gt gt LACP port 21 cur View current trunking configuration 6 Save your new configuration changes gt gt LA
43. router IP address If the master fails one of the backup virtual routers will take control of the virtual router IP address and actively process traffic addressed to it With VRRP Virtual Interface Routers VIR allows two VRRP routers to share an IP interface across the routers VIRs provide a single Destination IP DIP for upstream routers to reach various servers and provide a virtual default Gateway for the server blades VRRP components Virtual Virtual Each physical router running VRRP is known as a VRRP router router Two or more VRRP routers can be configured to form a virtual router RFC 2338 Each VRRP router may participate in one or more virtual routers Each virtual router consists of a user configured virtual router identifier VRID and an IP address router MAC address The VRID is used to build the virtual router MAC Address The five highest order octets of the virtual router MAC Address are the standard MAC prefix 00 00 5E 00 01 defined in RFC 2338 The VRID is used to form the lowest order octet Owners and renters Only one of the VRRP routers in a virtual router may be configured as the IP address owner This router has the virtual router s IP address as its real interface address This router responds to packets addressed to the virtual router s IP address for ICMP pings TCP connections and so on There is no requirement for any VRRP router to be the IP address owner Most VRRP installations cho
44. save updated configuration Enabling or disabling SCP apply and save Enter the following commands from the switch CLI to enable the SCP putcfg_apply and putcfg apply save commands gt gt cfg sys sshd ena Enable SCP apply and save gt gt cfg sys sshd dis Disable SCP apply and save SSHD apply Apply the changes 31 Accessing the switch Configuring the SCP administrator password To configure the scpadmin SCP administrator password first connect to the switch via the RS 232 management console For security reasons the scpadmin password can be configured only when connected directly to the switch console To configure the password enter the following CLI command At factory default settings the current SCP administrator password is admin gt gt cfg sys sshd scpadm Changing SCP only Administrator password validation required Enter current administrator password lt password gt Enter new SCP only administrator password lt new password gt Re enter new SCP only administrator password lt new password gt New SCP only administrator password accepted 12 IMPORTANT The SCP only administrator password must be different from the regular administrator password Using SSH and SCP client commands The following shows the format for using some client commands The examples below use 205 178 15 157 as the IP address of a sample switch Logging in to the switch Enter the following command to
45. sits by idly until a failure calls it into action Service providers now demand that vendor equipment support redundant configurations where all devices can process traffic when they are healthy increasing site throughput and decreasing user response times when no device has failed The HP 10GbE switch high availability configurations are based on VRRP The switch software implementation of VRRP includes proprietary extensions The switch software implementation of VRRP supports the Active Active mode of high availability Active Active redundancy In an active active configuration shown in the following figure two switches provide redundancy for each other with both active at the same time Each switch processes traffic on a different subnet When a failure occurs the remaining switch can process traffic on all subnets The following figure shows an Active Active configuration example 175 High availability Figure 26 Active Active redundancy Active subnet A and C we Servers Internet Switch B Active subnet B and D HP 10GbE switch extensions to VRRP This section describes VRRP enhancements that are implemented in switch software Enterprise Routing Switch Tracking VRRP router priority The HP 10GbE switch software supports a tracking function that dynamically modifies the priority of a VRRP router based on its current state The objective of tracking is to have whenever possible the master biddin
46. switch blocks the IP Multicast stream from flowing through any port that does not connect to a host member thus conserving bandwidth The clientserver path is set up as follows e An IP Multicast Router Mrouter sends Membership Queries to the switch which forwards them to all ports in a given VLAN e Hosts that want to receive the multicast data stream send Membership Reports to the switch which sends a proxy Membership Report to the Mrouter e The switch sets up a path between the Mrouter and the host and blocks all other ports from receiving the multicast e Periodically the Mrouter sends Membership Queries to ensure that the host wants to continue receiving the multicast If the host fails to respond with a Membership Report the Mrouter stops sending the multicast to that path 118 IGMP Snooping e The host can send an IGMPv2 Leave report to the switch which sends a proxy Leave report to the Mrouter The multicast path is terminated immediately A maximum of 8 VLANs can be configured for IGMP Snooping The switch can learn up to 16 multicast routers and supports up to 1 000 multicast groups IGMPv3 IGMPv3 includes new membership report messages to extend IGMP functionality The switch provides snooping capability for all types of IGMP version 3 IGMPv3 Membership Reports as described in RFC 3376 IGMPv3 supports Source Specific Multicast SSM SSM identifies session traffic by both source and group addre
47. that connects to a server or stub network is called an edge port Therefore ports 1 16 should have edge enabled Edge ports can start forwarding as soon as the link is up Edge ports do not take part in Spanning Tree and should not receive BPDUs If a port with edge enabled does receive a BPDU it begins STP processing until it is re enabled Link type The link type determines how the port behaves in regard to Rapid Spanning Tree The link type corresponds to the duplex mode of the port A full duplex link is pointto point p2p while a half duplex link should be configured as shared If you select auto as the link type the port dynamically configures the link type RSTP configuration guidelines This section provides important information about configuring Rapid Spanning Tree Groups e When RSTP is turned on STP parameters apply only to STP Group I e When RSTP is turned on all VLANs from STP Groups other than STP Group 1 are moved to STP Group 1 The other STP Groups 2 128 are turned off RSTP configuration example This section provides steps to configure Rapid Spanning Tree on the switch using the Command Line Interface CLI or the Browser based Interface BBI Configuring Rapid Spanning Tree CLI example 1 Configure port and VLAN membership on the switch as described in the Configuring ports and VLANs CLI example section in the VLANs chapter of this guide 2 Set the Spanning Tree mode to Rapid Spanni
48. the MIBs mainly for security To access the SNMP v3 0 menu enter the following command in the CLI gt gt cfg sys ssnmp snmpv3 For more information on SNMP MIBs and the commands used to configure SNMP on the switch see the HP 10Gb Ethernet Bl c Switch Command Reference Guide Detault configuration The switch software has two users by default Both the users adminmd5 and adminsha have access to all the MIBs supported by the switch e username 1 adminmd5 password adminmds Authentication used is MD5 e username 2 adminsha password adminsha Authentication used is SHA e username 3 v1v2only password none To configure an SNMP user name enter the following command from the CLI gt gt cfg sys ssnmp snmpv3 usm 6 A Accessing the switch User configuration Users can be configured to use the authentication privacy options The HP 10GbE switch supports two authentication algorithms MD5 and SHA as specified in the following command cfg sys ssnmp snmpv3 usm lt x gt auth md5 sha 1 To configure a user with name admin authentication type MD5 authentication password of admin and privacy option DES with privacy password of admin use the following CLI commands gt gt cfg sys ssnmp snmpv3 usm 5 SNMPv3 SNMPv3 SNMPv3 SNMPv3 SNMPv3 gt gt gt gt gt gt gt gt gt gt usmUser usmUser usmUser usmUser usmUser name auth md5 authpw admin priv des pr
49. the necessary address information and sends the data back to the switch which then relays the packet to the proper destination subnet using Layer 2 switching With Layer 3 IP routing in place on the switch routing between different IP subnets can be accomplished entirely within the switch This leaves the routers free to handle inbound and outbound traffic for this group of subnets 108 Example of subnet routing Prior to configuring you must be connected to the switch Command Line Interface CLI as the administrator Basic IP routing NOTE For details about accessing and using any of the menu commands described in this example see the HP 10Gb Ethernet BL c Switch Command Reference 1 Assign an IP address or document the existing one for each router and client workstation 2 In the example topology the following IP addresses are used Table 20 Subnet routing example IP address assignments Subnet Devices IP Addresses 1 Primary and Secondary Default Routers 205 21 17 1 and 205 21 17 2 2 First Floor Client Workstations 100 20 10 2 254 3 Second Floor Client Workstations 131 15 15 2 254 4 Common Servers 206 30 15 2 254 3 Assign an IP interface for each subnet attached to the switch 4 Since there are four IP subnets connected to the switch four IP interfaces are needed Table 21 Subnet routing example IP interface assignments Interface Devices IP Interface Address IF 1 Primary and S
50. the router ID from static to dynamic set the router ID to 0 0 0 0 save the configuration and reboot the switch To view the router ID enter gt gt info 13 ospf gen 138 OSPF Authentication OSPF protocol exchanges can be authenticated so that only trusted routing devices can participate This ensures less processing on routing devices that are not listening to OSPF packets OSPF allows packet authentication and uses IP multicast when sending and receiving packets Routers participate in routing domains based on predefined passwords The switch software supports simple password type 1 plain text passwords and MD5 cryptographic authentication This type of authentication allows a password to be configured per area The following figure shows authentication configured for area 0 with the password test Simple authentication is also configured for the virtual link between area 2 and area 0 Area 1 is not configured for OSPF authentication Figure 20 OSPF authentication 7 Areal I Lio AO SG N 4 N Pid Simple authentication N I Application key test N switch 2 Vy IF 1 IE2 l gt gt TITT SPAR pp Je EA FABR Application Switch mme 7 Application x p3 switch 1 switch 5 lt a oe aA lt j I Area 2 IF5 irtual link ASBR to HP Blade Chassis N External Networks HP Blade Chassis To configure simple plain text OSPF passwords on the switches shown in the figure use the following commands
51. thresholds The Alarm group can be used to track rising or falling values for a MIB object The object must be a counter gauge integer or time interval Use the cfg rmon alarm x revtidx or fevtidx to correlate an alarm index to an event index When the alarm threshold is reached the corresponding event is triggered Alarm MIB objects The most common data types used for alarm monitoring are ifStats errors drops bad CRCs and so on These MIB Object Identifiers OIDs correlate to the ones tracked by the History group An example of an ICMP stat is as follows 1 3 6 1 2 1 5 1 0 mgmt icmp icmpInMsgs The last digit x represents the interface on which to monitor which corresponds to the interface number or port number as follows e 1 250 IF 1 250 e 251 port I e 252 port 2 e 271 port 21 This value represents the alarm s MIB OID as a string Note that for non tables you must supply a 0 to specify end node Configure RMON Alarms CLI example 1 1 Configure the RMON Alarm parameters to track the number of packets received on a port gt gt cfg rmon alarm 6 Select RMON Alarm 6 gt gt RMON Alarm 6 oid 1 3 6 1 2 1 2 2 1 10 270 gt gt RMON Alarm 6 intrval 3600 gt gt RMON Alarm 6 almtype rising gt gt RMON Alarm 6 rlimit 2000000000 gt gt RMON Alarm 6 revtidx 6 gt gt RMON Alarm 6 sample abs gt gt RMON Alarm 6 owner Alarm for ifInOctets 2 Apply and save
52. 0 ff Disabled 2p Prity None w Type of Service 0 255 0 Disabled Protocol 0 255 0 Disabled Source IP Address 0 0 0 0 Mask 255 255 255 255 Destination IP Address Mask 255 255 255 255 TCP UDP Sre Port 1 65535 1 Mask 0 f8 fff Disabled w TCP UDP Dst Port 1 65535 1 Mask 0 1 fff Disabled v Fin syn Jrst IPSH ACK URG Mask 0 3 3f Disabled v Statistics Disabled Egress port None Mi d Click Submit 2 Apply verity and save the configuration O i CONFIGURE STATISTICS DASHBOARD TCP Flags invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save 94 Quality of Service 3 Add ACL 1 to port 1 a Click the Configure context button on the Toolbar b Select Switch Ports click the underlined text not the folder Open 53 HP 1 10Gb Ethernet Blade Switch S System Select Switch Ports Port Based Port Mirroring Ga RMON Menu os i Access Control Uplink Failure Detection c Select a port Select ma Eu R EN jail 95 Quality of Service d Add the ACL to the port Switch Port 1 Configuration Switch Port State Enabled ACL Configuration ACLs Available ACLs Selected ACLID ACLID 25 J ACL Groups Available ACL Groups Selected ACL Group ID ACL Group ID
53. 1 Configure a port s default 802 1 priority 2 Map gt gt Main cfg port 20 Select port gt gt Port 20 8021ppri Set port s default 802 1p priority Current 802 1p priority 0 Enter new 802 1p priority 0 7 1 gt gt Port 20 apply the 802 1p priority value to a COS queue and set the COS queue scheduling weight gt gt Main cfg qos 8021p Select 802 1p menu gt gt 802 1p priq Set COS queue assignments Enter priority 0 7 1 Current COS queue for priority 1 0 Enter new COS queue for priority 1 0 1 1 gt gt 802 1p qweight Set COS queue weights Enter COS queue 0 2 1 Current weight for COS queue 1 0 Enter new weight for COS queue 1 0 15 1 gt gt 802 1p apply 802 1p configuration BBI example 1 Configure a port s default 802 1p priority a Click the Configure context button on the Toolbar b Select Switch Ports click the underlined text not the folder Open 3 HP 10Gb Ethernet BL c Switch System Select Switch Ports Port Based Port Mirroring Layer 2 RMON Menu Layer 3 QoS Access Control Uplink Failure Detection 100 Quality of Service c Select a port 101 Quality of Service Set the 802 1p priority value Enabled Disabled Disabled Enabled j a y 2 x i nabled ownlink1 Disabled Off v Disabled Disabled
54. 12 Using the Browser based Interface ccccsccesesseeeesseceeeceeeneeceeeecseeeecenseeeeeeceeeeentaeeseeeesieeesnuaeeenateeeeneeeenes 13 Using Simple Network Management Protocol cccceceseseeseneeeesereeeeeeeceeeeesneeecneeeceeeessuseesnseeeneeeeneeeeeeas 14 DMI 14 SPM 14 LE ee 0 as VL se RE ERE aeaee E SEn ae Erena RES 14 User configurati oi enesesse nS enee RE eere na Er NAS EEA A E eE 15 View based configurations s lt c 05q2ipisaacssnonaayadosinateedsnboneheadtasodeesdeolahiaisosyssoiSlgiayavoesoeselaniatsonionieelaants 16 Ciltuser CQUIVOIENE secarse i nR NEN EOR EE E EEE E ESI EEE 16 CLI oper equivalent cccccccccesesescecesseeecceseseeeceseseeeeseeeeeseessaeeeceeaeeseeeseeeecesaaeessesuaeesceseaeeeeeeenes 17 Configuring SNMP trap hosts zc1sqs sasescomaegdeagaiteonennnygettaanituencensspghtigeitasmceseqqntani tacacecrdhgeltensaaeasnaiianns 17 SNMP GS cis2 2 ices cscasaseetestecge E d a N a aE SE 17 SNMPv2 trap host configuration 3 vesesmerieeqnvicareruvesnabeyawetsensaretangsanestseatecaayrpeiamas aiecedydosanas tucteurseatinanse 19 SNMPv3 trap host configuration s2nc2cnss3 orev uevecesmsanagedovanyaceuna prducduviayabaxtaontedeladetedaontendeoetateecenmiyleane 19 Secure dceess 16 EEE NN 20 Setting allowable source IP address ranges si isi 0ssaesssnveixiacerssoevsnvdvasensorssoesbnodeasetsvantedeuvaaqannnsbanldeeeraaaek 20 Configuring an IP address range for the management network s ss ssssesrserseierseerstrsrrreresrrsrrsrr
55. 17 RIP features 115 RMON remote monitoring 155 RMON groups alarms 161 events 165 examples of 156 159 160 161 162 164 165 166 170 history 158 statistics 155 Router ID OSPF router ID 138 routers 107 109 border peer autonomous systems AS 134 switch based routing topology 108 routing internal and external internal routing 134 RSA keys 33 RSTP 77 S security 20 RADIUS authentication 21 switch management 20 VLANs 53 segmentation 53 HP OpenView HP OpenView 14 SNMP 14 SNMP 134 SNMP v1 0 14 SNMP v3 0 14 Spanning Tree Protocol STP multiple instances 72 spanning tree configuration rules 38 SSH RSA host and server keys 33 supported clients 31 SSH SCP configuring 31 Static MRouter configuring CLI example 122 Static Multicast Router configuring BBI example 129 statistics 195 switch management security 20 via IP interface 58 switch ports VLANs membership 54 syslog messages 195 Index T tagging 55 technical terms port VLAN identifier PVID 55 tagged frame 55 tagged member 55 untagged frame 55 untagged member 55 VLAN identifier VID 55 Telnet 11 trace route 195 Trunk Hash algorithm 44 trunking configuration rules 38 typographical conventions 10 V VLANs broadcast domains 53 58 110 configuration rules 38 default PVID 54 example showing multiple VLANs 60 ID numbers 53 IP inter
56. 24 name oper tree 1 3 6 1 4 1 11 2 3 7 11 33 1 2 3 statistics c sys ssnmp snmpv3 view 25 name oper tree 1 3 6 1 4 1 11 2 3 7 4 f een 3s information Configuring SNMP trap hosts SNMPv1 trap host 1 Configure a user with no authentication or password c sys ssnmp snmpv3 usm 10 Configure user named vitrap name vitrap 2 Configure an access group and group table entries for the user Use the following command to specify which traps can be received by the user c sys ssnmp snmpv3 access lt x gt nview c sys ssnmp snmpv3 access 10 Define access group to view SNMPv1 traps name vitrap model snmpv1 nview iso c sys ssnmp snmpv3 group 10 Assign user to the access group model snmpv1 uname vitrap gname vitrap In this example the user will receive the traps sent by the switch 17 Accessing the switch 3 Configure an entry in the notify table c sys ssnmp snmpv3 notify 10 Assign user to the notify table name vitrap tag vitrap 4 Specify the IP address and other trap parameters in the Target Address targetAddr and Target Parameters targetParam tables Use the following command to specify the user name used with this targetParam table c sys ssnmp snmpv3 tparam lt x gt uname c sys ssnmp snmpv3 taddr 10 Define an IP address to send traps name vitrap addr 47 80 23 245 taglist vitrap pname viparam c sys ssnmp snmpv3 tparam 10 Specify SNMPv1 traps to send name vi
57. 6 CS6 48 CS5 40 CS4 32 CS3 24 CS2 16 CS 8 Lowest CSO 0 QoS levels The following table shows the default service levels provided by the switch listed from highest to lowest importance Table 19 Default QoS service levels Service Level Default PHB 802 1p Priority Critical CS7 7 Network Control CS6 6 Premium EF CS5 5 Platinum AF41 AF42 AF43 CS4 4 Gold AF31 AF32 AF33 CS3 3 Silver AF21 AF22 AF23 CS2 2 Bronze AF11 AF12 AF13 CS1 1 Using 802 1p priorities to provide QoS The HP 10GbE switch software provides Quality of Service functions based on the priority bits in a packet s VLAN header The priority bits are defined by the 802 1p standard within the IEEE 802 1q VLAN header The 802 1p bits if present in the packet specify the priority given to packets during forwarding Packets with a numerically higher non zero priority are given forwarding preference over packets with lower priority Packets with a priority mapped to a higher Class of Service COS and COS queue COSq weight are given forwarding preference over packets with priority mapped to a lower COS and COSq weight The scheduling scheme is Weight Round Robin WRR with user configurable weight from O to 15 for a COSq The switch can be configured with either two or eight output Class of Service queues COSq 98 Quality of Service The IEEE 802 1p standard uses eight levels of priority 0 7 Priority 7 is assigned to hi
58. A DA C gt 802 1Q Switch s Porte Port7 Ports Untagged member of VLAN 2 BS45011A As shown in the following figure the untagged packet is marked tagged as it leaves the switch through port 5 which is configured as a tagged member of VLAN 2 The untagged packet remains unchanged as it leaves the switch through port 7 which is configured as an untagged member of VLAN 2 56 VLANs Figure 5 802 1Q tagging after portbased VLAN assignment Tagged member ANLAN 2 CRC Data Tag SA DA E eros hu of VLAN 2 16 bits 3 bits 1 bits 12 bits at After Outgoing untagged packet pa Key unchanged Priority User_priority CFI Canonical format indicator VID VLAN identifier BS45012A PVID 2 802 1Q Switch In the following figure the tagged incoming packet is assigned directly to VLAN 2 because of the tag assignment in the packet Port 5 is configured as a tagged member of VLAN 2 and port 7 is configured as an untagged member of VLAN 2 Figure 6 802 1Q tag assignment PVID 2 Tagged member Tagged packet Ne P of VLAN 2 Before Untagged member of VLAN 2 BS45013A As shown in the following figure the tagged packet remains unchanged as it leaves the switch through port 5 which is configured as a tagged member of VLAN 2 However the tagged packet is stripped untagged as it leaves the switch through port 7 which is configured as a
59. ACL Group 1 to a port then add ACL Group 2 to the port the port s ACL filters contain a total of six precedence levels ACL Group 1 has precedence over ACL Group 2 Each port supports up to seven precedence levels Actions taken by an ACL are called In Profile actions You can configure additional In Profile and Out of Profile actions on a port Data traffic can be metered and re marked to ensure that the traffic flow provides certain levels of service in terms of bandwidth for different types of network traffic Metering QoS metering provides different levels of service to data streams through user configurable parameters A meter is used to measure the traffic stream against a traffic profile which you create Thus creating meters yields In Profile and Out of Profile traffic for each ACL as follows e InProfile lf there is no meter configured or if the packet conforms to the meter the packet is classified as In Profile e Out of Profile lf a meter is configured and the packet does not conform to the meter exceeds the committed rate or maximum burst rate of the meter the packet is classified as Out of Profile Using meters you set a Committed Rate in Kb s 1024 bits per second in each Kb s All traffic within this Committed Rate is In Profile Additionally you set a Maximum Burst Size that specifies an allowed data burst larger than the Committed Rate for a brief period These parameters define the In Profile traffic
60. ANs exist beyond the default VLAN 1 see the Creating a VLAN section in this chapter for information on adding ports to VLANs Add the VLAN to the STG using the command cfg 12 stp lt stg number gt add lt vlan number gt Creating a VLAN When you create a VLAN then that VLAN automatically belongs to STG 1 the default STG If you want the VLAN in another STG you must move the VLAN by assigning it to another STG To move a newly created VLAN to an existing STG 1 Create the VLAN 2 Add the VLAN to an existing STG When creating a VLAN also consider the following e AVIAN cannot belong to more than one STG e VLANs that span multiple switches must be mapped within the same Spanning Tree Group have the same STG ID across all the switches Rules for VLAN tagged ports Rules for VLAN tagged ports are listed below e Ifa port is tagged it can belong to multiple STGs e When a tagged port belongs to more than one STG the egress BPDUs are tagged to distinguish the BPDUs of one STG from those of another STG e An untagged port cannot span multiple STGs Adding and removing ports from STGs Information on adding and removing ports from STGs is as follows e By default all ports belong to VLAN 1 and STG 1 e Each port is always a member of at least one VLAN Each VLAN is always a member of at least one STG Port membership within VLANs can be changed and VLAN membership within STGs can be changed To move a port fro
61. BPDU it will replace its BPDU with the received BPDU Then the application switch adds its own bridge ID number and increments the path cost of the BPDU The application switch uses this information to block any redundant paths 68 Spanning Tree Protocol Determining the path for forwarding BPDUs When determining which port to use for forwarding and which port to block the switch uses information in the BPDU including each bridge priority ID A technique based on the lowest root cost is then computed to determine the most efficient path for forwarding Bridge priority The bridge priority parameter controls which bridge on the network is the STP root bridge To make one switch the root bridge configure the bridge priority lower than all other switches and bridges on your network The lower the value the higher the bridge priority The bridge priority is configured using the following command cfg 12 stp x brg prior Port priority The port priority helps determine which bridge port becomes the designated port In a network topology that has multiple bridge ports connected to a single segment the port with the lowest port priority becomes the designated port for the segment The port priority is configured using the following command cfg 12 stp y port x prior Port path cost The port path cost assigns lower values to high bandwidth ports such as Gigabit Ethernet to encourage their use The objective is to use the fastest l
62. CP IP route information with other routers Distance vector protocol RIP is known as a distance vector protocol The vector is the network number and next hop and the distance is the cost associated with the network number RIP identifies network reachability based on cost and cost is defined as hop count One hop is considered to be the distance from one switch to the next which is typically 1 This cost or hop count is known as the metric When a switch receives a routing update that contains a new or changed destination network entry the switch adds 1 to the metric value indicated in the update and enters the network in the routing table The IP address of the sender is used as the next hop Stability RIP includes a number of other stability features that are common to many routing protocols For example RIP implements the split horizon and hold down mechanisms to prevent incorrect routing information from being propagated RIP prevents routing loops from continuing indefinitely by implementing a limit on the number of hops allowed in a path from the source to a destination The maximum number of hops in a path is 15 The network destination network is considered unreachable if increasing the metric value by 1 causes the metric to be 16 that is infinity This limits the maximum diameter of a RIP network to less than 16 hops RIP is often used in stub networks and in small autonomous systems that do not have many redundant paths Ro
63. CP port 21 save Save for restore after reboot 46 Port based Network Access and traffic control Port based Network Access control Port based Network Access control provides a means of authenticating and authorizing devices attached to a LAN port that has point to point connection characteristics It prevents access to ports that fail authentication and authorization This feature provides security to all ports of the HP 10GbE switch except the management port 17 The following topics are discussed in this section e Extensible Authentication Protocol over LAN e 802 1x Authentication Process e 802 1x Port States e Supported RADIUS Attributes e Configuration Guidelines Extensible authentication protocol over LAN HP 10GbE switch software can provide user level security for its ports using the IEEE 802 1x protocol which is a more secure alternative to other methods of port based network access control Any device attached to an 802 1x enabled port that fails authentication is prevented access to the network and denied services offered through that port The 802 1x standard describes port based network access control using Extensible Authentication Protocol over LAN EAPol EAPoL provides a means of authenticating and authorizing devices attached to a LAN port that has point to point connection characteristics and of preventing access to that port in cases of authentication and authorization failures EAPol is a cl
64. Configure MD5 key for the virtual link between Area 2 and Area 0 on switches 2 and 4 gt gt cfg 13 ospf md5key 2 key packard 6 Assign MD5 key ID to OSPF virtual link on switches 2 and 4 gt gt cfg 13 ospf virt 1 mdkey 2 PwWePDN PB 1 2 1 3 Host routes for load balancing The HP 10GbE switch implementation of OSPF includes host routes Host routes are used for advertising network device IP addresses to external networks accomplishing the following goals e ABR Load Sharing As a form of load balancing host routes can be used for dividing OSPF traffic among multiple ABRs To accomplish this each switch provides identical services but advertises a host route for a different IP address to the external network If each IP address serves a different and equal portion of the external world incoming traffic from the upstream router should be split evenly among ABRs e ABR Failover Complementing ABR load sharing identical host routes can be configured on each ABR These host routes can be given different costs so that a different ABR is selected as the preferred route for each server and the others are available as backups for failover purposes e Equal Cost Multipath ECMP With equal cost multipath a router potentially has several available next hops towards any given destination ECMP allows separate routes to be calculated for each IP Type of Service All paths of equal cost to
65. Downlink1 1 N Downlink12 36 Port Ports and trunking Table 7 Ethernet switch port names Port number Port alias 13 Downlink13 14 Downlink14 15 Downlink15 16 Downlink16 17 Mgmt 18 Uplink 19 Uplink2 20 Uplink3 21 Uplink4 trunk groups When using port trunk groups between two switches you can create an aggregate link operating at up to forty Gigabits per second depending on how many physical ports are combined The switch supports up to 12 trunk groups per switch each with up to six ports per trunk group The trunking software detects broken trunk links link down or disabled and redirects traffic to other trunk members within that trunk group You can only use trunking if each link has the same configuration for speed flow control and auto negotiation Statistical load distribution In a configured trunk group containing more than one port the load distribution is determined by information embedded within the data frame For IP traffic the switch will calculate the trunk port to use for forwarding traffic by implementing the load distribution algorithm on value equals to modulus of XOR of last 3 bits of Source and last 3 bits of Destination IP address For non IP traffic the switch will calculate the trunk port to use for forwarding traffic by implementing the load distribution algorithm on value equals to modulus of XOR of last 3 bits of Source and last 3 bits of Destination MAC
66. HP 10Gb Ethernet BLc Switch Application Guide OD Part number 445946 001 First edition June 2007 Legal notices 2007 Hewlett Packard Development Company L P The information contained herein is subject to change without notice The only warranties for HP products and services are set forth in the express warranty statements accompanying such products and services Nothing herein should be construed as constituting an additional warranty HP shall not be liable for technical or editorial errors or omissions contained herein Microsoft Windows and Windows NT are U S registered trademarks of Microsoft Corporation SunOS and Solaris are trademarks of Sun Microsystems Inc in the U S and other countries Cisco is a registered trademark of Cisco Systems Inc and or its affiliates in the U S and certain other countries Contents Contents Accessing the switch Introductio NsiI a acid cena gaa EEE neil 9 Additional referentes ERE RE MR cea aI nee ene 10 Typographical conventions Ja eresersaroa Gre NO NE 10 MaoseretNbLvv4v44r ee 10 Connecting through the console p ser 11 Connecting through Nine vav4vv44s are auseanen ean 11 Connecting through Secure Silat cnceescctstaes semen ees eee Minin e eae em ES 11 Using the commornd line interfaces 1 455 cet csaseeceeearseeratoereerenmmeiahace nea eeersa eee 12 Configuring an Pessoa stnaesaaieschedns scedeiagisscheansstadviasnesthapsaadedeesiesthantiasdeadiesshassieeananss
67. Instrumentation VLAN Tagging PVID Tagging Port STP Enabled vi Enabled v Enabled Y Default Port VLAN ID 1 4095 Flow Control both Rx Tx 3 Autonegotiation Off Speed 10000 Duplex Mode Full Enable Disable sending Link UP Down Trap Enabled v Port Name Uplink3 4 Click Submit 5 Apply verify and save the configuration O invent CONFIGURE STATISTICS DASHBOARD Apply Save Revert Diff Dump 1 Apply 3 Save 2 Verify RMON group 2 history The RMON History group allows you to sample and archive Ethernet statistics for a specific interface during a specific time interval NOTE RMON port statistics must be enabled for the port before an RMON history group can monitor the port Data is stored in buckets which store data gathered during discreet sampling intervals At each configured interval the history instance takes a sample of the current Ethernet statistics and places them into a bucket History data buckets reside in dynamic memory When the switch is re booted the buckets are emptied 158 Requested buckets cfg rmon hist x rbnum are the number of buckets or data slots requested by Remote monitoring the user for each History Group Granted buckets info rmon hist x gbnum are the number of buckets granted by the system based on the amount of system memory available The system grants a maximum of 50 buckets Use an SNMP browser to view Histor
68. MAC address 12 meter 91 mirroring ports 191 monitoring ports 191 MSTP 77 multi links between switches using port trunking 36 multiple spanning tree groups 71 N network management 14 O Open Shortest Path First OSPF 131 ICMP IGMP TCP UDP filtering criteria 87 OSPF overview 131 OSPF area types 131 OSPF neighbors 133 OSPF link state database 133 OSPF route summarization 137 OSPF default route OSPF 137 OSPF virtual link 138 OSPF authentication 139 OSPF host routes OSPF 140 OSPF external routes 141 OSPF configuration examples 141 142 150 151 152 OSPF configuration verifying 154 P ping 195 Port Fast Forwarding 76 port mirroring configuration rules 38 troubleshooting 191 port trunking 37 port trunking fault tolerance 37 Port based Network Access control 47 Port based traffic control 51 ports monitoring 191 physical 54 priority value 802 1p 98 PVID port VLAN ID 54 197 Q Quality of Service 86 queuing and scheduling 105 R RADIUS port 1812 and 1645 88 port 1813 88 redundancy active active 175 VRRP Virtual Router Redundancy Protocol 175 re mark 91 Remote Authentication Dial in User Service RADIUS authentication 21 SSH SCP 34 Remote monitoring RMON 155 RIP Routing Information Protocol advertisements 114 distance vector protocol 114 hop count 114 metric 114 RIP configuration example 1
69. Management Protocol The switch software provides SNMP v1 0 and SNMP v3 0 support for access through any network management software such as HP OpenView SNMP v1 0 To access the SNMP agent on the switch the read and write community strings on the SNMP manager should be configured to match those on the switch The default read community string on the switch is public and the default write community string is private The read and write community strings on the switch can be changed using the following commands on the CLI gt gt cfg sys ssnmp rcomm and gt gt cfg sys ssnmp wcomm The SNMP manager should be able to reach the management interface or any one of the IP interfaces on the switch For the SNMP manager to receive the traps sent out by the SNMP agent on the switch the trap host on the switch should be configured with the following command cfg sys ssnmp snmpv3 taddr For more details see Configuring SNMP trap hosts SNMP v3 0 SNMPv3 is an enhanced version of the Simple Network Management Protocol approved by the Internet Engineering Steering Group in March 2002 SNMP v3 0 contains additional security and authentication features that provide data origin authentication data integrity checks timeliness indicators and encryption to protect against threats such as masquerade modification of information message stream modification and disclosure SNMP v3 ensures that the client can use SNMP v3 to query
70. N 10 gt gt VLAN 10 gt gt Layer 2 vlan 20 Select VLAN 20 gt gt VLAN 20 ena Enable VLAN 20 gt gt VLAN 20 add 21 Add port 21 to VLAN 20 178 High availability 2 Configure client and server interfaces cfg 13 if 1 gt gt IP Interface 1 addr 192 168 1 100 gt gt IP Interface 1 vlan 10 gt gt IP Interface 1 ena gt gt IP Interface 1 gt gt Layer 3 if 2 gt gt IP Interface 2 addr 192 168 2 101 gt gt IP Interface 1 vlan 20 gt gt IP Interface 2 ena gt gt IP Interface 2 gt gt Layer 3 if 3 gt gt IP Interface 3 addr 10 0 1 100 gt gt IP Interface 3 mask 255 255 255 0 gt gt IP Interface 3 ena gt gt IP Interface 2 Select interface 1 Define IP address for interface 1 Assign VLAN 10 to interface 1 Enable interface 1 Select interface 2 Define IP address for interface 2 Assign VLAN 20 to interface 2 Enable interface 2 Select interface 3 Define IP address for interface 3 Define subnet mask for interface 3 Enable interface 3 gt gt Layer 3 if 4 Select interface 4 gt gt IP Interface 4 addr 10 0 2 101 Define IP address for interface 4 gt gt IP Interface 4 mask 255 255 255 0 Define subnet mask for interface 4 gt gt IP Interface 4 ena Enable interface 4 3 Configure the default gateways Each default gateway points to one of the Layer 2 routers cfg 13 gw 1 Select default gateway 1
71. N is down and if the IP interface of a VIR is down that VIR goes into INIT state VRRP operation Only the virtual router master responds to ARP requests Therefore the upstream routers only forward packets destined to the master The master also responds to ICMP ping requests The backup does not forward any traffic nor does it respond to ARP requests If the master is not available the backup becomes the master and takes over responsibility for packet forwarding and responding to ARP requests Selecting the master VRRP router Each VRRP router is configured with a priority between 1 and 254 A bidding process determines which VRRP router is or becomes the master the VRRP router with the highest priority The master periodically sends advertisements to an IP multicast address As long as the backups receive these advertisements they remain in the backup state If a backup does not receive an advertisement for three advertisement intervals it initiates a bidding process to determine which VRRP router has the highest priority and takes over as master If at any time a backup determines that it has higher priority than the current master does it can preempt the master and become the master itself unless configured not to do so In preemption the backup assumes the role of master and begins to send its own advertisements The current master sees that the backup has higher priority and will stop functioning as the master 174 High
72. OSPF OSPPOVEIVIGW EN ENE EE OAE AR RES 131 Types Of OSPF Cred ES 131 Types of OSPF routing devices cccccceesseeseseeceneecensceeseaeeceeeceneeecseaeeceeeesneeeeeeaeeseeeeesueeeeeeeseneeeeeas 132 Neighbors and adjacencies ah 1h sahesiaaisachsaderabesia ciasvawscianes ta sivavatsseiahdoaustAashieiahtoausdeb aaa enniees 133 LAS TNS Ae ER ES EE 133 Shortest Path First rises RON ERR EN OE 133 Internal versus external routing rarsrvrrnnvrnrrrvnnrrrnrnrrvnnnrrnnnrrnnnrrrnnnnrrnnnrrsnnrernnnnennnrssnnrrsnnnnrnnnnnrsnnnenn 134 OSPF implementation in HP TOGbE switch software rrrerrrrrrrrrvvrrerrerrnrerrernnrererrrrnrersernnrersernrnsrsrennnsereen 134 Configurable parameters Luu0ybuuqoesmeguerumsagenurgteke dokk vaner nt 134 TIA EEE neaemmmaneteien 135 Assigning the area index EN 135 Using the area ID to assign the OSPF area number ccccceseseeeeseeceeeeeesereeceaeeeeneeeeneseeenseeesnneeenes 136 Attaching an area to a network Lasser made nserkendss det 136 gg 0 REE NE EE E R A EE 136 Electing the designated router and backup vsssccssussascaseisaacecuatonpe leas aaccsanioe eeuaaetenesaspeieenaneteaaenrs eee 137 S mMMaArZIN TOUTES EEE EE EE de bebenauanceandadetennddsinengaanensy 137 BEE gt FER A E E E E RR 137 Virt al RER RE T E ES 138 Router DE EET ME 138 FA 139 Kle for load OIG III RER e E E a SURS 140 OSPF features not supported in this release cccccccessssceceessececcseecesceseceecesseeecescnseesescnseeeeceeee
73. OSPF Hosts OSPF Route Redistribution Select b Enable OSPF 144 OSPF c Click Submit 4 Configure OSPF Areas a Open the OSPF Areas folder and select Add OSPF Area Open HP 10Gb Ethernet BL c Switch S System i Switch Ports fa Port Based Port Mirroring Ga Layer 2 RMON Menu Layer 3 fa IP Interfaces Network Routes fa Network Filters Default Gateways Ga IGMP 5 OSPF Routing Protocol p OSPF Areas Select r d Add OSPF Area OSPF Summary Ranges OSPF Interfaces OSPF Virtual Links OSPF Hosts E OSPF Route Redistribution E General b Configure the OSPF backbone area 0 145 c Click Submit d Select Add OSPF Area e Configure the OSPF area f Click Submit em OSPF 146 OSPF 5 Configure OSPF Interfaces a Open the OSPF Interfaces folder and select Add OSPF Interface Open HP 10Gb Ethernet BL c Switch E System Switch Ports Port Based Port Mirroring Layer2 E RMON Menu lt 3 Layer 3 IP Interfaces Network Routes ARP I Network Filters Route Maps Default Gateways E IGMP 3 OSPF Routing Protocol OSPF Areas OSPF Summary Ranges 3 OSPF Interfaces Select Add Add OSPF Interface OSPF Virtual Links OSPF Hosts E OSPF Route Redistribution E General 147 OSPF Configure the OSPF Interface 1 and attach
74. P Interface gt gt IP Interface NNNHP HP HP p 3 t HEHEHE E gt gt IP Interface gt gt IP Interface 2 cfg 13 ospf on Enable OSPF on the switch 4 Define the backbone 5 The backbone is always configured as a transit area using areaid 0 0 0 0 6 Define the stub area 7 Attach the network interface to the backbone 8 Attach the network interface to the stub area 9 Appl gt gt Open Shortest Path First aindex 0 Select menu for area index 0 gt gt OSPF Area index 0 areaid 0 0 0 0 Set the ID for backbone area 0 gt gt OSPF Area index 0 type transit Define backbone as transit type gt gt OSPF Area index 0 enable Enable the area gt gt OSPF Area index gt gt OSPF Area index gt gt OSPF Area index gt gt OSPF Area index aindex 1 Select menu for area index 1 areaid 0 0 0 1 Set the area ID for OSPF area 1 type stub Define area as stub type OE OH PERO enable Enable the area gt gt OSPF Area 1 if 1 Select OSPF menu for IP interface 1 gt gt OSPF Interface 1 aindex 0 Attach network to backbone index gt gt OSPF Interface 1 enable Enable the backbone interface gt gt OSPF Interface 1 if 2 Select OSPF menu for IP interface 2 gt gt OSPF Interface 2 aindex 1 Attach network to stub area index gt gt OSPF Interface 2 enable Enable the stub area interface and save the confi
75. Ports Port Based Port Mirroring i Layer 2 E RMON Menu i Layer 3 G IP Interfaces EG Network Routes GM Network Filters Route Maps Default Gateways Select Add Add Default Gateway b Configure the IP address for each default gateway Enable the default gateways seas OOOO O fen c Click Submit 184 High availability 4 Turn on VRRP and configure two Virtual Interface routers a Open the Virtual Router Redundancy Protocol folder and select General HP 10Gb Ethernet BL c Switch E System Switch Ports Port Based Port Mirroring GI Layer 2 E RMON Menu Open Layer 3 IP Interfaces gt E Network Routes E Network Filters E Route Maps Default Gateways IGMP E OSPF Routing Protocol E Routing Information Protocol Virtual Router Redundancy Protocol gt E Virtual Routers VRRP Interfaces Select E General 185 High availability b Enable VRRP processing c Click Submit d Open the Virtual Routers folder and select Add Virtual Router i amp Virtual Router Redundancy Protocol Open ss Virtual Routers Select Add Virtual Router a VRRP Interfaces E General 186 High availability e Configure the IP address for Virtual Router 1 VR1 Enable tracking on ports and set the priority to 101 Enable The Virtual Router f Click Submit g Select Add Virtual Router IF Virt
76. Protocol trunk The switch monitors the LtM for link failure e Link to Disable LtD The Link to Disable group consists of one or more downlink ports 1 16 and trunk groups that contain only downlink ports The trunk groups can be Link Aggregation Control Protocol trunks When the switch detects a link failure on the LIM it automatically disables all ports in the LID When the LtM returns to service the switch automatically enables all ports in the LtD Spanning Tree Protocol with UFD If Spanning Tree Protocol STP is enabled on ports in the LIM then the switch monitors the STP state and the link status on ports in the LIM The switch automatically disables the ports in the LID when it detects a link failure or STP Blocking state When the switch determines that ports in the LIM are in STP Forwarding State then it automatically enables the ports in the LtD to fall back to normal operation 168 High availability Configuration guidelines This section provides important information about configuring UFD e UFD is required only when uplink path redundancy is not available on the blade switches e Only one Failure Detection pair one group of Links to Monitor and one group of Links to Disable is supported on each switch all VLANs and Spanning Tree Groups e An LiM can be either one uplink port or one Multi Link trunk group of uplink ports e Ports that are already members of a trunk group are not allowed to be
77. VRRP Virtual Router 1 gt gt V gt gt VRRP Virtual Router 2 gt gt VRRP Virtual Router 2 gt gt VRRP Virtual Router 2 gt gt VRRP Virtual Router 2 vrid 1 if 1 addr 192 168 1 200 ena irtual Router Redundancy Protocol vr 2 vrid 2 if 2 addr 192 168 2 200 ena Turn VRRP on Select virtual router Set VRID to 1 Set interface 1 IP address virtual router Define Enable Enable Select virtual router Set VRID to 2 Set interface 2 virtual router Define IP address Enable virtual router 180 High availability 5 Enable tracking on ports Set the priority of Virtual Router 2 to 101 so that it becomes the Master cfg 13 vrrp vr 1 Select VRRP virtual router 1 gt gt VRRP Virtual Router 1 track ports ena Set tracking on ports gt gt VRRP Virtual Router 1 Priority Tracking gt gt VRRP Virtual Router 1 gt gt Virtual Router Redundancy Protocol vr 2 Select VRRP virtual router 2 gt gt VRRP Virtual Router 2 track ports ena Set tracking on ports gt gt VRRP Virtual Router 2 Priority Tracking gt gt VRRP Virtual Router 2 prio 101 Set the VRRP priority 6 Turn off Spanning Tree Protocol globally Apply and save changes cfg 12 stg 1 0ff Turn off STG gt gt Spanning Tree Group 1 apply gt gt Spanning Tree Group 1 save Task 1 Configure Switch A BBI example 1 Configure ports and VLANs a Click the Configure context bu
78. When VLANs are removed from STG 1 128 the VLANs automatically become members of the CIST CIST port configuration includes Hello time Edge port status enable disable and Link Type These parameters do not affect Spanning Tree Groups 1 128 They apply only when the CIST is used 80 RSTP and MSTP MSTP configuration guidelines This section provides important information about configuring Multiple Spanning Tree Groups When you turn on MSTP the switch automatically moves VLAN 1 to the Common Internal Spanning Tree CIST Region Name and revision level must be configured Each bridge in the region must have the same name and revision level The VLAN and STP Group mapping must be the same across all bridges in the region You can move any VLAN to the CIST You can move VLAN 1 into any Spanning Tree Group MSTP configuration example This section provides steps to configure Multiple Spanning Tree Protocol on the switch using the Command Line Interface CLI or the Browser based Interface BBI Configuring Multiple Spanning Tree Protocol CLI example 1 Configure port and VLAN membership on the switch as described in the Configuring ports and VLANs CLI example section in the VLANs chapter of this guide 2 Set the mode to Multiple Spanning Tree and configure MSTP region parameters 3 Assign VLANs to Spanning Tree Groups gt gt cfg 12 mrst Select Multiple Spanning Tree menu gt gt Multiple Spa
79. a into one of the 30 requested buckets After 30 samples are gathered the new samples overwrite the previous samples beginning with the first bucket Use SNMP to view the data 159 Remote monitoring Configure RMON History BBI example 1 Configure an RMON History group a Click the Configure context button b Open the Switch folder and select RMON gt History gt Add History Group Open HP 10Gb Ethernet BL c Switch System 9 Switch Ports E Port Based Port Mirroring GA Layer2 3 RMON Menu TG History Select dd Add History Group gg Event E Layer 3 Ga avs Access Control Uplink Failure Detection 2 Configure RMON History Group parameters mass O Ps O O OO OOO O O Number of Buckets Requested 1 65535 30 EJ OmerHsioyt Submit Delete 3 Click Submit 4 Apply verify and save the configuration DD STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save 160 Remote monitoring RMON group 3 alarms The RMON Alarm group allows you to define a set of thresholds used to determine network performance When a configured threshold is crossed an alarm is generated For example you can configure the switch to issue an alarm if more than 1 000 CRC errors occur during a 10 minute time interval Each Alarm index consists of a variable to monitor a sampling time interval and parameters for rising and falling
80. agged ports that belong to multiple VLANs are removed from the deleted VLAN only 59 VLANs Multiple VLANS with tagging The following figure shows only those switch portto server links that must be configured for the example While not shown all other server links remain set at their default settings Figure 8 Multiple VLANs with VLAN tagging PC 1 PC 2 PC 3 PC 4 PC 5 VLANs 2 amp 3 VLAN 4 VLANs 1 amp 2 VLAN 3 VLANs 1 amp 2 10Gb tagged adapter i 18 19 20 21 21 20 1918 T U U T Switch 1 Switch 2 Enclosure Centerwall Legend VLAN 1 VLAN 2 VLAN 3 T Tagged Port u Untagged Port External Layer 2 Switch Spanning Tree is Disabled in this example The features of this VLAN are described in the following table Table 10 Multiple VLANs with tagging Component Description Switch 1 Switch 1 is configured for VLANS 1 2 and 3 Port 1 is tagged to accept traffic from VLANs 1 and 2 Port 18 is tagged to accept traffic from VLANs 1 2 and 3 Port 20 is an untagged member of VLAN 2 Port 21 is tagged and accepts traffic from VLANs 1 and 3 Switch 2 Switch 2 is configured for VLANS 1 3 and 4 Port 2 is tagged to accept traffic from VLANS 3 and 4 Port 4 is configured only for VLAN 3 so VLAN tagging is off Port 18 is tagged to accept traffic from VLANs 1 and 3 Port 20 is an untagged member of VLAN 4 Port 21 is tagged and accepts traffic from VLANs 1 and 3
81. and VLAN membership on Switch 1 as described in the Configuring ports and VLANs on Switch 1 CLI example section in the VLANs chapter of this guide Add VLAN 2 to Spanning Tree Group 2 gt gt cfg l2 stp 2 Select Spanning Tree Group 2 gt gt Spanning Tree Group 2 add 2 Add VLAN 2 VLAN 2 is removed from Spanning Tree Group 1 Apply and save gt gt apply Apply the port configurations gt gt save Save the port configurations Configuring Switch 2 CLI example 1 2 Configure port and VLAN membership as described in the Configuring ports and VLANs on Switch 2 CLI example section in the VLANs chapter of this guide Add VLAN 2 to Spanning Tree Group 2 gt gt cfg l2 stp 2 Select Spanning Tree Group 2 gt gt Spanning Tree Group 2 add 2 Add VLAN 2 VLAN 2 is removed from Spanning Tree Group 1 Apply and save gt gt apply Apply the port configurations gt gt save Save the port configurations 7 w Spanning Tree Protocol Configuring Switch 1 BBI example 1 Configure port and VLAN membership on Switch 1 as described in the Configuring ports and VLANs on Switch 1 BBI example section in the VLANs chapter of this guide 2 Add VLAN 2 to Spanning Tree Group 2 a Click the Configure context button on the Toolbar b Select Spanning Tree Groups click the underlined text not the folder Open HP 10Gb Ethernet BL c Switch fa Switch Ports GA Port Ba
82. and preferred configuration for most networks RIPv2 expands the amount of useful information carried in RIP messages and provides a measure of security For a detailed explanation of RIPv2 refer to RFC 1723 and RFC 2453 RIPv2 improves efficiency by using multicast UDP address 224 0 0 9 data packets for regular routing updates Subnet mask information is provided in the routing updates A security option is added for authenticating routing updates by using a shared password HP 10GbE switch software supports using clear password for RIPv2 RIPv2 in RIPv1 compatibility mode HP 10GbE switch software allows you to configure RIPv2 in RIPv1 compatibility mode for using both RIPv2 and RIPv1 routers within a network In this mode the regular routing updates use broadcast UDP data packet to allow RIPv1 routers to receive those packets With RIPv1 routers as recipients the routing updates have to carry natural or host mask Hence it is not a recommended configuration for most network topologies NOTE When using both RIPv1 and RIPv2 within a network use a single subnet mask throughout the network RIP Features HP 10GbE switch software provides the following features to support RIPv1 and RIPv2 Poison Simple split horizon in RIP scheme omits routes learned from one neighbor in updates sent to that neighbor That is the most common configuration used in RIP that is setting this Poison to disable Split horizon with poisoned reverse includes
83. are discussed in this section e Quality of Service Overview e Using ACL Filters e Using DSCP Values to Provide QoS e Using 802 1p Priorities to Provide QoS e Queuing and Scheduling Overview QoS helps you allocate guaranteed bandwidth to the critical applications and limit bandwidth for less critical applications Applications such as video and voice must have a certain amount of bandwidth to work correctly using QoS you can provide that bandwidth when necessary Traffic for applications that are sensitive to timing out or cannot tolerate delay can be assigned to a high priority queue By assigning QoS levels to traffic flows on your network you can ensure that network resources are allocated where they are needed most QoS features allow you to prioritize network traffic thereby providing better service for selected applications The following figure shows the basic QoS model used by the HP 10GbE switch Figure 11 QoS model Ingress Ports Classify Meter Perform Queue and Egress Packets Traffic Actions Schedule ACL Filter Meter Re Mark Queue ACL Drop Pass ACOS The switch uses the Differentiated Services DiffServ architecture to provide QoS functions DiffServ is described in IETF RFCs 2474 and 2475 With DiffServ you can establish policies to direct traffic A policy is a traffic controlling mechanism that monitors the characteristics of the traffic for example its
84. as 113 Routing Information Protocol Distance vector PIOtO Cl issssscsssssansscsasaiesecsneansserecaiseaandennscescaaibessadeneseslansisdasbieneissiaibbssasbidajaeeehenssenweanens 114 Sal NN 114 FE re 114 RIP 115 RIPI A sd 115 RIPv2 in RIPv1 compotibility mode cn0cii ene narGurenceenirean nian head asses bass ems 115 RIP Featuresunsar uhyrer Serenade 115 POISON secsetisacaces esagaayinesnasees odsesbuttwasees Hr suceatieunsne S 115 TNT 10053 ss RE EAE e EE aaea TEE S ea SNES 115 Multicast RE EEE EE ARE EE 116 kver 116 MCHC sais 35s akse 116 Aithenticah oN essee asses aes eae aos E aap snaaeosnces waa sede onsen eetiaesees 116 FeigtdgambasssA ener rene nen terse renee 117 IGMP Snooping FAT 118 NEMNT 118 GM 119 FONEM 119 EG al RENN ERE RER NN 120 Configuring the EE EE EE EE 120 Cees 120 Static multicast role arvemasse kuke meierier uekat 121 IGMP Snooping configuration S nple Lunemensqeddakakensqgurassdtaknvdtnkalndait 121 Contents Configuring IGMP Snooping Nome 121 Configuring IGMP Filtering CLI exci le ciceaxecd pater seuccenrecd snsuey eounceeon ss analev sele 122 Configuring a Static Mrouter CLI example uvvrvov4v4vvvvsav aan 122 Configuring IGMP Snooping BBI example cccceeeceeeeceeceneeeeseeeeeeeeceeeeesneeesnaeeseeeeesteeeenetess 123 Configuring IGMP Filtering BBI example Lua vea Gera 125 Configuring a Static Multicast Router BBI example cccceseccesereeceseceeseeeeneeeeceseeenseeecteeeenaeees 129
85. assigned to an LIM e A trunk group configured as an LIM can contain multiple uplink ports 18 21 but no downlink ports 1 16 e An uplink port cannot be added to a trunk group if it already belongs to an LtM e An LtD can contain one or more ports and or one or more trunks e A trunk group configured as an LID can contain multiple downlink ports 1 16 but no uplink ports 18 21 Monitoring Uplink Failure Detection The UFD information menu displays the current status of the LIM and LtD and their member ports or trunks For example gt gt Information ufd Uplink Failure Detection Enabled LtM status Down STG STG State Link Status DISABLED 15 DISABLED STP turned off for this port LtD status Auto Disabled Link Status disabled disabled disabled disabled Use the stats ufd command to find out how many times link failure was detected on the LIM how many times Spanning Tree blocking state was detected on the LIM and how many times UFD disabled ports in the LtD Configuring Uplink Failure Detection The preceding figure shows a basic UFD configuration Assume that port 19 on Blade Switch 1 is connected to a Layer 2 3 routing switch outside of the chassis Port 18 and port 19 on Blade Switch 2 form a trunk that is connected to a different Layer 2 3 routing switch In this example NIC 1 is the primary network adapter NIC 2 NIC 3 and NIC 4 are non primary adapters NIC 1 and NIC 2 are conn
86. aster 20 VIR2 192 168 2 200 Backup L2 Switch NIC 1 10 0 1 1 24 NIC 2 10 0 2 1 24 NIC 1 10 0 1 2 24 Server 2 NIC 2 10 0 2 2 24 Internet x NIC 1 10 0 1 3 24 S NIC 2 10 0 2 3 24 Enterprise Routing Switch NIC 1 10 0 1 4 24 NIC 2 10 0 2 4 24 VIR 2 192 168 2 200 Master Although this example shows only two switches there is no limit on the number of switches used in a redundant configuration It is possible to implement an active active configuration across all the VRRP capable switches in a LAN Each VRRP capable switch in an active active configuration is autonomous Switches in a virtual router need not be identically configured In the scenario illustrated in the figure traffic destined for IP address 10 0 1 1 is forwarded through the Layer 2 switch at the top of the drawing and ingresses Switch A on port 20 Return traffic uses default gateway 1 192 168 1 1 If the link between Switch A and the Layer 2 switch fails Switch B becomes the Master because it has a higher priority Traffic is forwarded to Switch B Return traffic uses default gateway 2 192 168 2 1 and is forwarded through the Layer 2 switch at the bottom of the drawing To implement the active active example perform the following switch configuration Task 1 Configure Switch A 1 Configure ports cfg 12 vlan 10 Select VLAN 10 gt gt VLAN 10 ena Enable VLAN 10 gt gt VLAN 10 add 20 Add port 20 to VLA
87. ation Select primary default gateway Assign IP address Enable primary default gateway Select secondary default gateway Assign address Enable secondary default gateway gt gt Default gateway 2 fwrd gt gt IP Forwarding on gt gt IP Forwarding apply gt gt IP Forwarding cfg 13 cur Select the IP Forwarding Menu Turn IP forwarding on Make your changes active View current IP settings 10 Examine the resulting information If any settings are incorrect make the appropriate changes 11 Save your new configuration changes gt gt IP Forwarding save Save for restore after reboot Using VLANs to segregate broadcast domains In the previous example devices that share a common IP network are all in the same broadcast domain If you want to limit the broadcasts on your network you could use VLANs to create distinct broadcast domains For example as shown in the following procedure you could create one VLAN for the client trunks one for the routers and one for the servers In this example you are adding to the previous configuration 1 Determine which switch ports and IP interfaces belong to which VLANs 2 The following table adds port and VLAN information Table 22 Subnet routing example Optional VLAN ports VLAN Devices IP Interface Switch Port VLAN 1 First Floor Client Workstations 2 20 1 Second Floor Client Workstations 3 21
88. client confirms its identity by sending an EAP Response Identity frame to the switch authenticator which forwards the frame encapsulated in a RADIUS packet to the server 48 Port based Network Access and traffic control The Radius server chooses an EAP supported authentication algorithm to verify the client s identity and sends an EAP Request packet to the client via the switch authenticator The client then replies to the Radius server with an EAP Response containing its credentials Upon a successful authentication of the client by the server the 802 1x controlled port transitions from unauthorized to authorized state and the client is allowed full access to services through the controlled port When the client later sends an EAPOL Logoff message to the switch authenticator the port transitions from authorized to unauthorized state If a client that does not support 802 1x connects to an 802 1x controlled port the switch authenticator requests the client s identity when it detects a change in the operational state of the port The client does not respond to the request and the port remains in the unauthorized state NOTE When an 802 1x enabled client connects to a port that is not 802 1x controlled the client initiates the authentication process by sending an EAPOL Start frame When no response is received the client retransmits the request for a fixed number of times If no response is received the client assumes the port is in auth
89. d Make sure that trunk groups consist of the expected ports and that each port is in the expected state 40 Ports and trunking Configuring trunk groups BBI example 1 Configure trunk groups a Click the Configure context button on the Toolbar b Open the Layer 2 folder and select Trunk Groups HP 10Gb Ethernet BL c Switch GA Switch Ports GA Port Based Port Mirroring 802 1x FDB Virtual LANs Spanning Tree Groups Ga MSTP RSTP c Click a Trunk Group number to select it Select 41 Ports and trunking d Enable the Trunk Group To add ports select each port in the Ports Available list and click Add Switch Trunk Group 5 Configuration Ports added to Trunk Port 2 e Click Submit 2 Apply verify and save the configuration h GOE T j CONFIGURE STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save 3 Examine the trunking information on each switch a Click the Dashboard context button on the Toolbar Ss O CONFIGURE STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 42 Ports and trunking b Select Trunk Groups HP 10Gb Ethernet BL c Switch GA Switch Ports Port Based Port Mirroring open 802 1x FOB Virtual LANs Spanning Tree Groups MSTP RSTP c Information about each configured trunk group is displayed Make sure that trunk groups consist of the expected ports and that
90. d PC 3 The Layer 2 switch port to which it is connected is configured for both VLAN 1 and VLAN 2 and has tagging enabled NOTE All PCs connected to a tagged port must have an Ethernet adapter with VLAN tagging capability installed Configuring the example network These examples describe how to configure ports and VLANs on Switch 1 and Switch 2 Configuring ports and VLANs on Switch 1 CLI example To configure ports and VLANs on Switch 1 do the following 1 On Switch 1 enable VLAN tagging on the necessary ports Main cfg port 1 gt gt Port 1 tage Select port 1 connection to server 1 Current VLAN tag support disabled New VLAN tag support enabled Enable tagging Port 1 changed to tagged Main cfg port 18 Select uplink port 18 gt gt Port 18 tag e Enable tagging Current VLAN tag support disabled New VLAN tag support enabled Port 18 changed to tagged gt gt Port 18 apply Apply the port configurations 6l VLANs 2 Configure the VLANs and their member ports Since all ports are by default configured for VLAN 1 configure only those ports that belong to VLAN 2 gt gt cfg 12 vlan 2 gt gt VLAN 2 add 1 Current ports for VLAN 2 empty Pending new ports for VLAN 2 1 gt gt VLAN 2 add 18 Add port 18 to VLAN 2 Current ports for VLAN 2 1 Pending new ports for VLAN 2 18 gt gt VLAN 2 add 20 Add port 20 to VLAN 2 Port 20 is an UNTAGGED port and its current PVID is
91. d is measured in number of frames per second NOTE All ports that belong to a trunk must have the same traffic control settings 51 Port based Network Access and traffic control Configuring port based traffic control To configure a port for traffic control perform the following steps 1 Configure the traffic control threshold and enable traffic control Main cfg port 2 gt gt Port 2 brate 150000 Set broadcast threshold gt gt Port 2 mrate 150000 Set multicast threshold gt gt Port 2 drate 150000 Set DLF threshold 2 To disable a traffic control threshold use the following command gt gt Port 2 mrate dis Disable multicast threshold 3 Apply and save the configuration gt gt Port 2 apply Apply the port configurations gt gt Port 2 save Save the port configurations 52 VLANs Introduction This chapter describes network design and topology considerations for using Virtual Local Area Networks VLANs VLANs are commonly used to split up groups of network users into manageable broadcast domains to create logical segmentation of workgroups and to enforce security policies among logical segments The following topics are discussed in this chapter e VLANs and Port VLAN ID Numbers e VLAN Tagging e VLANs and IP Interfaces e VIAN Topologies and Design Considerations NOTE Basic VLANs can be configured during initial switch configuration More comprehensive VLAN configu
92. dd to place the ports into the Link to Monitor LtM Select ports in the LtD Ports Available list and click Add to ports into the Link to Disable LtD ace the Failure Detection Pair Configuration vi FDP Port Configuration LtM Ports Available LtM Ports Selected PortID Port18 Add gt gt ip Port21 LtD Ports Available LtD Ports Selected PortID A PortID Port3 Add gt gt Port1 Port4 LAdd gt gt Port2 Port5 Port6 e Click Submit 2 Apply verify and save the configuration h T TV ip CONFIGURE STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save 172 High availability VRRP overview In a high availability network topology no device can create a single pointof failure for the network or force a single point of failure to any other part of the network This means that your network will remain in service despite the failure of any single device To achieve this usually requires redundancy for all vital network components VRRP enables redundant router configurations within a LAN providing alternate router paths for a host to eliminate single points of failure within a network Each participating VRRP capable routing device is configured with the same virtual router IP address and ID number One of the virtual routers is elected as the master based on a number of priority criteria and assumes control of the shared virtual
93. e ER E R ENEE O EEEN OE OEREO EAGER 174 Selecting the master VRRP router asi sactetuecdoisesiesemnoaynanieesteseona as aeantentoemnalasiamaee 174 Failover methods annenin enee ee a a eee E EEEE E EEE Eat 175 Active Active redundancy cccscscccesssscseeceseceeesenseeeeeesaeeeeeceeaeeecesaaeeeeeaeeeesceseaeescesaaeescesaeeeensessaeeees 175 HP 10GbE switch extensions to VRRP ccocconeynsnasca Sedesmnadynandscantecenyuagivandonedesanyondiwed sande fei yeeaaeas meat 176 Tracking VRRP router priority Jeg 176 Virtual router deployment considerations yicsccssasrasiesbhosegrian Gaaalbiiboninn aul eheeian ANNE Han NRC 177 Assigning VRRP virtual router RR ER 177 Configuring EAN 177 High availabiliiy config ranse a E EAEE ne eee rer Teer 178 Active Active configuration 5 ac iajnsses ies scaceaea soos teaeicaeiepoeneasd Stes reS SESSE S SNES SNESS SEESE ESSES SNES Sse nn neess een net 178 Task 1 Configure Switch RE RE RE 178 elev 180 Task 1 Configure Switch Av BBlemampsle Lavrans 181 Troubleshooting tools Iitr ducti Ons an a E E a ie ee 191 Port MILFOHINGs lt 0ecccedecues pops s dekkene 191 Configuring Port Mirroring CLI example ccccceesceeseseeceeeeeeeeeeeceseeceeeessueeecsaeeseceeecnseeseaeeeeneeeeas 192 Configuring Port Mirroring BBI example o 3 ccssccasccessasarcchestacanessiearcesactaretesacsavansdosasnbensssvaatontacenbanss 193 Other network troubleshooting techniques cccccececeteceeeeceeeceseceseeseeeenrecseeeee
94. e IP address of the management interface manually or through Dynamic Host Control Protocol DHCP e Gateway 254 This gateway is the default gateway for the management interface STG 128 If the HP 10GbE switch is configured to use multiple spanning trees spanning tree group 128 STG 128 contains management VLAN 4095 and no other VLANS are allowed in STG 128 The default status of STG 128 is off If the TOGbE switch is configured to use Rapid Spanning Tree Protocol STG 1 contains management VLAN 4095 To access the 1OGbE switch management interface through the Onboard Administrator e Use the Onboard Administrator internal DHCP server through Enclosure Based IP Addressing e Use an external DHCP server Connect the Onboard administrator and the 10GbE switch to the network and disable Enclosure Based IP Addressing e Assign a static IP interface to the Onboard Administrator and to the 1OGbE switch management interface interface 250 Connecting through the console port Using a null modem cable you can directly connect to the switch through the console port A console connection is required in order to configure Telnet or other remote access applications For more information on establishing console connectivity to the switch see the HP 10Gb Ethernet Bl c Switch User Guide Connecting through Telnet By default Telnet is enabled on the switch Once the IP parameters are configured you can access the CLI from any works
95. e attributes are not supported and might affect 802 1x operations Other unsupported attributes include Service Type Session Timeout and Termination Action RADIUS accounting service for 802 1x authenticated devices or users is not supported Configuration changes performed using SNMP and the standard 802 1x MIB take effect immediately Port based traffic control Port based traffic control prevents HP 10GbE switch ports from being disrupted by LAN storms A LAN storm occurs when data packets flood the LAN which can cause the network to become congested and slow down Errors in the protocol stack implementation or in the network configuration can cause a LAN storm You can enable port based traffic control separately for each of the following traffic types e Broadcast packets with destination MAC address ff ff ff fit f e Multicast packets that have MAC addresses with the least significant bit of their first octet set to one e Destination Lookup Failed DLF packets with unknown destination MAC address that are treated like broadcast packets With Port based Traffic Control enabled the port monitors incoming traffic of each type noted above If the traffic exceeds a configured threshold the port blocks traffic that exceeds the threshold until the traffic flow falls back within the threshold The HP 10GbE switch supports separate traffic control thresholds for broadcast multicast and DLF traffic The traffic threshol
96. e other is a stub area A stub area does not allow advertisements of external routes thus reducing the size of the database Instead a default summary route of IP address 0 0 0 0 is automatically inserted into the stub area Any traffic for IP address destinations outside the stub area will be forwarded to the stub area s IP interface and then into the backbone Figure 21 Simple OSPF domain N 10 10 7 0 24 gt Backbone Stub Area AreaO N 10GbE sp Areal NS 4 0 0 0 1 0 0 0 0 0 0 0 IF 1 IF 2 10 10 7 1 10 10 12 1 I Network Network W L 10 10 12 0 24 p am HP Blade Chassis 141 OSPF Follow this procedure to configure OSPF support as shown in the figure 1 Configure IP interfaces on each network that will be attached to OSPF areas 2 In this example two IP interfaces are needed one for the backbone network on 10 10 7 0 24 and one for the stub area network on 10 10 12 0 24 3 Enable OSPF gt gt cfg 13 if 1 Select menu for IP interface 1 addr 10 10 7 1 Set IP address on backbone network mask 255 255 255 0 Set IP mask on backbone network enable Enable IP interface 1 gt gt IP Interface gt gt IP Interface gt gt IP Interface if 2 Select menu for IP interface 2 addr 10 10 12 1 Set IP address on stub area network mask 255 255 255 0 Set IP mask on stub area network enable Enable IP interface 2 gt gt IP Interface gt gt I
97. e to the transit area gt gt OSPF Interface 1 if 2 Select OSPF menu for IP interface 2 gt gt OSPF Interface 2 aindex 2 Attach network to stub area index gt gt OSPF Interface 2 enable Enable the stub area interface Configure the virtual link The nbr router ID configured in this step must be the same as the router ID that was configured for Switch A in step 2 gt gt OSPF Interface 2 gt gt OSPF Virtual Link 1 aindex 1 Specify the transit area gt gt OSPF Virtual Link 1 nbr 10 10 10 1 Specify the router ID gt gt OSPF Virtual Link 1 enable virt 1 Specify a virtual link number for the virtual link of the recipient Enable the virtual link Apply and save the configuration changes gt gt OSPF Interface 2 apply gt gt OSPF Interface 2 save Apply all changes Save all changes Other Virtual Link Options You can use redundant paths by configuring multiple virtual links Only the endpoints of the virtual link are configured The virtual link path may traverse multiple routers in an area as long as there is a routable path between the endpoints Example 3 Summarizing routes By default ABRs advertise all the network addresses from one area into another area Route summarization can be used for consolidating advertised addresses and reducing the perceived complexity of the network If the network IP addresses in an area are assig
98. each VLAN to a separate STG Each STG is independent Each STG sends its own Bridge Protocol Data Units BPDUs and each STG must be independently configured The STG or bridge group forms a loop free topology that includes one or more virtual LANs VLANs The switch supports 128 STGs running simultaneously The default STG 1 supports IEEE 802 1d Spanning Tree Protocol and may contain more than one VLAN All other STGs support Per VLAN Spanning Tree PVST and may contain only one VLAN each The switch can support multiple VLANs in STGs 2 128 however you must enable IEEE 802 1s Multiple Spanning Tree Protocol mode For more information see the RSTP and MSTP chapter in this guide Why do we need Multiple Spanning Trees The following figure shows a simple example of why we need multiple Spanning Trees This example assumes that port 20 and 21 are not part of a Trunk Group Two VLANs VLAN 1 and VLAN 2 exist between Switch 1 and Switch 2 If the same Spanning Tree Group is enabled on both switches the switches see an apparent loop and block port 21 on Switch 2 which cuts off communication between the switches for VLAN 2 Spanning Tree Protocol Figure 9 Two VLANs on one instance of Spanning Tree Protocol VLAN 1 STG 1 Switch 1 21 VLAN 2 STG VLAN 2 is blocked by STP Switch 2 In the following figure VLAN 1 and VLAN 2 belong to different Spanning Tree Groups The two instances of spanning tree separate
99. econdary Default Routers 205 21 17 3 IF 2 First Floor Client Workstations 100 20 10 1 IF 3 Second Floor Client Workstations 131 15 15 1 IF 4 Common Servers 206 30 15 1 5 IP interfaces are configured using the following commands at the CLI cfg 13 if 1 Interface Interface Interface Interface Interface Interface Interface Interface Interface Interface Interface 2 2 2 3 3 3 4 4 addr 205 21 17 3 ena JED addr 100 20 10 1 ena sn fit addr 131 15 15 1 ena if 4 addr 206 30 15 1 ena Select Assign Enable Select Assign Enable Select Assign Enable Select Assign Enable in terface 1 address interface 1 in terface 2 address interface 2 in terface 3 address in terface 3 interface 4 address in terface 5 6 Set each server and workstation s default gateway to the appropriate switch IP interface the one in the same subnet as the server or workstation 7 Configure the default gateways to the routers addresses Basic IP routing 8 Configuring the default gateways allows the switch to send outbound traffic to the routers gt gt Default gt gt Default gt gt Default gt gt Default gt gt Default gt gt IP Interface 5 gateway gateway gateway gateway gateway 9w 1 1 addr 205 21 17 1 1 ena 1 gw 2 2 addr 205 21 17 2 2 ena 9 Enable apply and verify the configur
100. ected to port 1 and port 2 on Blade Switch 1 NIC 3 and NIC 4 are connected to port 1 and port 2 on Blade Switch 2 169 High availability Configuring UFD on Switch 1 CLI example 1 Assign uplink ports 18 21 to be monitored for communication failure gt gt Main cfg ufd fdp ena Enable Failure Detection Pair gt gt FDP ltm Select Link to Monitor menu gt gt Failure Link to Monitor addport 19 Monitor uplink port 19 2 Assign downlink ports 1 16 to disable when an uplink failure occurs gt gt cfg ufd fdp ltd Select Link to Disable menu gt gt Failure Link to Disable addport 1 Add port 1 as a Link to Disable gt gt Failure Link to Disable addport 2 Add port 2 as a Link to Disable 3 Turn UFD on gt gt cfg ufd on Turn Uplink Failure Detection on gt gt Uplink Failure Detection apply Make your changes active gt gt Uplink Failure Detectiont save Save for restore after reboot When a link failure or Spanning Tree blocking occurs on port 19 Blade Switch 1 disables port 1 and port 2 Configuring UFD on Switch 2 CLI example 1 Create a trunk group of uplink ports 18 21 to monitor gt gt Main cfg trunk 2 Create trunk group 2 gt gt Trunk group 2 ena Enable trunk group 2 gt gt Trunk group 2 add 18 Add port 18 to trunk group 2 gt gt Trunk group 2 add 19 Add port 19 to trunk group 2 2 Assign the trunk group to be monitored for commun
101. eee eas 141 OSPF configuration examples EEE 141 Example 1 Simple OSPF domain CLI example ccccccscsccccssceeeccseccescsseeeesesseeeesecssseeescseeeeseeseaes 14 Example 1 Simple OSPF domain BBI example c ccccsesseceeseseeeeesseseecesseeeeesseeeecessaeeeeessaaes 142 Example 2 Viruallinks a sccsce2ceitsnetes Safeteeaiehethededdecedd Qeaibb chi becehalaadid Hanen teases 150 Configuring OSPF for a virtual link on Switch A 4 ctscatsd cccedane taalsbasatacancdiulaWaceshaatierateantamdcuanss 150 Configuring OSPF for a virtual link on Switch Ba 151 Other Virtual Link Options cccccccccccsseeceesenseecesesseecesceseceseseseeeeessseeeesenseeeeseseeeeessnseeeesenseeeeees 152 Example 3 Summarizing oleuv4v4vrrvvv4ere ae aoe 152 Verifying ISP Onl Ge EE ENE EE eae 154 Remote monitoring Freda 155 SEE PE EE EE EN EE EEE steals EE E E R 155 RMON group l statisties sjuitesra seters dad 155 Configuring RMON Statistics CLI amp amplbLuuvvv vvvqvmsme ane o rlekraeten 156 Configuring RMON Statistics BBI example cccceceeeeesseeseeesneeeeeeeseesneeeneesseesnteseeeesnteetees 156 RMON group T v deira eee 158 History MIB OD GGtS cscrivsnictesssssdarnssacintianiasibenssatinesaniasanadanaeaninaniadbuasndekiageaseesiariasbecsesberuariaians 159 RMON group oS GIGIIS sstssecesiasianedsessvecsedsschapvasneeehasiesihassvsaeeeiasavenneesin rmeaasabanhbestadenasiabannaiadeass 161 Alarm MIB objects ccccccecseseeccesseeeecess
102. eeeeecseeeeeesceeececseseeseceeeeeescseeeecseseeeeeeseesesseeeeesesaaes 161 RMON GhOUp J EL RE ETE 165 Configuring RMON Events CLI example 0 ceccecceeeeeeeeeesesseeeeseeeeeessesseeseneesseesnreeeeeesneeneeens 165 Configuring RMON Events BBI example ccccccceseceeseneeceneeeesnreeceseceeeeeeseeeceseeeneeeenteeeeeeeees 166 Contents High availability le 167 Uplink Failure Detection rrorvrrrrrorrrrrervrvrrrerervnrerrennvrerervevnsrerensnreerersnsessenevsesesennnseerennnsesrenenensessennnser 167 Failure Detection Faks PP 168 Spanning Tree Protocol vaar FSA 168 Configuration guidelines TS 169 Monitoring Uplink Failure Dateien inca nncsnchsen ct areoninenae Renee ean pee 169 Configuring Uplink Failure Detection 44444 169 Configuring UFD on Switch Tam vasre sen 170 Configuring UFD on Switch 2 CLI example vvvrv4vvmv vr 170 Configuring Uplink Failure Detection BBI example rarnrvnrnnnrnrrnvrnrrrvnrrrnrrnrrnnnrrrnnrrrrnnrrrnnnrrrnnnenn 171 YRKE Sveen 173 VRRP Components aars nasa neii 173 TET 173 Virtual router MAC dddresuanessstie votnaaboestsebeassgaunnrdracsiad erento eh indebadssarentesnindennass 173 Owners and EE ER 173 Master and backup virtual Touter 3 csisisecsessssaciesiatoncaasiscaeebsionabarnsanmneasiazabestrseaneassecenan tauren 174 Virtual Interface Forks iasccicisaccaessscaninisrerieossoasuesinraraadbeas aasnoieapiatseisanbeeidheas eariibiouitasbonieediads 174 VRRP Operaio eese coreo ori ea
103. en TE 10Gb Ethernet BL c Switch 3 System BlUser Table Select E Radius i BTacacs H Syslog Trap Features 2 Config Image Control E Management Network c Enter the IP address of the primary and secondary RADIUS servers and enter the RADIUS secret for each server Enable the RADIUS server A CAUTION If you configure the RADIUS secret using any method other than a direct console connection the secret may be transmitted over the network as clear text d Click Submit 23 Accessing the switch 2 Apply verify and save the configuration h Fame Hy FIGURE STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save RADIUS authentication features The switch supports the following RADIUS authentication features e Supports RADIUS client on the switch based on the protocol definitions in RFC 2138 and RFC 2866 e Allows RADIUS secret password up to 32 bytes e Supports secondary authentication server so that when the primary authentication server is unreachable the switch can send client authentication requests to the secondary authentication server Use the cfg sys radius cur command to show the currently active RADIUS authentication server e Supports user configurable RADIUS server retry and time out values o Time out value 1 10 seconds o Retries 1 3 e The switch will time out if it does not receive a response from the RADIUS server in one t
104. er of a specific VLAN When an untagged frame exits the switch through a tagged member port the frame header is modified to include the 32 bit tag associated with the PVID When a tagged frame exits the switch through a tagged member port the frame header remains unchanged original VID remains NOTE If an 802 1Q tagged frame is sent to a port that has VLAN tagging disabled then the frames are forwarded based on their port VLAN ID PVID 55 VLANs Figure 3 Default VLAN settings 802 1Q Switch VLAN 1 Port 1 Port2 Porta Porta Ports Porte Port7 Ports PVID 1 CRC vvo gt gt Incoming Outgoing at untagged untagged packet packet unchanged Key ay By default All ports are assigned PVID 1 All ports are untagged members of VLAN 1 BS45010A NOTE The port numbers specified in these illustrations may not directly correspond to the physical port configuration of your switch model When you configure VLANs you configure the switch ports as tagged or untagged members of specific VLANs See the following figures In the following figure the untagged incoming packet is assigned directly to VLAN 2 PVID 2 Port 5 is configured as a tagged member of VLAN 2 and port 7 is configured as an untagged member of VLAN 2 Figure 4 Port based VLAN assignment PVID 2 Port1 Port2 Port3 Tagged member Untagged packet NS of VLAN 2 gged p CRC Data S
105. ertieastairaakesiansebesinhsasabrsatienesadosaes tianbee unbaaanaieasianes 80 MPETRE 80 Common Internal Spanning Teevvaseommssornkamdnn hasagneradermn basidsmnd de 80 MSTP configuration guidelines uvrveqeassseskesaaGe ata anda ne 81 MSTP configuration SHANI E o5 0520ssoacrassaysace vaameeenigeaevota raanicons yey inas cone Taatquatiovas tana ideaniadand vaceanteeabantass 81 Configuring Multiple Spanning Tree Protocol CLI example ceeeeeceeseeeeeeeeseesneesnsecseeesneesnteeaes 81 Configuring Multiple Spanning Tree Protocol BBI example cceeceesseeseeeteeeeeesneeeseeesteesnteesaes 82 Quality of Service kl sje Fe RE RER EE NE RER 86 ONE EEE EE EEE EE 86 Using GR SE EE RR ga aa adc aa cae 87 Summary of packet classifiers cccccccccscccecceseseeeceseeeeeceeeeeseseeeesecseseeesceeeeeseseseesesseaeesessseeeseseeseees 87 Summary Ot ACL actions issena a ty stv tee E TE E E EEE EEEE ES eh await ad 89 Understanding ACL precedence a aisssiiecenunGiaienionncinaianiiomenGinemienatn Wis eaieenn ana 89 Contents Using ACh Groupsiccai cies shicetertens ae 90 ACL Metering and Retiring i5c05 4eacceieetacecesaced vance saccaueeelngetetssacadiensdeadtontsudeieaesetabiaeactoassdastonseamaausas 91 Meteringsu sassanidene dead ange oa benene 91 Re marking REE EE EE en gate EN EE ER 91 Viewing OE EEE EE EE 91 ACLconfiguration Ge ENER NE 92 Configure Access Control Lists CLI example assisscsnsssnrrrsassdscsateavscsadenrensaaeneanseadb
106. es occur to the physical topology or its configuration parameters RSTP reduces the bridged LAN topology to a single Spanning Tree For more information about Spanning Tree Protocol see the Spanning Tree Protocol chapter in this guide RSTP parameters are configured in Spanning Tree Group 1 STP Groups 2 128 do not apply to RSTP and must be cleared There are new STP parameters to support RSTP and some values to existing parameters are different RSTP is compatible with devices that run 802 1d Spanning Tree Protocol If the switch detects 802 1d BPDUs it responds with 802 1d compatible data units RSTP is not compatible with Per VLAN Spanning Tree PVST protocol Port state changes The port state controls the forwarding and learning processes of Spanning Tree In RSTP the port state has been consolidated to the following discarding learning and forwarding Table 13 RSTP vs STP port states Port operational status STP port state RSTP port state Enabled Blocking Discarding Enabled Listening Discarding Enabled Learning Learning Enabled Forwarding Forwarding Disabled Disabled Discarding 77 RSTP and MSTP Port type and link type Spanning Tree Configuration includes the following parameters to support RSTP and MSTP e Edge port e Link type Although these parameters are configured for Spanning Tree Groups 1 128 cfg 12 stp y port x they only take effect when RSTP MSTP is turned on Edge port A port
107. eseeserse 21 RADIUS authentication and orakel 21 How RADIUS authentication WOrks cc0 cijasiecsiniossenansnnseerdeognemanenonenoeopnn beanendeoonaanmmeuaronnans 21 Configuring RADIUS on the switch CLI example vasse eekdedde 22 Configuring RADIUS on the switch BBI example Lg eee 23 RADIUS authentication ee LOR REN RE 24 User accounts for RADIUS vek Larsen eek ESES SINE E o SESE EE 24 RADIUS attributes for user privileges tcniaauvancanvaiatwausn sisses dnnakidun anni aNnaeaiee 25 HENG GT EE NR SN 25 How TACACS authentication Fe Vava dima wivnheniaagdeaaniernds 26 TACACS authentication features seede mei edaknenb bd 26 Authorization ioe ER E E E EE ER EE 26 ACCOUNTING irie Ea subnets E E E R E E E E T E ER 27 Configuring TACACS authentication on the switch CLI example orerrvrrnvenenenovrrnrvanevernvnnrrvrrevenennne 28 Configuring TACACS authentication on the switch BBI example sssseeeeereriseseersersrrrsresrrsreserrsreseese 29 Secure Shell and Secure Copy ccccccccccsssceccsssseecesssneeeccssneeecesseeecesseseeeecssseeesesseseesessesesesenseeeeessiseeeesenes 30 Configuring SSH and SCP features CLI example ssncasscecteereisensaeieacednei semaines saeedineens 31 Using SSH and SCP client commands cocsss usvricceensesenstey ea ceauesensarenrceaeneea eecreueae aes 32 SSH and SCP encryption of management messages ceccccessseeseseceeceeeeseeecueeeeeaeeeeeeesteeeenaeeneaes 33 Generating RSA host and server keys for SSH acce
108. esnreseeeesieesnteseseesseeenteesses 195 Console and Syslog messagesunnanunmnum nn ntedeseines dnenvaarteessiandshasvrariesadaseanesstabeassed 195 Move 195 Troeen 195 Statistics and state intorMation s cssecscsrsserserncoserssassccssennsnsssssassscaesensosrsasnenssaenabssssssonesssaesane senssendans 195 Customer support tOOlS cccccccceccsseceeeceseceeeceeeeeeeceeeeesceeeeeseeeseesecseeeesceseeeeseseaeesecesaeesesetaeaeeeeeas 195 Index Accessing the switch Introduction This guide will help you plan implement and administer the switch software for the HP 10Gb Ethernet BL c Switch Where possible each section provides feature overviews usage examples and configuration instructions Accessing the switch describes how to configure and view information and statistics on the switch over an IP network This chapter also discusses different methods to manage the switch for remote administrators such as setting specific IP addresses and using Remote Authentication Dial in User Service RADIUS authentication Secure Shell SSH and Secure Copy SCP for secure access to the switch Ports and port trunking describes how to group multiple physical ports together to aggregate the bandwidth between large scale network devices Port based Network Access and Traffic Control describes how to authenticate devices attached to a LAN port that has point to point connection characteristics Port based Network Access Control pro
109. f Switch A is the master and it has two or more active servers fewer than Switch B then Switch B becomes the master If Switch B is the master it remains the master even if servers are restored on Switch A such that it has one fewer or an equal number of servers If Switch B is the master and it has one active server fewer than Switch A then Switch A becomes the master The user can implement this behavior by configuring the switch for tracking as follows 1 2 3 Set the priority for Switch A to 101 Leave the priority for Switch B at the default value of 100 On both switches enable tracking based on ports ports interfaces ifs or virtual routers vr You can choose any combination of tracking parameters based on your network configuration NOTE There is no shortcut to setting tracking parameters The goals must first be set and the outcomes of various configurations and scenarios analyzed to find settings that meet the goals 177 High availability High availability configurations The HP 10GbE switches offer flexibility in implementing redundant configurations This section discusses the Active Active configuration Active Active configuration The following figure shows an example configuration where two switches are used as VRRP routers in an active active configuration In this configuration both switches respond to packets Figure 27 Active Active high availability configuration VIR 1 192 168 1 200 M
110. face 153 OSPF 7 Configure route summarization by specifying the starting address and mask of the range of addresses to be summarized gt gt OSPF Interface 2 range 1 Select menu for summary range gt gt OSPF Summary Range 1 addr 36 128 192 0 Set base IP address of summary range gt gt OSPF Summary Range 1 mask 255 255 192 0 Set mask address for summary range gt gt OSPF Summary Range 1 aindex 0 Inject summary route into backbone gt gt OSPF Summary Range 1 enable Enable summary range 8 Use the hide command to prevent a range of addresses from advertising to the backbone gt gt OSPF Interface 2 range 2 Select menu for summary range gt gt OSPF Summary Range 2 addr 36 128 200 0 Set base IP address gt gt OSPF Summary Range 2 mask 255 255 255 0 Set mask address gt gt OSPF Summary Range 2 hide enable Hide the range of addresses 9 Apply and save the configuration changes gt gt OSPF Summary Range 2 apply Apply all changes gt gt OSPF Summary Range 2 save Save all changes Verifying OSPF configuration Use the following commands to verify the OSPF configuration on your switch e info 13 ospf general e info 13 ospf nbr info 13 ospf dbase dbsum e info 13 ospf routes e stats 13 route See the HP 10Gb Ethernet Bl c Switch Command Reference for information on the above commands 154 Remote monito
111. face configuration 111 IP interfaces 58 multiple spanning trees 68 multiple VLANs 55 port members 54 PVID 54 security 53 Spanning Tree Protocol 68 tagging 54 topologies 58 VLAN 1 default 58 VRRP Virtual Router Redundancy Protocol active active redundancy 175 overview 173 virtual router ID numbering ID numbering 177 overview tracking 176 vrid 173 198
112. fine ACL 257 gt gt ACL 257 egrport 21 gt gt ACL 257 action deny gt gt ACL 257 stats e gt gt ACL 257 cfg port 20 aclqos gt gt Port 20 ACL add acl 1 Add ACL 1 to port 20 gt gt Port 20 ACL add acl 257 Add ACL 257 to port 20 gt gt Port 20 ACL apply gt gt Port 20 ACL save In this example all traffic Layer 2 known unicast that ingresses on port 20 from source MAC 00 21 00 00 00 00 and is destined for port 21 is denied Configure Access Control Lists and Groups BBI example 1 1 Configure Access Control Lists ACLs a Click the Configure context button on the Toolbar b Open the Access Control Lists folder and select Add ACL Open HP 10Gb Ethernet BL c Switch System Switch Ports Port Based Port Mirroring Layer 2 RMON Menu Layer 3 QoS Access Control Access Control Lists Select add Add ACL Access Control List Groups a Uplink Failure Detection 93 Quality of Service c Configure the ACL parameters Set the Filter Action to Deny the Ethernet Type to IPv4 and the Destination IP Address to 100 10 1 116 Access Control List ACL Id 1 384 255 Group Id 0 Filter Action Deny v Set priority value none v Ethemet Packet Format Disabled v Tagging Packet Format Disabled v Source MAC Address 00 00 00 00 00 00 Mask FER Destination MAC Address 00 00 00 00 00 00 Ethemet Type None Value 0600 85 600 VLAN Id 1 4095 1 Mask
113. g gt gt VRRP Virtual Router 1 prio 101 Set the VRRP priority gt gt VRRP Virtual Router 1 gt gt Virtual Router Redundancy Protocol vr 2 Select VRRP virtual router 2 gt gt VRRP Virtual Router 1 track ports ena Set tracking on ports 6 Turn off Spanning Tree Protocol globally cfg 12 stg 1 0ff Turn off STG gt gt Spanning Tree Group 1 apply gt gt Spanning Tree Group 1 save 179 Task 2 Configure Switch B 1 Configure ports 2 Configure client and server interfaces cfg 13 if 1 High availability gt gt gt gt gt gt gt gt gt gt gt gt cfg 12 vlan 10 VLAN 10 VLAN 10 VLAN 10 L V ena add vian ena add 20 20 21 Select VLAN Enable VLAN Add port 20 Select VLAN Enable VLAN Add port 21 10 10 to VLAN 10 20 20 to VLAN 20 gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt gt IP IP IP IP Layer 3 if 2 IP IP IP IP Interface 2 Layer 3 if 3 IP Interface 3 IP Interface 3 IP Interface 3 IP Interface 2 Layer 3 if 4 IP Interface 4 IP Interface 4 IP Interface 4 1 1 1 1 Interface Interface Interface Interface Interface 2 Interface 1 Interface 2 addr vlan 10 ena addr 192 168 1 101 192 168
114. g associated with each tracked item If the priority level of a standby is greater than that of the current master then the standby can assume the role of the master See Configuring the Switch for Tracking for an example on how to configure the switch for tracking VRRP priority 176 High availability Virtual router deployment considerations Review the following issues described in this section to prevent network problems when deploying virtual routers Assigning VRRP Virtual Router ID Configuring the Switch for Tracking Assigning VRRP virtual router ID During the software upgrade process VRRP virtual router IDs are assigned automatically if failover is enabled on the switch When configuring virtual routers at any point after upgrade virtual router ID numbers cfg 13 vrrp vr vrid must be assigned The virtual router ID may be configured as any number between 1 and 250 Configuring the switch for tracking Tracking configuration largely depends on user preferences and network environment Consider the configuration shown in the previous figure Assume the following behavior on the network Switch A is the master router upon initialization If Switch A is the master and it has one fewer active servers than Switch B then Switch remains the master This behavior is preferred because running one server down is less disruptive than bringing a new master online and severing all active connections in the process I
115. g processes for various virtual routers in a LAN converge on the same switch Tracking ensures that the selected switch is the one that offers optimal network performance For tracking to have any effect on virtual router operation preemption must be enabled Switch software can track the attributes listed in the following table Table 23 VRRP tracking parameters Parameter Description Number of IP interfaces on the switch that are active up Helps elect the virtual routers with the most available cfg 13 vrrp track ifs routes as the master An IP interface is considered active when there is at least one active port on the same VLAN This parameter influences the VRRP router s priority in virtual interface routers Number of active ports on the same VLAN Helps elect the virtual routers with the most available cfg 13 vrrp track ports ports as the master This parameter influences the VRRP router s priority in virtual interface routers Number of virtual routers in master mode on the switch Useful for ensuring that traffic for any particular client cfg 13 vrrp track vrs server pair is handled by the same switch increasing routing efficiency This parameter influences the VRRP router s priority in virtual interface routers Each tracked parameter has a user configurable weight associated with it As the count associated with each tracked item increases or decreases so does the VRRP router s priority subject to the weightin
116. g whitepapers html UFD allows the switch to monitor specific uplink ports to detect link failures When the switch detects a link failure it automatically disables specific downlink ports The corresponding server s network adapter can detect the disabled downlink and trigger a network adapter failover to another port on the switch or another switch in the chassis The switch automatically enables the downlink ports when the uplink returns to service The following figure shows a basic UFD configuration with a Failure Detection Pair FDP that consists of one LtM Link to Monitor and one LtD Link to Disable When the switch detects a link failure in the LtM it disables the ports in the LtD The server blade detects the disabled downlink port which triggers a NIC failover 167 Figure 24 Uplink Failure Detection for switches Enterprise Routing Switch Uplink Ports LtM aun Blade Switch 1 Downlink Ports LID NIC NIC NIC NIC 412184 wo Server 1 LID High availability Enterprise Routing Switch LIMT Blade Switch 2 HP Blade Chassis Failure Detection Pair To use UFD you must configure a Failure Detection Pair and then turn UFD on A Failure Detection Pair consists of the following groups of ports e Link to Monitor LtM The Link to Monitor group consists of one uplink port 18 21 or one trunk group that contains only uplink ports The trunk group can be a Link Aggregation Control
117. ges of the remote user and authorizes the appropriate access When both the primary and secondary authentication servers are not reachable the administrator has an option to allow backdoor access via the console only or console and Telnet access The default value is disable for Telnet access and enable for console access The administrator also can enable secure backdoor cfg sys tacacs secbd to allow access if both the primary and secondary TACACS servers fail to respond Accounting Accounting is the action of recording a user s activities on the device for the purposes of billing and or security It follows the authentication and authorization actions If the authentication and authorization is not performed via TACACS no TACACS accounting messages are sent out You can use TACACS to record and track software logins configuration changes and interactive commands The switch supports the following TACACS accounting attributes e protocol console telnet ssh http start_time e stop time e elapsed time NOTE When using the browser based Interface the TACACS Accounting Stop records are sent only if the Quit button on the browser is clicked Accessing the switch Configuring TACACS authentication on the switch CLI example 1 Turn TACACS authentication on and then configure the Primary and Secondary TACACS servers gt gt Main cfg sys tacacs Select the TACACS Server menu gt gt TACACS Server on Tur
118. ghest priority network traffic such as OSPF or RIP routing table updates priorities 5 6 are assigned to delay sensitive applications such as voice and video and lower priorities are assigned to standard applications value of O zero indicates a best effort traffic prioritization and this is the default when traffic priority has not been configured on your network The switch can filter packets based on the 802 1p values and it can assign or overwrite the 802 1p value in the packet Figure 13 Layer 2 802 1q 802 1p VLAN tagged packet Preamble T T T T T T T T T T T T T Priority VLAN Identifier VID 7 tes 4 ao 1 oly 6 54 3 2 10 Ingress packets receive a priority value as follows e Tagged packets the switch reads the 802 1p priority in the VLAN tag e Untagged packets the switch tags the packet and assigns an 802 1p priority based on the port s default priority cfg port x 8021ppri Egress packets are placed in a COS queue based on the priority value and scheduled for transmission based on the scheduling weight of the COS queue Use the cfg qos 8021p cur command to display the mapping between 802 1p values Class of Service queues COSq and COSq scheduling weights gt gt 802 1p cur Current priority to COS queue configuration Number of COSq 2 Priority COSq Weight 0 YouBRWNEHO PRePHOoOO Oo NNNNHFPHPH HB 99 Quality of Service 802 1p configuration CLI example
119. gt IGMP Filters gt Add Filter Open HP 10Gb Ethernet BL c Switch E System S Switch Ports Port Based Port Mirroring a Layer 2 fa RMON Menu Layer 3 a IP Interfaces a Default Gateways 5 IGMP ia IGMP Snooping 33 IGMP Filters Select hua Add Filter Eswitch Ports E IGMP Static Mrouter E Domain Name System b Far the IGMP Filter Ao the range of IP multicast addresses and the filter action allow or eny c Click Submit 126 IGMP Snooping 4 Assign the filter to a port and enable IGMP Filtering on the port a Select Layer 3 gt IGMP gt IGMP Filters gt Switch Ports Open HP 10Gb Ethernet BL c Switch E System G Switch Ports fa Port Based Port Mirrorin Ga Layer 2 RMON Menu Layer 3 1E IP Interfaces fa Default Gateways 5 IGMP 3 IGMP Snooping 53 IGMP Filters Add Add Filter Switch Ports IGMP Static Mrouter ElDomain Name System Select b Select a port from the list 127 IGMP Snooping c Enable IGMP Filtering on the port Select a filter in the IGMP Filters Available list and click Add lt lt Remove d Click Submit 5 Apply verify and save the configuration O STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save 128 IGMP Snooping Configuring a Static Multicast Router BBI example 1 Configure Static Mrouter a Click the Configure context button b Open t
120. guration changes gt gt OSPF Interface 2 apply Global command to apply all changes gt gt OSPF Interface 2 save Global command to save all changes Example 1 Simple OSPF domain BBI example 1 Configure IP interfaces on each network that will be attached to OSPF areas IF 1 IP address 10 10 7 1 Subnet mask 255 255 255 0 IF 2 IP address 10 10 12 1 Subnet mask 255 255 255 0 a Click the Configure context button 142 OSPF b Open the IP Interfaces folder and select Add IP Interface HP 10Gb Ethernet BL c Switch A System Switch Ports E Port Based Port Mirroring Ga Layer 2 RMON Menu 5 Layer3 Open ad IP Interfaces Select Add Add IP Interface c Configure an IP interface Enter the IP address subnet mask and enable the interface foo Enabled d Click Submit 2 Apply verity and save the configuration OD STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save 143 OSPF 3 Enable OSPF a Open the OSPF Routing Protocol folder and select General Open HP 10Gb Ethernet BL c Switch System a Switch Ports GA Port Based Port Mirroring Layer2 fa RMON Menu Layer 3 GA IP Interfaces i Network Routes fa Network Filters i Route Maps fa Default Gateways E IGMP OSPF Routing Protocol OSPF Areas i OSPF Summary Ranges fa OSPF Interfaces fo OSPF Virtual Links i
121. h of their neighbors and to establish contact with new neighbors The hello process is used for electing one of the neighbors as the area s Designated Router DR and one as the area s Backup Designated Router BDR The DR is adjacent to all other neighbors and acts as the central contact for database exchanges Each neighbor sends its database information to the DR which relays the information to the other neighbors The BDR is adjacent to all other neighbors including the DR Each neighbor sends its database information to the BDR just as with the DR but the BDR merely stores this data and does not distribute it If the DR fails the BDR will take over the task of distributing database information to the other neighbors Link State Database OSPF is a link state routing protocol A link represents an interface or routable path from the routing device By establishing an adjacency with the DR each routing device in an OSPF area maintains an identical Link State Database LSDB describing the network topology for its area Each routing device transmits a Link State Advertisement LSA on each of its interfaces LSAs are entered into the LSDB of each routing device OSPF uses flooding to distribute LSAs between routing devices When LSAs result in changes to the routing device s LSDB the routing device forwards the changes to the adjacent neighbors the DR and BDR for distribution to the other neighbors OSPF routing updates occur
122. h to collect RMON statistics gt gt cfg port 20 rmon gt gt Port 20 RMON ena gt gt Port 20 RMON apply gt gt Port 20 RMON save Select Port 20 RMON Enable RMON Make your changes active Save for restore after reboot 2 View RMON statistics for the port gt gt stats port 20 gt gt Port Statistics rmon RMON statistics for port 20 etherStatsDropEvents etherStatsOctets etherStatsPkts etherStatsBroadcastPkts etherStatsMulticastPkts etherStatsCRCAlignErrors etherStatsUndersizePkts etherStatsOversizePkts etherStatsFragments etherStatsJabbers etherStatsCollisions etherStatsPkts64Octets etherStatsPkts65tol1270ctets etherStatsPktsl28to2550ctets etherStatsPkts256to5llOctets etherStatsPkts512to10230ctets etherStatsPkts1024to015180ctets Select Port 20 Stats NA 7305626 48686 4380 6612 22 Configuring RMON Statistics BBI example 1 Configure ports a Click the Configure context button b Select Switch Ports click the underlined text not the folder Open HP 10Gb Ethernet BL c Switch System Select Switch Ports Port Based Port Mirroring G Layer 2 _ RMON Menu Layer 3 fl QoS Access Control Uplink Failure Detection 156 2 Select a port Remote monitoring 157 Remote monitoring 3 Enable RMON on the port Switch Port 20 Configuration Switch Port State RMON
123. he RADIUS server to authenticate and authorize a remote administrator using the protocol definitions specified in RFC 2138 and 2866 Transactions between the client and the RADIUS server are authenticated using a shared key that is not sent over the network In addition the remote administrator passwords are sent encrypted between the RADIUS client the switch and the back end RADIUS server How RADIUS authentication works RADIUS authentication works as follows 1 2 3 A remote administrator connects to the switch and provides the user name and password Using Authentication Authorization protocol the switch sends the request to the authentication server The authentication server checks the request against the user ID database Using RADIUS protocol the authentication server instructs the switch to grant or deny administrative access 21 Accessing the switch Configuring RADIUS on the switch CLI example To configure RADIUS on the switch do the following 1 Turn RADIUS authentication on and then configure the Primary and Secondary RADIUS servers For example gt gt Main cfg sys radius Select the RADIUS Server menu gt gt RADIUS Server on Turn RADIUS on Current status OFF New status ON gt gt RADIUS Server prisrv 10 10 1 1 Enter primary server IP Current primary RADIUS server 0 0 0 0 New pending primary RADIUS server 10 10 1 1 gt gt RADIUS Server secsrv 10 10 1 2 Enter secondary se
124. he Switch folder and select Layer 3 gt IGMP gt IGMP Static Mrouter gt Add Mrouter Open HP 10Gb Ethernet BL c Switch a Switch Ports GA Port Based Port Mirroring G RMON Menu 5 Layer 3 IP Interfaces fa Network Routes a Network Filters i Route Maps i Default Gateways 433 IGMP GA IGMP Snooping IGMP Filters IGMP Static Mrouter Select add Add Mrouter c Enter a port number VLAN ID number and IGMP version number Submit Delete d Click Submit 129 IGMP Snooping 2 Apply verity and save the configuration O STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save 130 OSPF The HP 10GbE switch software supports the Open Shortest Path First OSPF routing protocol The switch implementation conforms to the OSPF version 2 specifications detailed in Internet RFC 1583 The following sections discuss OSPF support for the HP 10GbE switch e OSPF Overview This section provides information on OSPF concepts such as types of OSPF areas types of routing devices neighbors adjacencies link state database authentication and internal versus external routing e OSPF Implementation in HP 1OGbE switch software This section describes how OSPF is implemented in switch software such as configuration parameters electing the designated router summarizing routes defining route maps and so forth e OSPF Configuratio
125. he backbone is partitioned possibly as a result of joining separate OSPF networks parts of the AS will be unreachable and you will need to configure virtual links to reconnect the partitioned areas see Virtual Links Up to three OSPF areas can be connected to the HP 10GbE switch To configure an area the OSPF number must be defined and then attached to a network interface on the switch The full process is explained in the following sections An OSPF area is defined by assigning two pieces of information an area index and an area ID The command to define an OSPF area is as follows gt gt cfg 13 ospf aindex lt area index gt areaid lt n n n n gt NOTE The aindex option above is an arbitrary index used only on the switch and does not represent the actual OSPF area number The actual OSPF area number is defined in the areaid portion of the command as explained in the following sections Assigning the area index The aindex lt area index gt option is actually just an arbitrary index 0 2 used only by the switch This index does not necessarily represent the OSPF area number though for configuration simplicity it should where possible For example both of the following sets of commands define OSPF area 0 the backbone and area 1 because that information is held in the area ID portion of the command However the first set of commands is easier to maintain because the arbitrary area indexes agree with the
126. her backdoor or secure backdoor enabled but not both at the same time The default value for backdoor access through the console port only is enabled You always can access the switch via the console port by using noradius and the administrator password whether backdoor secure backdoor are enabled or not The default value for backdoor and secure backdoor access through Telnet SSH HTTP HTIPS is disabled All user privileges other than those assigned to the administrator must be defined in the RADIUS dictionary RADIUS attribute 6 which is built into all RADIUS servers defines the administrator The file name of the dictionary is RADIUS vendor dependent The RADIUS attributes shown in the following table are defined for user privilege levels Table 3 Proprietary attributes for RADIUS User name access User service type Value User Vendor supplied 255 Operator Vendor supplied 252 TACACS authentication The switch software supports authentication authorization and accounting with networks using the Cisco Systems TACACS protocol The switch functions as the Network Access Server NAS by interacting with the remote client and initiating authentication and authorization sessions with the TACACS access server The remote user is defined as someone requiring management access to the switch either through a data or management port 25 Accessing the switch TACACS offers the following advantages over RADIUS e TACACS uses TCP ba
127. i e Type Data field is zero bytes in length this attribute will have the same value as the Calling Station Id 4 NAS IP Address IP address of the authenticator used for 1 0 0 0 RADIUS communication 5 NAS Port Port number of the authenticator port to which 1 0 0 0 the supplicant is attached 24 State Server specific value This is sent unmodified 0 1 0 1 0 1 0 back to the server in an Access Request that is in response to an Access Challenge 30 Called Station ID The MAC address of the authenticator 1 0 0 0 encoded as an ASCII string in canonical format e g 000D5622E3 9F 31 Calling Station ID The MAC address of the supplicant encoded 1 0 0 0 as an ASCII string in canonical format e g 000348436206 79 EAP Message Encapsulated EAP packets from the supplicant 1 1 1 1 to the authentication server Radius and vice versa The authenticator relays the decoded packet to both devices 80 Message Authenticator Always present whenever an EAP Message 1 1 1 1 attribute is also included Used to integrity protect a packet 87 NAS PortID Name assigned to the authenticator port e g 1 0 0 0 Server 1_Port3 Legend RADIUS Packet Types A R Access Request A A Access Accept A C Access Challenge A R Access Reject RADIUS Attribute Support O This attribute MUST NOT be present in a packet 0 Zero or more instances of this attribute MAY be present in a packet 0 1 Zero or one in
128. ication failure gt gt Main cfg ufd fdp ena Enable Failover Pair gt gt FDP ltm Select Link to Monitor menu gt gt Failover Link to Monitor addtrnk 2 Monitor trunk group 2 3 Assign downlink ports 1 16 to disable when an uplink failure occurs gt gt Main cfg ufd fdp ltd Select Link to Disable menu gt gt Failover Link to Disable addport 1 Add port 1 as a Link to Disable gt gt Failover Link to Disable addport 2 Add port 2 as a Link to Disable 4 Turn UFD on gt gt Main cfg ufd on Turn Uplink Failure Detection on gt gt Uplink Failure Detection apply Make your changes active gt gt Uplink Failure Detection save Save for restore after reboot When a link failure or Spanning Tree blocking occurs on trunk group 2 Blade Switch 2 disables port 1 and port 2 170 High availability Configuring Uplink Failure Detection BBI example 1 Configure Uplink Failure Detection a Click the Configure context button b T the Switch folder and select Uplink Failure Detection click the underlined text not the older Open S HP 10Gb Ethernet BL c Switch fa System GA Switch Ports GA Port Based Port Mirroring GA RMON Menu Qos G Access Control Select Uplink Failure Detection c Turn Uplink Failure Detection on and then select FDP 171 High availability d Enable the FDP Select ports in the LIM Ports Available list and click A
129. ices within the local area e Area Border Router ABR a router that has interfaces in multiple areas ABRs maintain one LSDB for each connected area and disseminate routing information between areos e Autonomous System Boundary Router ASBR a router that acts as a gateway between the OSPF domain and non OSPF domains such as RIP BGP and static routes Figure 18 OSPF domain and an autonomous system OSPF Autonomous System j Backbone re VE BGP I Dor Area ZS Pi Area 3 i Ve Nas vI Inter Area R i nter Area Routes 2 nN I External ASBR Summary Routes ABR Routes ioe PE 21 So N gt 7 RIP ae ee m Sg i I P ABR 5 ABR l I i l p Internal ASBR p A Router Na Areal _ Area2 4 132 OSPF Neighbors and adjacencies In areas with two or more routing devices neighbors and adjacencies are formed Neighbors are routing devices that maintain information about each others health To establish neighbor relationships routing devices periodically send hello packets on each of their interfaces All routing devices that share a common network segment appear in the same area and have the same health parameters hello and dead intervals and authentication parameters respond to each other s hello packets and become neighbors Neighbors continue to send periodic hello packets to advertise their health to neighbors In turn they listen to hello packets to determine the healt
130. icular group if the following conditions apply e If the switch does not receive an IGMP Membership Report message within the query response interval e f no multicast routers have been learned on that port With FastLeave enabled on the VLAN a port can be removed immediately from the port list of the group entry when the IGMP Leave message is received unless a multicast router was learned on the port Enable FastLeave only on VLANs that have only one host connected to each physical port 119 IGMP Snooping IGMP Filtering With IGMP Filtering you can allow or deny a port to send and receive multicast traffic to certain multicast groups Unauthorized users are restricted from streaming multicast traffic across the network If access to a multicast group is denied IGMP Membership Reports from the port for that group are dropped and the port is not allowed to receive IP multicast traffic from that group If access to the multicast group is allowed Membership Reports from the port are forwarded for normal processing To configure IGMP Filtering you must globally enable IGMP Filtering define an IGMP Filter assign the filter to a port and enable IGMP Filtering on the port To define an IGMP Filter you must configure a range of IP multicast groups choose whether the filter will allow or deny multicast traffic for groups within the range and enable the filter NOTE Low numbered filters take precedence over high number filters F
131. ient server protocol that has the following components e Supplicant or Client The Supplicant is a device that requests network access and provides the required credentials user name and password to the Authenticator and the Authentication Server e Authenticator The Authenticator enforces authentication and controls access to the network The Authenticator grants network access based on the information provided by the Supplicant and the response from the Authentication Server The Authenticator acts as an intermediary between the Supplicant and the Authentication Server requesting identity information from the client forwarding that information encapsulated in RADIUS packets to the Authentication Server for validation relaying the server s responses to the client and authorizing network access based on the results of the authentication exchange The HP 10GbE switch acts as an Authenticator e Authentication Server The Authentication Server validates the credentials provided by the Supplicant to determine if the Authenticator should grant access to the network The Authentication Server may be co located with the Authenticator The switch relies on external RADIUS servers for authentication Upon a successful authentication of the client by the server the 802 1x controlled port transitions from unauthorized to authorized state and the client is allowed full access to services through the port When the client sends an EAP Logoff mes
132. ing IGMP Snooping Configuration IGMP on Set report timeout Set multicast router timeout Set robust value or expected packet loss on subnet 2 Set query interval Aggregate IGMP report Flood unregistered IPMC Set Source IP for GSQ proxy Remove all VLAN s from IGMP Snooping IGMP V3 snooping on Set number of sources to snoop in GR Exclude viv2 Configured VLANs Snooping VLANs VLAN ID VLAN ID VLAN 1 VLANs without Fastleave VLANs with Fastleave VLAN ID VLAN ID VLAN 1 d Click Submit 3 Apply verify and save the configuration h nell TO ip CONFIGURE STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save 124 IGMP Snooping Configuring IGMP Filtering BBI example 1 Configure IGMP Snooping 2 Enable IGMP Filtering a Click the Configure context button b Open the IGMP folder and select IGMP Filters click the underlined text not the folder HP 10Gb Ethernet BL c Switch 9 System Switch Ports Port Based Port Mirroring i Layer 2 RMON Menu Layer 3 IP Interfaces Default Gateways Open IGMP Snooping 0 IGMP Filters Select 1 IGMP Static Mrouter E Domain Name System c Enable IGMP Filtering globally Enabled d Click Submit 125 IGMP Snooping 3 Define the IGMP Filter a Select Layer 3 gt IGMP
133. ing Authentication password then it is necessary to enter an authentication key value The following method is used to authenticate a RIP message e Ifthe router is not configured to authenticate RIPv2 messages then RIPv1 and unauthenticated RIPv2 messages are accepted authenticated RIPv2 messages are discarded e If the router is configured to authenticate RIPv2 messages then RIPv1 messages and RIPv2 messages which pass authentication testing are accepted unauthenticated and failed authentication RIPv2 messages are discarded For maximum security RIPv messages are ignored when authentication is enabled cfg 13 rip if x auth password otherwise the routing information from authenticated messages is propagated by RIPv1 routers in an unauthenticated manner 116 Routing Information Protocol RIP configuration example NOTE An interface RIP disabled uses all the default values of the RIP no matter how the RIP parameters are configured for that interface RIP sends out RIP regular updates to include an Up interface but not a Down interface 1 Add VLANs for routing interfaces gt gt Main cfg 12 vlan 2 ena Enable VLAN 2 gt gt VLAN 2 add 20 Add port 20 to VLAN 2 Port 20 is an UNTAGGED port and its current PVID is 1 Confirm changing PVID from 1 to 2 y n y gt gt VLAN 2 cfg 12 vlan 3 ena Enable VLAN 3 gt gt VLAN 3 add 21 Add port 21 to VLAN 3 Port 21 is an UNTAGGED port and its current PVID is 1
134. ing the switch Table 2 User access levels User account Description and tasks performed Administrator Administrators are the only ones that can make permanent changes to the switch configuration changes that are persistent across a reboot reset of the switch Administrators can access switch functions to configure and troubleshoot problems on the switch level Because administrators can also make temporary operator level changes as well they must be aware of the interactions between temporary and permanent changes RADIUS attributes for user privileges When the user logs in the switch authenticates the level of access by sending the RADIUS access request that is the client authentication request to the RADIUS authentication server If the authentication server successfully authenticates the remote user the switch verifies the privileges of the remote user and authorizes the appropriate access The administrator has the option to allow backdoor access through the console port only or through the console and Telnet SSH HTTP HTTPS access When backdoor access is enabled access is allowed even if the primary and secondary authentication servers are reachable Only when both the primary and secondary authentication servers are not reachable the administrator has the option to allow secure backdoor secbd access through the console port only or through the console and Telnet SSH HTTP HTTPS access When RADIUS is on you can have eit
135. inks so that the route with the lowest cost is chosen value of zero indicates that port cost is computed dynamically based on link speed This works when forcing link speed so it does not just apply to auto negotiated link speed By default all switch ports have the path cost set to 2 To use dynamic path cost based on link speed set the path cost to 0 zero For example if the path cost is set to zero e A10 Gbps link receives a path cost of 2 e A100 Mbps link receives a path cost of 19 Configure the port path cost using the following command cfg 12 stp y port x cost Spanning Tree Group configuration guidelines This section provides important information on configuring Spanning Tree Groups STGs Default Spanning Tree configuration In the default configuration a single STG with the ID of 1 includes all ports on the switch It is called the default STG All other STGs except the default STG are empty and VLANs must be added by the user You cannot assign ports directly to an STG Add the ports to a VLAN and add the VLAN to the STG STGs 1 127 are enabled by default and assigned an ID number from 1 to 127 STG 128 is disabled by default and contains the management VLAN 4095 An STG cannot be deleted only disabled If you disable the STG while it still contains VLAN members Spanning Tree will be off on all ports belonging to that VLAN 69 Spanning Tree Protocol Adding a VLAN to a Spanning Tree Group If no VL
136. ion gt gt cfg dump Verify the configuration Using the Browser based Interface By default the Browser based Interface BBI protocol is enabled on the switch The Browser based Interface BBI provides access to the common configuration management and operation features of the switch through your Web browser For more information see the HP 10Gb Ethernet BL c Switch Browser based Interface Reference Guide The BBI is organized at a high level as follows Configuration These menus provide access to the configuration elements for the entire switch o System Configure general switch configuration elements o Switch ports Configure switch ports and related features o Port based port mirroring Configure mirrored ports and monitoring ports o Layer 2 Configure Layer 2 features including trunk groups VLANs and Spanning Tree Protocol o RMON menu Configure Remote Monitoring RMON functions o Layer 3 Configure all of the IP related information including IGMP Snooping o QoS Configure Quality of Service features o Access Control Configure Access Control Lists and Groups o Uplink Failure Detection Configure a Failover Pair of Links to Monitor and Links to Disable Statistics These menus provide access to the switch statistics and state information Dashboard These menus display settings and operating status of a variety of switch features 13 Accessing the switch Using Simple Network
137. ion on configuring IP interfaces see the Configuring an IP interface section in the Accessing the switch chapter VLAN topologies and design considerations By default all switch ports are configured to the default VLAN 1 This configuration groups all ports into the same broadcast domain The VLAN has an 802 1Q VLAN ID of 1 VLAN tagging is turned off because by default all ports are members of a single VLAN only If configuring Spanning Tree Protocol cfg 12 stp note that each of spanning tree groups 2 128 may contain only one VLAN If configuring Multiple Spanning Tree Protocol cfg 12 mrst each of the spanning tree groups 1 32 for MSTP may contain multiple VLANs 58 VLANs VLAN configuration rules VLANs operate according to specific configuration rules which must be considered when creating VLANs For example HP recommends that all ports involved in trunking and Port Mirroring have the same VLAN configuration If a port is on a trunk with a mirroring port the VLAN configuration cannot be changed For more information on port trunking see the Port trunking example section in the Ports and trunking chapter All ports involved in Port Mirroring must have memberships in the same STP group but they can have memberships in different VLANs When you delete a VLAN untagged ports are moved to the default VLAN VLAN 1 Tagged ports that belong only to the deleted VLAN are moved to the default VLAN 1 T
138. ivpw admin configure the group s access level admin admin Configure user type Configure a user access group along with the views the group may access Use the access table to gt gt cfg sys ssnmp snmpv3 access 5 SNMPv3 SNMPv3 SNMPv3 SNMPv3 SNMPv3 gt gt gt gt gt gt gt gt gt gt vacmAccess vacmAccess vacmAccess vacmAccess vacmAccess 5 5 5 5 5 name admingrp level rview wview nview Configure an access group authPriv iso iso iso Because the read view rview write view wview and notify view nview are all set to iso the user type has access to all private and public MIBs Assign the user to the user group Use the group table to link the user to a particular access group gt gt cfg sys ssnmp snmpv3 group 5 gt gt SNMPv3 vacmSecurityToGroup 5 uname admin gt gt SNMPv3 vacmSecurityToGroup 5 gname admingrp If you want to allow user access only to certain MIBs see the View based configurations section 15 Accessing the switch View based configurations CLI user equivalent To configure an SNMP user equivalent to the CLI user use the following configuration c sys ssnmp snmpv3 usm 4 name usr Configure the user c sys ssnmp snmpv3 access 3 name usrgrp Configure access group 3 rview usr wview usr nview usr c sys ssnmp snmpv3 group 4 Assign user to access group
139. known as external routing Typically an AS will have one or more border routers peer routers that exchange routes with other OSPF networks as well as an internal routing system enabling every router in that AS to reach every other router and destination within that AS When a routing device advertises routes to boundary routers on other autonomous systems it is effectively committing to carry data to the IP space represented in the route being advertised For example if the routing device advertises 192 204 4 0 24 it is declaring that if another router sends data destined for any address in the 192 204 4 0 24 range it will carry that data to its destination OSPF implementation in HP TOGbE switch software The HP 10GbE switch supports a single instance of OSPF and up to 4 K routes on the network The following sections describe OSPF implementation in switch software e Configurable Parameters e Defining Areas e Interface Cost e Electing the Designated Router and Backup e Summarizing Routes e Default Routes e Virtual Links e Router ID e Authentication Configurable parameters In HP 10GbE switch software OSPF parameters can be configured through the Command Line Interface CLI Browser Based Interface BBI for HP 1OGbE switches or through SNMP For more information see Accessing the Switch The CLI supports the following parameters interface output cost interface priority dead and hello intervals
140. l Local Area Networks VLANs configured on the switch Routing between IP subnets The physical layout of most corporate networks has evolved over time Classic hub router topologies have given way to faster switched topologies particularly now that switches are increasingly intelligent HP 10GbE switches are intelligent and fast enough to perform routing functions on a par with wire speed Layer 2 switching The combination of faster routing and switching in a single device provides another service it allows you to build versatile topologies that account for legacy configurations 106 Basic IP routing For example consider the following topology migration Figure 14 Router legacy network d D Admin Sales Eng Staff2 Sales Staff Eng2 Admin Subnet Hub Eng Subnet Hub Staff Subnet Server Subnet Internet P HP Blade Chassis In this example a corporate campus has migrated from a router centric topology to a faster more powerful switch based topology As is often the case the legacy of network growth and redesign has left the system with a mix of illogically distributed subnets This is a situation that switching alone cannot cure Instead the router is flooded with cross subnet communication This compromises efficiency in two ways e Routers can be slower than switches The cross subnet side trip from the switch to the router and back again adds two hops for the da
141. listens to the BPDUs to learn if there is a loop and if dictated by normal STG behavior following priorities etc the port transitions into the Blocking state This feature permits the switch to interoperate well with Fast Path a NIC Teaming feature Configuring Port Fast Forwarding Use the following CLI commands to enable Port Fast Forwarding on an external port gt gt cfg l2 stp 1 port 20 Select port 20 gt gt Spanning Tree Port 20 fastfwd ena Enable Port Fast Forwarding gt gt Spanning Tree Port 20 apply Make your changes active Save for restore after reboot gt gt Spanning Tree Port 20 save Fast Uplink Convergence Fast Uplink Convergence enables the switch to quickly recover from the failure of the primary link or trunk group in a Layer 2 network using Spanning Tree Protocol Normal recovery can take as long as 60 seconds while the backup link transitions from Blocking to Listening to Learning and then Forwarding states With Fast Uplink Convergence enabled the switch immediately places the secondary path into Forwarding state and sends multicasts of addresses in the forwarding database FDB and ARP table over the secondary link so that upstream switches can learn the new path Configuration guidelines When you enable Fast Uplink Convergence the switch software automatically makes the following configuration changes e Increases the bridge priority to 65500 so that it does not become the root s
142. ly from one machine to another SCP uses SSH for encryption of data on the network On a switch SCP is used to download and upload the switch configuration via secure channels By default SCP is disabled on the switch 30 Accessing the switch The switch implementation of SSH is based on version 1 5 and version 2 0 and supports SSH clients from version 1 0 through version 2 0 Client software can use SSH version 1 or version 2 The following SSH clients are supported SSH 3 0 1 for Linux freeware SecureCRT 4 1 8 VanDyke Technologies Inc OpenSSH_3 9 for Linux FC 3 FedoraCore 3 for SCP commands PuTTY Release 0 58 Simon Tatham for Windows Configuring SSH and SCP features CLI example Before you can use SSH commands use the following commands to turn on SSH and SCP Enabling or disabling SSH To enable the SSH feature connect to the switch CLI and enter the following commands gt gt cfg sys sshd on Turn SSH on Current status OFF New status ON SSHD apply Apply the changes to start generating RSA host and server keys RSA host key generation starts RSA host key generation completes lasts 212549 ms RSA host key is being saved to Flash ROM please don t reboot the box immediately RSA server key generation starts RSA server key generation completes lasts 75503 ms RSA server key is being saved to Flash ROM please don t reboot the box immediately Apply complete don t forget to
143. m one STG to another move the VLAN to which the port belongs or move the port to a VLAN that belongs to the STG e When you remove a port from a VLAN that port is also removed from the STG to which the VLAN belongs However if that port belongs to another VLAN in the same STG the port remains in the STG e If you remove an untagged port from a non default VLAN and STG it is added to VLAN 1 and STG 1 70 Spanning Tree Protocol The relationship between ports trunk groups VLANs and spanning trees is shown in the following table Table 11 Ports trunk groups and VLANs Switch element Belongs to Port Trunk group or one or more VLANs Trunk group Only one VLAN VLAN non default One Spanning Tree Group Assigning cost to ports and trunk groups When you configure a trunk group to participate in a Spanning Tree Group all ports must have the same Spanning Tree configuration as follows e port priority e path cost e link type e Edge port status e Port Fast Forward status Assign lower path costs on each member of a trunk group to ensure the trunk group remains in the Forwarding state Multiple Spanning Trees Each switch supports a maximum of 128 Spanning Tree Groups STGs Multiple STGs provide multiple data paths which can be used for load balancing and redundancy You enable independent links on two switches using multiple STGs by configuring each path with a different VLAN and then assigning
144. mary routes can be defined for up to 16 IP address ranges using the following command gt gt cfig 13 ospf range lt range number gt addr lt IP address gt mask lt mask gt where lt range number gt is a number 1 to 16 lt IP address is the base IP address for the range and lt mask gt is the IP address mask for the range Default routes When an OSPF routing device encounters traffic for a destination address it does not recognize it forwards that traffic along the default route Typically the default route leads upstream toward the backbone until it reaches the intended area or an external router Each switch acting as an ABR automatically inserts a default route into each attached area In simple OSPF stub areas or NSSAs with only one ABR leading upstream see Area 1 in the figure below any traffic for IP address destinations outside the area is forwarded to the switch s IP interface and then into the connected transit area usually the backbone Since this is automatic no further configuration is required for such areas Figure 19 Injecting default routes Stub Area Backbone Stub Area ope s 7 Arao MA Area2 gt 7 a s By p RO i Priority IF 1 3 p I Default i Route Priority Default Default Route Route N N A yw j a A p d ASBR to External Networks HP Blade Chassis HP Blade Chassis 137 OSPF In more complex OSPF areas with multiple ABRs or
145. me or value when using the Read your user guide thoroughly command Do not type the brackets Command items shown inside brackets are optional and host Is a can be used or excluded as the situation demands Do not type the brackets Management Network The 10Gb Ethernet BL c Switch is an integral subsystem within the overall BladeSystem The BladeSystem chassis includes an Onboard Administrator as the central element for overall chassis and control The 1OGbE switch communicates with the Onboard Administrator through its internal management port port 17 The factory default settings permit management and control access to the switch through the 10 100 Mbps Ethernet port on the Onboard Administrator or the built in console port You also can use the external Ethernet ports to manage and control the 1OGbE switch The 10GbE switch management network has the following characteristics Port 17 Management port 17 has a fixed configuration as follows O S O Oo 100 Mbps Full duplex Flow control both No auto negotiation Accessing the switch o Untagged o Port VLAN ID PVID 4095 VLAN 4095 Management VLAN 4095 isolates management traffic within the HP 1OGbE switch VLAN 4095 contains only one member port port 17 No other ports can be members of VLAN 4095 e Interface 250 Management interface 250 is associated with VLAN 4095 No other interfaces can be associated with VIAN 4095 You can configure th
146. mmand ping lt host name gt lt IP address gt attempts 1 32 msec delay m mgt d data The IP address is the hostname or IP address of the device The number of attempts is optional Msec delay optional is the number of milliseconds between attempts By default the m or mgt option for the management port is used To use data ports specify the d or data option Trace route To identity the route used for station to station connectivity across the network execute the following command traceroute lt host name gt lt IP address gt lt max hops gt msec delay The IP address is the hostname or IP address of the target station Max hops optional is the maximum distance to trace 1 32 devices Msec delay optional is the number of milliseconds to wait for the response Statistics and state information The switch keeps track of a large number of statistics and many of these are error condition counters The statistics and state information can be very useful when troubleshooting a LAN or Real Server problem For more information about available statistics see one of the following e Viewing statistics chapter of the HP 10Gb Ethernet BL c Switch Browser based Interface Reference Guide or e Statistics Menu chapter of the HP 10Gb Ethernet Bl c Switch Command Reference Customer support tools The following diagnostics tools are not user configurable and should be performed through HP technical su
147. mplementation does not support the Churn machine an option used to detect if the port is operable within a bounded time period between the actor and the partner Only the Market Responder is implemented and there is no marker protocol generator A port s Link Aggregation Identifier LAG ID determines how the port can be aggregated The Link Aggregation ID LAG ID is constructed mainly from the system ID and the port s admin key as follows e System ID The system ID is an integer value based on the switch s MAC address and the system priority assigned in the CLI e Admin key A port s admin key is an integer value 1 65535 that you can configure in the CLI Each HP 10GbE switch port that participates in the same LACP trunk group must have the same admin key value The admin key is local significant which means the partner switch does not need to use the same admin key value For example consider two switches an Actor the HP 10GbE switch and a Partner another switch as shown in the following table Table 8 Actor vs partner LACP configuration Actor Switch Partner Switch 1 Partner Switch 2 Port 18 admin key 100 Port 1 admin key 50 Port 19 admin key 100 Port 2 admin key 50 Port 20 admin key 200 Port 3 admin key 60 Port 21 admin key 200 Port 4 admin key 60 44 Ports and trunking In the configuration shown in the table above Actor switch ports 18 and 19 aggregate to form an
148. mpv3 access lt x gt level c sys ssnmp snmpv3 tparam lt x gt Configure the user in the user table to match the configuration of the access table It is not necessary to configure the community table for SNMPv3 traps because the community string is not used by SNMPv3 19 Accessing the switch The following example shows how to configure a SNMPv3 user v3t rap with authentication only c sys ssnmp snmpv3 usm 11 Configure user named v3trap name v3trap auth md5 authpw v3trap c sys ssnmp snmpv3 access 11 access group to view SNMPv3 traps name v3trap level authNoPriv nview iso c sys ssnmp snmpv3 group 11 Assign user to the access group uname v3trap gname v3trap c sys ssnmp snmpv3 notify 11 Assign user to the notify table name v3trap tag v3trap c sys ssnmp snmpv3 taddr 11 Define an IP address to send traps name v3trap addr 47 81 25 66 taglist v3trap pname v3param c sys ssnmp snmpv3 tparam 11 Specify SNMPv3 traps to send name v3param uname v3trap level authNoPriv Set the authentication level For more information on using SNMP see the HP 10Gb Ethernet Bl c Switch Command Reference Guide See the HP 10Gb Ethernet BL c Switch User Guide for a complete list of supported MIBs Secure access to the switch Secure switch management is needed for environments that perform significant management functions across the Internet The following are some of the functions for secured management e Limiting ma
149. n Examples This section provides step by step instructions on configuring different configuration examples o Creating a simple OSPF domain o Creating virtual links o Summarizing routes OSPF overview OSPF is designed for routing traffic within a single IP domain called an Autonomous System AS The AS can be divided into smaller logical units known as areas All routing devices maintain link information in their own Link State Database LSDB The LSDB for all routing devices within an area is identical but is not exchanged between different areas Only routing updates are exchanged between areas thereby significantly reducing the overhead for maintaining routing information on a large dynamic network The following sections describe key OSPF concepts Types of OSPF areas An AS can be broken into logical units known as areas In any AS with multiple areas one area must be designated as area 0 known as the backbone The backbone acts as the central OSPF area All other areas in the AS must be connected to the backbone Areas inject summary routing information into the backbone which then distributes it to other areas as needed OSPF defines the following types of areas e Stub Area an area that is connected to only one other area External route information is not distributed into stub areas e Not So Stubby Area NSSA similar to a stub area with additional capabilities External routes from outside the AS can be adverti
150. n TACACS on Current status OFF New status ON gt gt TACACS Server prisrv 10 10 1 1 Enter primary server IP Current primary TACACS server 0 0 0 0 New pending primary TACACS server 10 10 1 1 gt gt TACACS Server secsrv 10 10 1 2 Enter secondary server IP Current secondary TACACS server 0 0 0 0 New pending secondary TACACS server 10 10 1 2 2 Configure the TACACS secret and second secret gt gt TACACS Server secret Enter new TACACS secret lt 1 32 character secret gt gt gt TACACS Server secret2 Enter new TACACS second secret lt 1 32 character secret gt A CAUTION If you configure the TACACS secret using any method other than a direct console connection the secret may be transmitted over the network as clear text 3 If desired you may change the default TCP port number used to listen to TACACS The well known port for TACACS is 49 gt gt TACACS Server port Current TACACS port 49 Enter new TACACS port 1 65000 lt TCP port number gt 4 Configure the number retry attempts for contacting the TACACS server and the timeout period gt gt TACACS Server retries Current TACACS server retries 3 Enter new TACACS server retries 1 3 2 gt gt TACACS Server time Current TACACS server timeout 5 Enter new TACACS server timeout 4 15 10 Enter the timeout period in minutes 5 Configure custom privilege level mapping optional
151. n untagged member of VLAN 2 57 VLANs Figure 7 802 1Q tagging after 802 1Q tag assignment PVID 2 Port 1 Port2 Porta A ONAN wo 802 10 Switch CRC Data SA pa O gt a Port 6 Port7 Ports AE Port 4 eg en CRC Recalculated 8100 Priority CFI VID 2 o 16 bits 3 bits 1bit 12 bits Data Outgoing After SA untagged packet changed Key DA tag removed Priority User_priority St CFI Canonical format indicator VID VLAN identifier BS45014A NOTE Using the boot conf factory command resets all ports to VLAN 1 except management port 17 and all other settings to the factory defaults at the next reboot VLANs and IP interfaces Carefully consider how you create VLANs within the switch so that communication with the switch remains possible In order to access the switch for remote configuration trap messages and other management functions be sure that at least one IP interface on the switch has a VLAN defined You can also inadvertently cut off access to management functions if you exclude the ports from the VLAN membership For example if all IP interfaces are left on VLAN 1 the default and all ports are configured for VLAN 2 and then switch management features are effectively cut off To remedy this keep all ports used for remote switch management on the default VLAN and assign an IP interface to the default VLAN For more informat
152. nabled on the switch all subsequent SSH authentication requests will be redirected to the specified RADIUS or TACACS servers for authentication The redirection is transparent to the SSH clients User access control The switch allows an administrator to define end user accounts that permit end users to perform limited actions on the switch Once end user accounts are configured and enabled the switch requires username password authentication For example an administrator can assign a user who can log into the switch and perform operational commands effective only until the next switch reboot The administrator defines access levels for each switch user as shown in the following table Table 6 User access levels User account Description Password Administrator The Administrator has complete access to all menus information and admin configuration commands on the switch including the ability to change both the user and administrator passwords Operator The Operator manages all functions of the switch The Operator can reset oper ports or the entire switch User The User has no direct responsibility for switch management user Users can view all switch status information and statistics but cannot make any configuration changes to the switch Passwords can be up to 128 characters in length for TACACS Telnet SSH console and BBI access When RADIUS authentication is used the maximum password length is 32 characters
153. nagement users to a specific IP address range See the Setting allowable source IP address ranges section in this chapter e Authentication and authorization of remote administrators See the RADIUS authentication and authorization section or the TACACS authentication section both later in this chapter e Encryption of management information exchanged between the remote administrator and the switch See the Secure Shell and Secure Copy section later in this chapter Setting allowable source IP address ranges To limit access to the switch without having to configure filters for each switch port you can set a source IP address or range that will be allowed to connect to the switch IP interface through Telnet SSH SNMP or the switch browser based interface BBI When an IP packet reaches the application switch the source IP address is checked against the range of addresses defined by the management network and management mask If the source IP address of the host or hosts is within this range it is allowed to attempt to log in Any packet addressed to a switch IP interface with a source IP address outside this range is discarded 20 Accessing the switch Configuring an IP address range for the management network In this example the management network is set to 192 192 192 0 and management mask is set to 255 255 255 128 This defines the following range of allowed IP addresses 192 192 192 1 to 192 192 192
154. ndwidth of the interface Low cost indicates high bandwidth You can manually enter the cost for the output route with the following command gt gt cfg 13 ospf if lt OSPF interface number gt cost lt cost value 1 65535 gt 136 OSPF Electing the designated router and backup In any area with more than two routing devices a Designated Router DR is elected as the central contact for database exchanges among neighbors and a Backup Designated Router BDR is elected in case the DR fails DR and BDR elections are made through the hello process The election can be influenced by assigning a priority value to the OSPF interfaces on the switch The command is as follows gt gt cfig 13 ospf if lt OSPF interface number gt prio lt priority value 0 255 gt A priority value of 255 is the highest and 1 is the lowest A priority value of O specifies that the interface cannot be used as a DR or BDR In case of a tie the routing device with the lowest router ID wins Summarizing routes Route summarization condenses routing information Without summarization each routing device in an OSPF network would retain a route to every subnet in the network With summarization routing devices can reduce some sets of routes to a single advertisement reducing both the load on the routing device and the perceived complexity of the network The importance of route summarization increases with network size Sum
155. ned to a contiguous subnet range you can configure the ABR to advertise a single summary route that includes all the individual IP addresses within the area The following example shows one summary route from area 1 stub area injected into area 0 the backbone The summary route consists of all IP addresses from 36 128 192 0 through 36 128 254 255 except for the routes in the range 36 128 200 0 through 36 128 200 255 152 OSPF Figure 23 Summarizing routes ckbon Stub Ar 7 Area0 TN Pen e 0 0 0 0 0 0 0 1 IF 1 ABR Summary A JOGDE 36 128 192 x to 2 Route 36 128 254 x va S 10 10 7 0 24 MN 36 128 192 018 7 36 128 192 1 Ill Network ee SEE x _ Network 7 mans 10GbE HP Blade Chassis NOTE You can specify a range of addresses to prevent advertising by using the hide option In this example routes in the range 36 128 200 0 through 36 128 200 255 are kept private Follow this procedure to configure OSPF support on Switch A and Switch B as shown in the figure 1 Configure IP interfaces for each network which will be attached to OSPF areas gt gt cfg 13 if 1 Select menu for IP interface 1 gt gt IP Interface 1 addr 10 10 7 1 Set IP address on backbone network mask 255 255 255 0 Set IP mask on backbone network ena Enable IP interface 1 if 2 Select menu for IP interface 2 addr 36 128 192 1 Set IP address on stub area network mask 255 255 192 0 Se
156. ng Tree gt gt cfg 12 mrst Select Multiple Spanning Tree menu gt gt Multiple Spanning Tree mode rstp Set mode to Rapid Spanning Tree gt gt Multiple Spanning Tree on Turn Rapid Spanning Tree on 3 Apply and save the changes gt gt apply Apply the configuration gt gt save Save the configuration 78 RSTP and MSTP Configuring Rapid Spanning Tree Protocol BBI example 1 Configure port and VLAN membership on the switch as described in the Configuring ports and VLANs BBI example section in the VLANs chapter of this guide 2 Configure RSTP general parameters a Click the Configure context button on the Toolbar b Open the MSTP RSTP folder and select General HP 10Gb Ethernet BL c Switch GM System GM Switch Ports GA Port Based Port Mirroring Layer 2 Ga 8021x GA Virtual LANs Spanning Tree Groups MSTP RSTP Select BICIST Bridge BICIST Ports 2 Trunk Groups 2 Trunk Hash BLACP BUpLink Fast c Select RSTP mode and set the MSTP RSTP state to ON d Click Submit 79 RSTP and MSTP 3 Apply verify and save the configuration h T j ONFIGURE STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save Multiple Spanning Tree Protocol IEEE 802 1s Multiple Spanning Tree extends the IEEE 802 1w Rapid Spanning Tree Protocol through multiple Spanning Tree Groups MSTP maintains u
157. ning Tree Groups rrrererrrrrannnnnnrannnverrvenerernrenerenrsvensrnrrvenssnrsevenersserenessssee 72 Configuring Multiple Spanning Tree Groums scsase2 50 sescsa sedasqcegssascntewadessenar rset tt atang peanosenaareentadeenaes 73 Configuring Switch 1 CLI example ve 73 ere Switch HE rer 73 Configuring Switch 1 BBI example vvs ahstedls aster cae ciha akg Aahoeed aden da 74 Port Fast Forwarding EE pene yeu rer CREPE tre ie SE reer terere renee 76 Configuring Port Fast Free tansy EEEE 76 Fast Uplink Convergen e miiarnne earne EE E E E E EE OTEA 76 Contiguration guidelines sises caties eiiis eE E O EEE E E E E e NEN E EEEE 76 Configuring Fast Veke 76 RSTP and MSTP 211310 Ge eg EE ER a S EE 77 Rapid Spanning Tree Frotosoln uarandnununminsnunnvvnnmernn intimt 77 TE Ge EE EE EE ER ee rmeeeeaan 77 Port type and link type rororrnorsrnrnrrvrnnrrnvarrrnnnrrrnnnrennnrrrnnnnesnnnrrsnnrrrrnnnrnnnrrsnnnnrnnnnernnrrsnnnnrnnnnnern sner 78 Edje po EEE EE REN EE SET 78 Dev 78 RSTP configuration guidelines une 78 RSTP configuration example lt s c 2 260s s saecaussareasabnacacaiatsacansancsanassascceassseassabesadedansbendnsebecedeiansbananebecaniad 78 Configuring Rapid Spanning Tree CLI example 0 ccceeceeeseeseeeeeeeeeesseeesneeeseeseeesnteseeeseesttesaes 78 Configuring Rapid Spanning Tree Protocol BBI example cccccecceceeteeeeneeceneeeenseeeseaeeeeteeeeneaeees 79 Multiple Spanning Tree Protocol sic idscasibssancstestasvaakssa
158. nning Treet mode mstp Set mode to Multiple Spanning Trees gt gt Multiple Spanning Treet on Turn Multiple Spanning Trees on gt gt Multiple Spanning Treet name xxxxxx Define the Region name gt gt Multiple Spanning Tree rev xx Define the Region revision level gt gt cfg l2 stp 2 Select Spanning Tree Group 2 gt gt Spanning Tree Group 2 add 2 Add VLAN 2 gt gt Spanning Tree Group 2 apply Apply the configurations 81 RSTP and MSTP Configuring Multiple Spanning Tree Protocol BBI example 1 Configure port and VLAN membership on the switch as described in the Configuring ports and VLANs BBI example section in the VLANs chapter of this guide 2 Configure MSTP general parameters a Click the Configure context button on the Toolbar b Open the MSTP RSTP folder and select General HP 10Gb Ethernet BL c Switch GM System GM Switch Ports GA Port Based Port Mirroring Layer 2 G 802 1x Virtual LANs Spanning Tree Groups MSTP RSTP General 2 Trunk Groups E Trunk Hash BLACP BUpLink Fast c Enter the region name and revision level Select MSTP mode and set the MSTP RSTP state to ON Nene fmyregon Submit Default CIST d Click Submit 82 RSTP and MSTP 3 Configure Common Internal Spanning Trees CIST bridge parameters a Open the MSTP RSTP folder and select CIST Bridge Open HP 10Gb Ethernet BL c Switch System i Switch
159. nually configured trunk group e Dynamic LACP trunk group The trunk group supports the FDB static entry If the port with the static entry fails other ports in the trunk handle the traffic If the port is removed from the trunk the static entry is removed from the trunk but remains configured on the port The FDB information commands info 12 fdb display trunk support for static FDB entries if applicable gt gt Forwarding Database dump MAC address VLAN Port Trnk State I 21 21 21 Configuring a static FDB entry Perform the following actions to configure a static FDB entry Main cfg 12 fdb static Select static FDB menu gt gt Static FDBH add 00 60 af 00 02 30 Enter VLAN number 2 Enter port 1 21 2 gt gt Static FDB apply Apply the configuration gt gt Static FDB save Save the configuration 67 Spanning Tree Protocol Introduction When multiple paths exist on a network Spanning Tree Protocol STP configures the network so that a switch uses only the most efficient path The following topics are discussed in this chapter e Overview e Bridge Protocol Data Units BPDUs e Spanning Tree Group STG configuration guidelines e Multiple Spanning Trees Overview Spanning Tree Protocol STP detects and eliminates logical loops in a bridged or switched network STP forces redundant data paths into a standby blocked state When multiple paths exist STP configures the net
160. o a device or gain access to its services Switch software supports ASCII inbound login to the device PAP CHAP and ARAP login methods TACACS change password requests and one time password authentication are not supported Authorization Authorization is the action of determining a user s privileges on the device and usually takes place after authentication The default mapping between TACACS authorization privilege levels and switch management access levels is shown in the table below The privilege levels listed in the following table must be defined on the TACACS server Table 4 Default TACACS privilege levels User access level TACACS level user 0 oper 3 admin 6 Accessing the switch Alternate mapping between TACACS privilege levels and HP 10GbE switch management access levels is shown in the table below Use the command cfg sys tacacs cmap ena to use the alternate TACACS privilege levels Table 5 Alternate TACACS privilege levels User access level TACACS level user 0 1 oper 6 8 admin 14 15 You can customize the mapping between TACACS privilege levels and HP 10GbE switch management access levels Use the command cfg sys tacacs usermap to manually map each TACACS privilege level 0 15 to a corresponding HP 10GbE switch management access level user oper admin none If the remote user is authenticated by the authentication server the HP 10GbE switch verifies the privile
161. o three retries The switch will also automatically retry connecting to the RADIUS server before it declares the server down e Supports user configurable RADIUS application port The default is 1645 User Datagram Protocol UDP based on RFC 2138 Port 1812 is also supported e Allows network administrator to define privileges for one or more specific users to access the switch at the RADIUS user database e Allows the administrator to configure RADIUS backdoor and secure backdoor for Telnet SSH HTTP and HTTPS access User accounts for RADIUS users The user accounts listed in the following table can be defined in the RADIUS server dictionary file Table 2 User access levels User account Description and tasks performed User User interaction with the switch is completely passive nothing can be changed on the switch Users may display information that has no security or privacy implications such as switch statistics and current operational state information Operator Operators can only effect temporary changes on the switch These changes are lost when the switch is rebooted reset Operators have access to the switch management features used for daily switch operations Because any changes an operator makes are undone by a reset of the switch operators cannot severely impact switch operation but do have access to the Maintenance menu By default the operator account is disabled and has no password 24 Access
162. only when changes occur instead of periodically For each new route if an adjacency is interested in that route for example if configured to receive static routes and the new route is indeed static an update message containing the new route is sent to the adjacency For each route removed from the route table if the route has already been sent to an adjacency an update message containing the route to withdraw is sent Shortest Path First Tree The routing devices use a link state algorithm Dijkstra s algorithm to calculate the shortest path to all known destinations based on the cumulative cost required to reach the destination The cost of an individual interface in OSPF is an indication of the overhead required to send packets across it The cost is inversely proportional to the bandwidth of the interface A lower cost indicates a higher bandwidth 133 OSPF Internal versus external routing To ensure effective processing of network traffic every routing device on your network needs to know how to send a packet directly or indirectly to any other location destination in your network This is referred to as internal routing and can be done with static routes or using active internal routing protocols such as OSPF RIP or RIPv2 It is also useful to tell routers outside your network upstream providers or peers about the routes you have access to in your network Sharing of routing information between autonomous systems is
163. ools 195 D default gateway configuration example 13 109 Differentiated Services Code Point DSCP DSCP 97 Dynamic Host Configuration Protocol 112 E EAPoL configuration guidelines 51 EtherChannel as used with port trunking 38 Extensible Authentication Protocol over LAN EAPoL EAPOL 47 F switch failover overview 175 Fast Uplink Convergence 76 fault tolerance port trunking 37 FDB static entries 66 frame tagging 55 G default gateway 108 H high availability 9 167 IBM DirectorSNMP IBM Director 14 IEEE 802 1Q VLAN tagging 55 58 IEEE standards 802 1x 47 IGMP Filtering configuring BBI example 125 IGMP Filtering configuring CLI example 122 IGMP Snooping 118 IGMP Snooping configuring BBI example 123 IGMP Snooping configuring CLI example 121 IGMPv3 snooping 119 IP address routing example 109 IP interfaces configuring 12 example configuration IP interface configuration 111 VLAN 1 default 58 VLANs 58 IP routing 106 default gateway configuration 13 109 IP interface configuration 109 111 IP interfaces example configuration 109 IP subnets routing IP subnets 107 routing 108 IP subnets VLANs 53 J fragmenting jumbo frames fragmenting to normal size routing 106 LACP 44 Link Aggregation Control Protocol 44 logical segment 53 LSAs 133 Main Menu command line interface CLI 12 media access control
164. or example the action defined for IGMP Filter 1 supersedes the action defined for IGMP Filter 2 Configuring the range Each IGMP Filter allows you to set a start and end point that defines the range of IP addresses upon which the filter takes action Each IP address in the range must be between 224 0 0 0 and 239 255 255 255 Configuring the action Each IGMP Filter can allow or deny IP multicasts to the range of IP addresses configured If you configure the filter to deny IP multicasts then IGMP Membership Reports from multicast groups within the range are dropped You can configure a secondary filter to allow IP multicasts to a small range of addresses within a larger range that a primary filter is configured to deny The two filters work together to allow IP multicasts to a small subset of addresses within the larger range of addresses The secondary filter must have a lower number than the primary filter so that it takes precedence 120 IGMP Snooping Static multicast router A static multicast router Mrouter can be configured for a particular port on a particular VLAN A static Mrouter does not have to be learned through IGMP Snooping You can configure static Mrouters on any switch port except the management port 17 The switch supports up to total of sixteen static Mrouters When you configure a static Mrouter on a VLAN it replaces any dynamic Mrouters learned through IGMP Snooping IGMP Snooping configuration example
165. orized state and begins sending frames even if the port is unauthorized 802 1x port states The state of the port determines whether the client is granted access to the network as follows e Unauthorized While in this state the port discards all ingress and egress traffic except EAP packets e Authorized When the client is authenticated successfully the port transitions to the authorized state allowing all traffic to and from the client to flow normally e Force Unauthorized You can configure this state that denies all access to the port e Force Authorized You can configure this state that allows full access to the port Use the 802 1x Global Configuration Menu cf g 12 8021x global to configure 802 1x authentication for all ports in the switch Use the 802 1x Port Menu cfg 12 8021x port x to configure a single port 49 Port based Network Access and traffic control Supported RADIUS attributes The HP 10GbE switch 802 1x Authenticator relies on external RADIUS servers for authentication with EAP The following table lists the RADIUS attributes that are supported as part of RADIUS EAP authentication based on the guidelines specified in Annex D of the 802 1x standard and RFC 3580 Table 9 EAP support for RADIUS attributes Attribute Attribute Value A R A A A C A R 1 User Name The value of the Type Data field from the 1 0 1 0 0 supplicant s EAP Response Identity message If the Identity is unknown
166. orsassanseannenseersseaseannnnds 92 Configure Access Control Lists and Groups BBI example 1 ssssssssssessseisseissrissserssersserssrissrersserssrssn 93 Using DSOP values to provide QoS Luussskamkerei etatene 97 Differentiated Services concepts cccccsesseecesseecesceseceesesseeeeeessseeeesceseceeeseseeeesseseeeesseseeesenssseeeeseneaaees 97 Per Hop Behavior xi lt ccisscctsneseauscaeit sn cesctssaudcbesssecedsandtaderesisasesasaidoreeasiatatastiieettevagecaeaidgelesisecati aeietetees 97 EEE NE NE 98 Using 802 1p priorities to provide OL peer aes abre oeenkeadi 98 802 1p configuration CLI example Lamssksnsememam markedet qiassdiktn 100 802 1p configuration BBI example ccwisnadnanianwiiera ans emen elaine uate uieaeaaarenanetmions 100 Jeg and Scheduling lt qcuniionscad a E nan a 105 Basic IP routing IP routing hel jt eee eee arte mane Tee nent EE R merry ener yet arena TERE E Tuer rer EEE EER 106 Routing between FL 106 Ex mpleof subnet TONING asx eacet oestonsusebvcaneaveps aseaseu een E n EE EEEREN E EEEE TESSE REEE EEEE NEE ERE eee EE 109 Using VIAMs to segregate broadcast domains lt 4 scccesaseniaesesiccaceaseniaiieaccesrteasrnen deaceneerninaaeecnereans 110 Dynamic Host Configuration Protocol lt cccccsustassucsseuecexsasssnatie oeveceetaaassuenniecen eae eer aaneo rece a 112 Diale OVE Te E RO NE SN PO 112 DHCP relay agent colgerden cisc anccanccescteeseseatcansspeantesscaabcsdaigncnsensiaaseneseacniarsneaneeasacastecredeeani
167. ort Version Expires Max Query Resp Time QRV QQIC 21 v2 static unknown 2 20 V3 4 09 128 2 125 These commands display information about IGMP Groups and Mrouters learned through IGMP Snooping 121 IGMP Snooping Configuring IGMP Filtering CLI example 1 Enable IGMP Filtering on the switch gt gt cfg 13 igmp igmpflt Select IGMP Filtering menu gt gt IGMP Filter ena Enable IGMP Filtering Current status disabled New status enabled 2 Define an IGMP Filter 3 Assi gt gt cfg 13 igmp igmpflt Select IGMP Filtering menu gt gt IGMP Filter filter 1 Select Filter 1 Definition menu gt gt IGMP Filter 1 Definition range 224 0 1 0 Enter first IP address of the range Current multicast address2 Enter new multicast address2 226 0 0 0 Enter second IP address of the range Current multicast address1 New pending multicast addressl 224 0 1 0 Current multicast address2 New pending multicast address2 226 0 0 0 gt gt IGMP Filter 1 Definition action deny Deny multicast traffic gt gt IGMP Filter 1 Definition ena Enable the filter n the IGMP Filter to a port gt gt cfg 13 igmp igmpflt Select IGMP Filtering menu gt gt IGMP Filter port 21 Select port 21 gt gt IGMP Port 21 filt ena Enable IGMP Filtering on the port Current port 21 filtering disabled New port 21 filtering enabled gt gt IGMP Port 21 add 1 Add IGMP Filter 1 to the port
168. ose not to implement an IP address owner For the purposes of this chapter VRRP routers that are not the IP address owner are called renters 173 High availability Master and backup virtual router Virtual Within each virtual router one VRRP router is selected to be the virtual router master See Selecting the Master VRRP Router for an explanation of the selection process NOTE If the IP address owner is available it will always become the virtual router master The virtual router master forwards packets sent to the virtual router It also responds to Address Resolution Protocol ARP requests sent to the virtual router s IP address Finally the virtual router master sends out periodic advertisements to let other VRRP routers know it is alive and its priority Within a virtual router the VRRP routers not selected to be the master are known as virtual router backups Should the virtual router master fail one of the virtual router backups becomes the master and assumes its responsibilities Interface Router At Layer 3 a Virtual Interface Router VIR allows two VRRP routers to share an IP interface across the routers VIRs provide a single Destination IP DIP for upstream routers to reach various destination networks and provide a virtual default Gateway NOTE Every VIR must be assigned to an IP interface and every IP interface must be assigned to a VLAN If no port in a VLAN has link up the IP interface of that VLA
169. ould come The following figure shows a basic DHCP network example Figure 16 DHCP relay agent configuration Boston 1 10GbE DHCP Server DHCP Client HP Blade Chassis In HP 10GbE switch implementation there is no need for primary or secondary servers The client request is forwarded to the BOOTP servers configured on the switch The use of two servers provides failover redundancy However no health checking is supported Use the following commands to configure the switch as a DHCP relay agent gt gt cfg 13 bootp gt gt Bootstrap Protocol Relay addr Set IP address of BOOTP server gt gt Bootstrap Protocol Relay addr2 Set IP address of 2nd BOOTP server gt gt Bootstrap Protocol Relay on Globally turn BOOTP relay on gt gt Bootstrap Protocol Relay off Globally turn BOOTP relay off Display current configuration gt gt Bootstrap Protocol Relay cur Additionally DHCP Relay functionality can be assigned on a per interface basis Use the following command to enable the Relay functionality gt gt cfg 13 if lt 1 249 gt relay ena 113 Routing Information Protocol In a routed environment routers communicate with one another to keep track of available routes Routers can learn about available routes dynamically using the Routing Information Protocol RIP HP 1OGbE switch software supports RIP version 1 RIPv1 and RIP version 2 RIPv2 for exchanging T
170. p to 32 spanning tree instances that correspond to STP Groups 1 32 In Multiple Spanning Tree Protocol MSTP several VLANs can be mapped to each Spanning Tree instance Each Spanning Tree instance is independent of other instances MSTP allows frames assigned to different VLANs to follow separate paths each path based on an independent Spanning Tree instance This approach provides multiple forwarding paths for data traffic enabling load balancing and reducing the number of Spanning Tree instances required to support a large number of VLANs MSTP region A group of interconnected bridges that share the same attributes is called an MST region Each bridge within the region must share the following attributes e Alphanumeric name e Revision level e VLAN to STG mapping scheme MSTP provides rapid reconfiguration scalability and control due to the support of regions and multiple Spanning Tree instances support within each region Common Internal Spanning Tree The Common Internal Spanning Tree CIST provides a common form of Spanning Tree Protocol with one Spanning Tree instance that can be used throughout the MSTP region CIST allows the switch to interoperate with legacy equipment including devices that run IEEE 802 1d STP CIST allows the MSTP region to act as a virtual bridge to other bridges outside of the region and provides a single Spanning Tree instance to interact with them CIST is the default spanning tree group
171. param mpmodel snmpv1 uname vitrap model snmpvl 5 Use the community table to define the community string used in the traps c sys ssnmp snmpv3 comm 10 Define the community string index vitrap name public uname vitrap 18 Accessing the switch SNMPV2 trap host configuration The SNMPV2 trap host configuration is similar to the SNMPv1 trap host configuration Wherever you specify the model specify snmpv2 instead of snmpv1 c sys ssnmp snmpv3 usm 10 Configure user named v2trap name v2trap c sys ssnmp snmpv3 access 10 Define access group to view SNMPv2 traps name v2trap model snmpv2 nview iso c sys ssnmp snmpv3 group 10 Assign user to the access group model snmpv2 uname v2trap gname v2trap c sys ssnmp snmpv3 notify 10 Assign user to the notify table name v2trap tag v2trap c sys ssnmp snmpv3 taddr 10 Define an IP address to send traps name v2trap addr 47 81 25 66 taglist v2trap pname v2param c sys ssnmp snmpv3 tparam 10 Specify SNMPv2 traps to send name v2param mpmodel snmpv2c uname v2trap model snmpv2 c sys ssnmp snmpv3 comm 10 Define the community string index v2trap name public uname v2trap SNMPv3 trap host configuration To configure a user for SNMPv3 traps you can choose to send the traps with both privacy and authentication with authentication only or without privacy or authentication Use the following commands to configure the access table c sys ssnmp sn
172. pport e Offline Diagnostics This tool is used for troubleshooting suspected switch hardware issues These tests verify that the selected hardware is performing within expected engineering specifications e Software Panics lf a fatal software condition is found during runtime the switch will capture the current hardware and software state information into a panic dump This dump file can be analyzed post mortem to determine the cause of the problem 195 Troubleshooting tools e Stack Trace lf a fatal software condition occurs the switch dumps stack trace data to the console If you have a console attached to the switch capture the console dump and forward it to HP technical support 196 Index 8 802 1x port states 49 A accessing the switch defining source IP addresses 20 RADIUS authentication 21 security 20 using the command line interface CLI 12 ACL Blocks and Groups 90 ACL configuration examples 92 ACL filters 87 active active redundancy 175 allowable source IP addresses 20 B BBI See Browser Based Interface 134 Bridge Protocol Data Unit BPDU 68 broadcast domains 53 58 Browser Based Interface 134 c Cisco EtherChannel 38 Command Line Interface 134 command line interface CLI 12 configuration 38 configuration rules port mirroring 38 trunking 38 VLANs 38 configuring OSPF 141 configuring SNMP trap hosts 17 console messages 195 customer support t
173. r 3 QoS Access Control Click a port number to select a monitoring port f lu lbo f Jun al 2 ud 8 le lo vand 193 Troubleshooting tools d Click Add Mirrored Port Monitoring Port 18 Configuration Mirrored Port Direction Add Mirrored Port Delete Monitor Port e Enter a port number for the mirrored port and select the Port Mirror Direction Port Mirroring Configuration for Port 18 Mirrored Port Port Mirror Direction f Click Submit 2 Apply verify and save the configuration h r ly CONFIGURE STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save 3 Verify the Port Mirroring configuration on the switch Monitoring Port 18 Configuration Add Mirrored Port Delete Monitor Port 194 Troubleshooting tools Other network troubleshooting techniques Other network troubleshooting techniques include the following Console and Syslog messages When a switch experiences a problem review the console and Syslog messages The switch displays these informative messages when state changes and system problems occur Syslog messages can be viewed by using the info sys log command For more information on interpreting syslog messages see the HP 10Gb Ethernet BL c Switch Command Reference Guide Ping To verify station to station connectivity across the network execute the following co
174. ration can be done from the command line interface See the HP 10Gb Ethernet BL c Switch Command Reference Guide Overview Setting up VLANs is a way to segment networks to increase network flexibility without changing the physical network topology With network segmentation each switch port connects to a segment that is a single broadcast domain When a switch port is configured to be a member of a VLAN it is added to a group of ports workgroup that belongs to one broadcast domain Ports are grouped into broadcast domains by assigning them to the same VLAN Multicast broadcast and unknown unicast frames are flooded only to ports in the same VLAN VLANs and port VLAN ID numbers VLAN numbers The HP 10GbE switch supports up to 1 000 VLANs per switch Even though the maximum number of VLANs supported at any given time is 1 000 each can be identified with any number between 1 and 4095 VLAN 1 is the default VLAN and all ports are assigned to it VLAN 4095 is reserved for switch management and it cannot be configured 53 VLANs Viewing VLANs The VLAN information menu info 12 vlan displays all configured VLANs and all member ports that have an active link state for example gt gt Layer 2 vlan Status Ports Default VLAN 1 4 16 18 21 2 VLAN 2 2 3 4095 VLAN 4095 17 PVID numbers Each port in the switch has a configurable default VLAN number known as its PVID This places all ports on the same VLAN initially although
175. re cee mqessneroemeasyiioresee once anes a er ee ea ee 67 Configuring a static FDB ass 67 Spanning Tree Protocol Contents rd 42 68 NENNE aens cats atte ena dean asa 68 Bridge Protocol Data Units c ccscncsocadeacexs lt cscsuecsseiasieeexesasnesanacnsnsadsuabeisaeecaSseagntspessgieh tb iapsauebatsaaccedasbonsasbass 68 Determining the path for forwarding BPDUS c ccesccseeeeeeceteeeneeeeeeeeeeeesesseseeeessessneeeneeeseeentesneeed 69 Bridge ELD EE EE E ER REAPEROS EER AEE RENAE TEERDE RF E 69 OME OMONINV 252245 cua nn a a A E E ES 69 ogi ee eo PETE EET E NE EE SR 69 Spanning Tree Group configuration guidelines vudanmneseirmneisen emmievjuheihk he usdtviter 69 Default Spanning essnigrdlets4avesder asesemese eek 69 Adding a VIAN to a Spanning Tree G psssesnesmmsaaasimutennmemahunnganddusnteneted 70 Creating a VLAN scisiisssercoscosdsdseisyscesesencdeds la eD Ee AEE Ge 70 Rules for VLAN Jagged P rsti evana eiiie ven Eaa ia E R secdummanesamuneetas 70 Adding and removing ports from STGs wisi ssricscosssanecarsbnicssoceaasbcacsnzasacossom yearn ee asssosacayenapinrctesesianvierries 70 Assigning cost to ports and trunk GTOUPS edysasissnn ccsadegasanisnaen lt eandqucsied ganas coundgeusanisarenceanejan sini sacbnandaraayt 71 M ltiple Spanning Trees sescenti raiot a E an i e kneet 71 Why do we need Multiple Spanning Trees ccccecesecessecceseeeecneecensaeeeeeecenseeeesaeeeeueeeenseeeneeeenneeeeaes 71 VLAN participation in Span
176. retransmission interval and interface transit delay OSPF traps Traps produce messages upon certain events or error conditions such as missing a hello failing a neighbor or recalculating the SPF In addition to the above parameters you can also specify the following e Link State Database size The size of the external LSA database can be specified to help manage the memory resources on the switch e Shortest Path First SPF interval Time interval between successive calculations of the shortest path tree using the Dijkstra s algorithm 134 OSPF e Stub area metric A stub area can be configured to send a numeric metric value such that all routes received via that stub area carry the configured metric to potentially influence routing decisions e Default routes Default routes with weight metrics can be manually injected into transit areas This helps establish a preferred route when multiple routing devices exist between two areas It also helps route traffic to external networks Defining areas If you are configuring multiple areas in your OSPF domain one of the areas must be designated as area 0 known as the backbone The backbone is the central OSPF area and is usually physically connected to all other areas The areas inject routing information into the backbone which in turn disseminates the information into other areas Since the backbone connects the areas in your network it must be a contiguous area If t
177. ring Introduction Remote Monitoring RMON allows network devices to exchange network monitoring data RMON performs the following major functions e Gathers cumulative statistics for Ethernet interfaces e Tracks a history of statistics for Ethernet interfaces e Creates and triggers alarms for user defined events Overview The RMON MIB provides an interface between the RMON agent on the switch and an RMON management application The RMON MIB is described in RFC 1757 The RMON standard defines objects that are suitable for the management of Ethernet networks The RMON agent continuously collects statistics and proactively monitors switch performance RMON allows you to monitor traffic flowing through the switch The switch supports the following RMON Groups as described in RFC 1757 e Group 1 Statistics e Group 2 History e Group 3 Alarms e Group 9 Events RMON group statistics The switch supports collection of Ethernet statistics as outlined in the RMON statistics MIB in reference to etherStatsTable You can enable RMON statistics on a per port basis and you can view them using the following command stat port x rmon RMON statistics are sampled every second and new data overwrites any old data on a given port NOTE RMON port statistics must be enabled for the port before you can view RMON statistics 155 Configuring RMON Statistics CLI example Remote monitoring 1 Enable RMON on each port where you wis
178. rt of this chapter describes the different types of ports used on the switch This information is useful in understanding other applications described in this guide from the context of the embedded switch server environment For specific information on how to configure ports for speed auto negotiation and duplex modes see the port commands in the HP 10Gb Ethernet Bl c Switch Command Reference Guide The second part of this chapter provides configuration background and examples for trunking multiple ports together Trunk groups can provide super bandwidth multi link connections between switches or other trunk capable devices A trunk group is a group of links that act together combining their bandwidth to create a single larger virtual link The switch provides trunking support for the four external ports and 16 server ports Ports on the switch The following table describes the Ethernet ports of the switch including the port name and function NOTE The actual mapping of switch ports to NIC interfaces is dependant on the operating system software the type of server blade and the enclosure type For more information see the HP 10Gb Ethernet Bl c Switch User Guide Table 7 Ethernet switch port names Port number Port alias Downlink1 Downlink2 Downlink3 Downlink4 Downlink5 Downlink6 Downlink7 Downlink8 Oo M ININIUOJ RI O ND Downlink9 O Downlink10
179. rted RADIUS attributes ccccccccccsssceeceseeceeeesseeeeeceeeeescsseceecesseeeesesseeeesenseceesessseeeessseeeeseneaaees 50 EA Pel configuration guidelines s 51 Port based traffic control ccccccccesessececesseeeceeseseececseneeeeeeseseeeesceeeeeseeseeeeesseeeescsseeeesesseseesesseseeeesetatees 51 Configuring port based traffic control ssrrnravrrrvanrrnvnvvnrrrnnrrrnnnnvnnnnrrsnorrrnnnnrnnnrrsnnrrrnnnersnnnrsrnnrrrsnnen 52 VLANs hedre 53 NNN 53 VLANs and port VLAN ID numbers s25 lt cscereceaedondtasnad orone2gdchaaasvegereadtenuband seadeconigatabiacueasereaneneiateadeanttawt 53 MAN at ERE EEE EE E 53 Viewing VAN GE EE EE EE 54 BT gt EE NE EE ER EE EE 54 Viewing and configuring P VIDS isa c ccnasselaey sas sanoecedadday et saveemnend emul Gjendine sees stessr resene 54 PO Ge EEE EE 54 eg CONTIG UTGTIGN OR NE 54 KE ire Te fo ol OE EE 55 Ed Jr redd 58 VLAN topologies and design considerations RE 58 VLAN configuration rules vassverk 59 Multiple VLANS with FLUC le EEE EN NE 60 Configuring the sanere vs 61 Configuring ports and VLANs on Switch 1 CLI example Lo vbsnrtetlnr nstandmebsekkketden 61 Configuring ports and VLANs on Switch 2 CLI eomplbuanpas suamdsseudromuden 63 Configuring ports and VLANs on Switch 1 BBI example cceceeesseeteceneeeeeeeeeeesneeneeesseeeneennees 64 PDB Stati c eniri ES aean e E E souabnadaneqquosuneendnadedeqaa E E R 66 Trunking support for FDB static SHINES x cevaccnsssass ve
180. rver IP Current secondary RADIUS server 0 0 0 0 New pending secondary RADIUS server 10 10 1 2 2 Configure the primary RADIUS secret and secondary RADIUS secret gt gt RADIUS Server secret Enter new RADIUS secret lt 1 32 character secret gt gt gt RADIUS Server secret2 Enter new RADIUS second secret lt 1 32 character secret gt A CAUTION If you configure the RADIUS secret using any method other than a direct console connection the secret may be transmitted over the network as clear text 3 If desired you may change the default User Datagram Protocol UDP port number used to listen to RADIUS The well known port for RADIUS is 1645 gt gt RADIUS Server port Current RADIUS port 1645 Enter new RADIUS port 1500 3000 lt UDP port number gt 4 Configure the number of retry attempts for contacting the RADIUS server and the timeout period gt gt RADIUS Server retries Current RADIUS server retries 3 Enter new RADIUS server retries 1 3 lt server retries gt gt gt RADIUS Server time Current RADIUS server timeout 3 Enter new RADIUS server timeout 1 10 10 Enter the timeout period in seconds 5 Apply and save the configuration gt gt RADIUS Server apply gt gt RADIUS Server save 22 Accessing the switch Configuring RADIUS on the switch BBI example 1 Configure RADIUS parameters a Click the Configure context button b Open the System folder and select Radius Op
181. s Flag Value URG 0x0020 ACK 0x0010 PSH 0x0008 RST 0x0004 SYN 0x0002 FIN 0x000 1 88 Quality of Service e Packet Format o Ethernet format eth2 SNAP LLC o Ethernet tagging format e Egress port packets Note that the egress port ACL will not match a broadcast multicast unknown unicast or Layer 3 packet The egress port ACL will not match packets if the destination port is a trunk member Summary of ACL actions Actions determine how the traffic is treated The HP 1OGbE switch QoS actions include the following e Pass or Drop e Remark a new DiffServ Code Point DSCP e Re mark the 802 1p field e Setthe COS queue Understanding ACL precedence Each ACL has a unique precedence level based on its number When an incoming packet matches the highest precedence ACL the ACL s configured action takes place The other assigned ACLs also are considered in order of precedence ACLs are divided into Precedence Groups as shown in the following table Precedence Group ACLs Precedence Level Precedence Group 1 ACL 1 ACL 128 Low Precedence Group 2 ACL 129 ACL 256 Precedence Group 3 ACL 257 ACL 384 High NOTE Precedence Groups are not related to ACL Groups Each Precedence Group has its own precedence level such that Precedence Group 2 has a higher precedence level than Precedence Group 1 Within each Precedence Group higher numbered ACLs receive higher precedence so that the lo
182. s the format of frames transmitted on a tagged port you must carefully plan network designs to prevent tagged frames from being transmitted to devices that do not support 802 1Q VLAN tags or devices where tagging is not enabled Important terms used with the 802 1Q tagging feature are VLAN identifier VID the 12 bit portion of the VLAN tag in the frame header that identifies an explicit VLAN Port VLAN identifier PVID a classification mechanism that associates a port with a specific VLAN For example a port with a PVID of 3 PVID 3 assigns all untagged frames received on this port to VLAN 3 Tagged frame a frame that carries VLAN tagging information in the header The VLAN tagging information is a 32 bit field VLAN tag in the frame header that identifies the frame as belonging to a specific VLAN Untagged frames are marked tagged with this classification as they leave the switch through a port that is configured as a tagged port Untagged frame a frame that does not carry any VLAN tagging information in the frame header Untagged member a port that has been configured as an untagged member of a specific VLAN When an untagged frame exits the switch through an untagged member port the frame header remains unchanged When a tagged frame exits the switch through an untagged member port the tag is stripped and the tagged frame is changed to an untagged frame Tagged member a port that has been configured as a tagged memb
183. sage to the authenticator the port will transition from authorized to unauthorized state 47 Port based Network Access and traffic control 802 1x authentication process The clients and authenticators communicate using Extensible Authentication Protocol EAP which was originally designed to run over PPP and for which the IEEE 802 1x Standard has defined an encapsulation method over Ethernet frames called EAP over LAN EAPOL The following figure shows a typical message exchange initiated by the client Figure 2 Using EAPol to authenticate a port RADIUS 802 1x Client Server EAPOL HP 10GbE RADIUS EAP o Authenticator gt Ethernet RADIUS Client UDP IP ai Port Unauthorized EAPOL Start EAP Request Identity EAP Response Identity Radius Access Request Radius Access Challenge EAP Request Credentials EAP Response Credentials Radius Access Request Radius Access Accept EAP Success Port Authorized EAPoL Message Exchange During authentication EAPOL messages are exchanged between the client and the switch authenticator while RADIUS EAP messages are exchanged between the switch authenticator and the Radius authentication server Authentication is initiated by one of the following methods Switch authenticator sends an EAP Request Identity packet to the client Client sends an EAPOL Start frame to the switch authenticator which responds with an EAP Request Identity frame The
184. sed Port Mirroring 3 Layer 2 8021x GR Virtual LANs Select Spanning Tree Groups MSTPIRSTP E Trunk Groups ETrunk Hash BILACP c Select a Spanning Tree Group number 74 Spanning Tree Protocol d Enter the Spanning Tree Group number and set the Switch Spanning Tree State to on To add a VLAN to the Spanning Tree Group select the VLAN in the VLANs Available list and click Add VLAN 2 is automatically removed from Spanning Tree Group 1 Switch Spanning Tree Group Configuration Spanning Tree Group ID 1 128 Switch Spanning Tree State Bridge Priority 0 65535 Bridge Hello Time 1 10secs Bridge Max Age 6 40secs Bridge Forward Delay 4 30secs VLANs Available VLANs in STG Vlan ID Name Vlan ID Name 1 Default VLAN Add gt gt 2 VLAN Name 4095 Mgmt VLAN lt lt Remove Switch Spanning Tree Port Configuration Switch Port Port Priority Port Path Cost Port Spanning Tree State 128 2 off 128 2 off e Scroll down and click Submit 3 Apply verify and save the configuration h Se iy CONFIGURE STATISTICS DASHBOARD Apply Save Revert Diff Dump invent 1 Apply 2 Verify 3 Save 73 Spanning Tree Protocol Port Fast Forwarding Port Fast Forwarding permits a port that participates in Spanning Tree to bypass the Listening and Learning states and enter directly into the Forwarding state While in the Forwarding state the port
185. sed connection oriented transport whereas RADIUS is UDP based TCP offers a connection oriented transport while UDP offers best effort delivery RADIUS requires additional programmable variables such as re transmit attempts and time outs to compensate for best effort transport but it lacks the level of built in support that a TCP transport offers e TACACS offers full packet encryption whereas RADIUS offers password only encryption in authentication requests e TACACS separates authentication authorization and accounting How TACACS authentication works TACACS works much in the same way as RADIUS authentication 1 Remote administrator connects to the switch and provides user name and password NOTE The user name and password can have a maximum length of 128 characters The password cannot be left blank 2 Using Authentication Authorization protocol the switch sends request to authentication server 3 Authentication server checks the request against the user ID database 4 Using TACACS protocol the authentication server instructs the switch to grant or deny administrative access During a session if additional authorization checking is needed the switch checks with a TACACS server to determine if the user is granted permission to use a particular command TACACS authentication features Authentication is the action of determining the identity of a user and is generally done when the user first attempts to log in t
186. sed within the NSSA but only if they are originated by a router from inside the NSSA area External routes originated by a router that is not a member of the NSSA area are not advertised in the NSSA area e Transit Area an area that allows area summary information to be exchanged between routing devices The backbone area 0 any area that contains a virtual link to connect two areas and any area that is not a stub area or an NSSA are considered transit areas 131 OSPF Figure 17 OSPF area types _ EE m a _ La Backbone rie Jr Pid Area 0 Fs 2 Also a Transit Area p NZ ABR ra ABR D ABR E ee gt ED SE E R ma og gt X 7 4 SS Internal LSA N 7 n 1 Virtual I Routes 7 vo ne I VI Stub Area Transit Area Link Not So Stubby Area No External Routes IS p f NSSA Ten from Backbone 2 BR p N 4 ae y External LSA Ps Er T _ Routes 7 arr p s N NJ ASBR 7 F N X r Stub Area NSSA Sr ABR Area Border Router or Transit Area ASBR Autonomous System Connected to Backbone Non OSPF Area l Boundary Router via Virtual Link N RIP BGPAS _ ne Pd Types of OSPF routing devices As shown in the figure OSPF uses the following types of routing devices e Internal Router IR a router that has all of its interfaces within the same area IRs maintain LSDBs identical to those of other routing dev
187. send a new IP address when a device is connected to a different place in the network DHCP is an extension of another network IP management protocol Bootstrap Protocol BOOTP with an additional capability of being able to dynamically allocate reusable network addresses and configuration parameters for client operation Built on the client server model DHCP allows hosts or clients on an IP network to obtain their configurations from a DHCP server thereby reducing network administration The most significant configuration the client receives from the server is its required IP address other optional parameters include the generic file name to be booted the address of the default gateway and so forth The DHCP relay agent eliminates the need to have DHCP BOOTP servers on every subnet It allows the administrator to reduce the number of DHCP servers deployed on the network and to centralize them Without the DHCP relay agent there must be at least one DHCP server deployed at each subnet that has hosts needing to perform the DHCP request DHCP relay agent DHCP is described in RFC 2131 and the DHCP relay agent supported on HP 10GbE switches is described in RFC 1542 DHCP uses UDP as its transport protocol The client sends messages to the server on port 67 and the server sends messages to the client on port 68 DHCP defines the methods through which clients can be assigned an IP address for a finite lease period and allowing reassignment of
188. shooting tools Ingress traffic is duplicated and sent to the mirrored port before processing and egress traffic is duplicated and sent to the mirrored port after processing Configuring Port Mirroring CLI example To configure Port Mirroring for the example shown in the preceding figure 1 Specify the monitoring port gt gt cfg pmirr monport 18 Select port 18 for monitoring 2 Select the ports that you want to mirror Port 18 add 21 Select port 21 to mirror Enter port mirror direction in out or both in Monitor ingress traffic on port 21 Port 18 add 1 Select port 1 to mirror Enter port mirror direction in out or both out Monitor egress traffic on port 1 3 Enable Port Mirroring gt gt cfg pmirr mirr ena Enable port mirroring 4 Apply and save the configuration gt gt PortMirroring apply Apply the configuration gt gt PortMirroring save Save the configuration 5 View the current configuration gt gt PortMirroring cur Display the current settings Port mirroring is enabled Monitoring Ports Mirrored Ports 1 none none none none none 192 Troubleshooting tools Configure Port Mirroring Click the Configure context button b re Switch folder and select Port Based Port Mirroring click the underlined text not the folder Open lt j HP 10Gb Ethernet BL c Switch aa System Select S Port Based Port Mirroring E Layer 2 E RMON Menu Laye
189. source destination and protocol and performs a controlling action on the traffic when certain characteristics are matched The switch can classify traffic by reading the IEEE 802 1p priority value or by using filters to match specific criteria When network traffic attributes match those specified in a traffic pattern the policy instructs the switch to perform specified actions on each packet that passes through it The packets are assigned to different Class of Service COS queues and scheduled for transmission 86 Quality of Service The basic HP 10GbE switch QoS model works as follows e Classify traffic o Read 802 1p Priority o Match ACL filter parameters e Meter traffic o Define bandwidth and burst parameters o Select actions to perform on in profile and out of profile traffic e Perform actions o Drop packets o Pass packets o Mark DSCP or 802 1p Priority o Set COS queue with or without re marking e Queue and schedule traffic o Place packets in a COS queue configurable as either 2 or 8 queues o Schedule transmission based on the COS queue weight Using ACL filters Access Control Lists are filters that allow you to classify and segment traffic so you can provide different levels of service to different traffic types Each filter defines the conditions that must match for inclusion in the filter and also the actions that are performed when a match is made Summary of packet classifiers The HP 10GbE s
190. ss 05 2ceiasecsnscesveneniannioonscerevmeckernadenseavermecteaneeses 33 SSH SCP integration with RADIUS and TACACS authentication eerren 34 Contents erte ov 34 Setting up user DSen nen eene EE E med E uden det reden tener aces 35 Ports and trunking PERSIE ta OE NN NN NE 36 Peder ARE A aae AEA AAE FEARTA aT Eaa i 36 Port WONK aU ER EEE ERR pce eects EE SSRA PE AR ESES np sec perce 37 Statistical ido aat basis rAr ER TOES n eaaa 37 B iltin fault EE RE EE 37 Before you configure MUNKS sessir tenriseerri ene teesssies ris ent enadi reS eee errai reS EEEE OR Aea S Feseia i 37 Teg group configuration TUES ic ceteasazcancanetepelaaea ss ncconteuserauiamusuiganaaielaaeuuintaianae a icecontaatieorininasatieae 38 Portirunking example ES EE eee cere 39 Configuring trunk groups CLI example asset 40 Configuring trunk groups BBI example vvs 41 Configurable Trunk Hash algorithm sva 44 link Aggregation Control Protocol i5 csccj cnccsisstels edited eee ane es ee igee ee 44 Configuring PT vvs 46 Port based Network Access and traffic control Port based Network Access sanser ser 47 Extensible authentication protocol over LAN ccccccssssecesseceeecesseeeccsseceesceseseeeccssseeescsseeeesessstesesenseaaes 47 802 1x authentication process ccccccccesscccesssseccescsseceesceseeeeeessseeeescsseceescesesesescsseeeesessegeesessaeeecentaaees 48 EP Message he vvs 48 802 IX port lalese ereina E EEE EREET OEE EE EATON E RETER bader rie 49 Suppo
191. sses The switch uses source filtering which allows hosts to report interest in receiving multicast packets only from specific source addresses or from all but specific source addresses The switch supports the following IGMPv3 filter modes e INCLUDE mode The host requests membership to a multicast group and provides a list of IP addresses from which it wants to receive traffic e EXCLUDE mode The host requests membership to a multicast group and provides a list of IP addresses from which it does not want to receive traffic This indicates that the host wants to receive traffic only from sources that are not part of the Exclude list To disable snooping on EXCLUDE mode reports use the following command cfg 13 igmp snoop igmpv3 exclude dis By default the switch snoops the first eight sources listed in the IGMPv3 Group Record Use the following command to change the number of snooping sources cfg 13 igmp snoop igmpv3 sources lt 1l 64 gt IGMPv3 Snooping is compatible with IGMPv1 and IGMPv2 Snooping You can disable snooping on version 1 and version 2 reports using the following command cfg 13 igmp snoop igmpv3 viv2 dis Fastleave When the switch with IGMP Snooping enabled receives an IGMPv2 leave message it sends a Group Specific Query to determine if any other devices in the same group and on the same port are still interested in the specified multicast group traffic The switch removes the affiliated port from that part
192. stance of this attribute MAY be present in a packet 1 Exactly one instance of this attribute MUST be present in a packet 1 One or more of these attributes MUST be present 50 Port based Network Access and traffic control EAPol configuration guidelines When configuring EAPol consider the following guidelines e The 802 1x port based authentication is currently supported only in pointto point configurations that is with a single supplicant connected to an 802 1x enabled switch port e When 802 1x is enabled a port has to be in the authorized state before any other Layer 2 feature can be operationally enabled For example the STG state of a port is operationally disabled while the port is in the unauthorized state e The 802 1x supplicant capability is not supported Therefore none of its ports can connect successfully to an 802 1x enabled port of another device such as another switch which acts as an authenticator unless access control on the remote port is disabled or is configured in forced authorized mode For example if a HP 1OGbE switch is connected to another HP 10GbE switch and if 802 1x is enabled on both switches the two connected ports must be configured in force authorized mode e The 802 1x standard has optional provisions for supporting dynamic virtual LAN assignment via RADIUS tunneling attributes for example Tunnel Type VLAN Tunnel Medium Type 802 and Tunnel Private Group ID VLAN id Thes
193. such routes in updates but sets their metrics to 16 The disadvantage of using this feature is the increase of size in the routing updates Triggered updates Triggered updates are an attempt to speed up convergence When Triggered Updates is enabled cfg 13 rip if x trigg ena whenever a router changes the metric for a route it sends update messages almost immediately without waiting for the regular update interval It is recommended to enable Triggered Updates 115 Routing Information Protocol Multicast RIPv2 messages use IP multicast address 224 0 0 9 for periodic broadcasts Multicast RIPv2 announcements are not processed by RIPv1 routers IGMP is not needed since these are inter router messages which are not forwarded To configure RIPv2 in RIPv1 compatibility mode set multicast to disable Default The RIP router can listen and supply a default route usually represented as 0 0 0 0 in the routing table When a router does not have an explicit route to a destination network in its routing table it uses the default route to forward those packets Metric The metric field contains a configurable value between 1 and 15 inclusive which specifies the current metric for the interface The metric value typically indicates the total number of hops to the destination The metric value of 16 represents an unreachable destination Authentication RIPv2 authentication uses plaintext password for authentication If configured us
194. t IP mask on stub area network ena Enable IP interface 2 gt gt IP Interface gt gt IP Interface gt gt IP Interface gt gt IP Interface gt gt IP Interface NNNEF EF PF HH HH OH gt gt IP Interface 2 Enable OSPF gt gt IP Interface 2 cfg 13 ospf on 3 Define the backbone gt gt Open Shortest Path First aindex 0 Select menu for area index 0 gt gt OSPF Area index 0 areaid 0 0 0 0 Set the ID for backbone area 0 gt gt OSPF Area index 0 type transit Define backbone as transit type gt gt OSPF Area index 0 enable Enable the area 4 Define the stub area gt gt OSPF Area index 0 aindex 1 Select menu for area index 1 gt gt OSPF Area index 1 areaid 0 0 0 1 Set the area ID for OSPF area 1 gt gt OSPF Area index 1 type stub Define area as stub type gt gt OSPF Area index 1 enable Enable the area 5 Attach the network interface to the backbone gt gt OSPF Area index 1 if 1 Select OSPF menu for IP interface 1 gt gt OSPF Interface 1 aindex 0 Attach network to backbone index gt gt OSPF Interface 1 enable Enable the backbone interface 6 Attach the network interface to the stub area gt gt OSPF Interface 1 if 2 Select OSPF menu for IP interface 2 gt gt OSPF Interface 2 aindex 1 Attach network to stub area index gt gt OSPF Interface 2 enable Enable the stub area inter
195. t must be placed in the appropriate VLAN The settings are made as follows gt gt VLAN 3 cfg 13 if 1 Appl Save gt gt IP Interface gt gt IP Interface gt gt IP Interface gt gt IP Interface gt gt IP Interface gt gt IP Interface gt gt IP Interface 1 1 2 2 3 3 4 vlan 2 sa Jit 2 vlan 1 E als E vlan 1 if 4 vlan 3 Select Set to Select Set to Select Set to Select Set to IP interface VLAN 2 IP interface VLAN 1 IP interface VLAN 1 IP interface VLAN 3 1 for def routers 2 for first floor 3 for second floor 4 for servers and verify the configuration gt gt gt gt gt gt IP Interface 4 apply IP Interface 4 info 12 vlan Information port Make your changes active View current port information View current VLAN information your new configuration changes gt gt Information save Save for restore after reboot 111 Basic IP routing Dynamic Host Configuration Protocol Dynamic Host Configuration Protocol DHCP is a transport protocol that provides a framework for automatically assigning IP addresses and configuration information to other IP hosts or clients in a large TCP IP network Without DHCP the IP address must be entered manually for each network device DHCP allows a network administrator to distribute IP addresses from a central point and automatically
196. t request it IGMP Snooping prevents multicast traffic from being flooded to all data ports The switch learns which server hosts are interested in receiving multicast traffic and forwards it only to ports connected to those servers The following topics are discussed in this chapter e Overview e IGMPv3 e FastLeave e IGMP Filtering e Static Multicast Router e IGMP Snooping Configuration example Overview Internet Group Management Protocol IGMP is used by IP Multicast routers to learn about the existence of host group members on their directly attached subnet see RFC 2236 The IP Multicast routers get this information by broadcasting IGMP Query Reports and listening for IP hosts reporting their host group memberships This process is used to set up a client server relationship between an IP Multicast source that provides the data streams and the clients that want to receive the data IGMP Snooping conserves bandwidth With IGMP Snooping the switch learns which ports are interested in receiving multicast data and forwards multicast data only to those ports In this way other ports are not burdened with unwanted multicast traffic The switch currently supports snooping for IGMP version 1 version 2 and version 3 The switch can sense IGMP Membership Reports from attached host servers and act as a proxy to set up a dedicated path between the requesting host and a local IP Multicast router After the pathway is established the
197. ta slowing throughput considerably e Traffic to the router increases increasing congestion Even if every end station could be moved to better logical subnets a daunting task competition for access to common server pools on different subnets still burdens the routers This problem is solved by using HP 10GbE switch with built in IP routing capabilities Cross subnet LAN traffic can now be routed within the switches with wire speed Layer 2 switching performance This not only eases the load on the router but saves the network administrators from reconfiguring each and every end station with new IP addresses 107 Basic IP routing Take a closer look at the HP 10GbE switch in the following configuration example Figure 15 Switch based routing topology La gt Bm First Floor P Second Floor P 10 100 Client 10 100 Client Subne 100 20 1 131 151 100 Mbps Primary Default Router 205 21 17 1 Server Subnet 206 30 15 2 254 Secondary Default Router 205 21 17 2 The switch connects the Gigabit Ethernet and Fast Ethernet trunks from various switched subnets throughout one building Common servers are placed on another subnet attached to the switch Primary and backup routers are attached to the switch on yet another subnet Without Layer 3 IP routing on the switch cross subnet communication is relayed to the default gateway in this case the router for the next level of routing intelligence The router fills in
198. tation connected to the network using a Telnet connection Telnet access provides the same options for a user and an administrator as those available through the console port minus certain commands The switch supports four concurrent Telnet connections To establish a Telnet connection with the switch run the Telnet program on your workstation and issue the telnet command followed by the switch IP address Connecting through Secure Shell By default the Secure Shell SSH protocol is disabled on the switch SSH enables you to securely log into another computer over a network to execute commands remotely As a secure alternative to using Telnet to manage switch configuration SSH ensures that all data sent over the network is encrypted and secure For more information see the Secure Shell and Secure Copy section later in this chapter For additional information on the CLI see the HP 10Gb Ethernet Bl c Switch Command Reference Guide Accessing the switch Using the command line interfaces The command line interface CLI can be accessed via local terminal connection or a remote session using Telnet or SSH The CLI is the most direct method for collecting switch information and performing switch configuration The HP 10GbE switch provides two CLI modes The menu based AOS CLI and the tree based ISCLI You can set the HP 10GbE switch to use either CLI mode The Main Menu of the AOS CLI with administrator privileges is displayed belo
199. that determine how a trunk group reacts in any network topology All trunks must originate from one device and lead to one destination device For example you cannot combine a link from Server 1 and a link from Server 2 into one trunk group Any physical switch port can belong to only one trunk group Trunking from non HP devices must comply with Cisco EtherChannel technology All trunk member ports must be assigned to the same VLAN configuration before the trunk can be enabled If you change the VLAN settings of any trunk member you cannot apply the change until you change the VLAN settings of all trunk members When an active port is configured in a trunk the port becomes a trunk member when you enable the trunk using the cfg 12 trunk x ena command The spanning tree parameters for the port then change to reflect the new trunk settings All trunk members must be in the same spanning tree group and can belong to only one spanning tree group However if all ports are tagged then all trunk ports can belong to multiple spanning tree groups When a trunk is enabled the trunk spanning tree participation setting takes precedence over that of any trunk member You cannot configure a trunk member as a monitor port in a Port Mirroring configuration A monitor port cannot monitor trunks however trunk members can be monitored 38 Ports and trunking Port trunking example In this example the 10 Gigabit uplink ports on each s
200. the IP address to another client later Additionally DHCP provides the mechanism for a client to gather other IP configuration parameters it needs to operate in the TCP IP network In the DHCP environment the switch acts as a relay agent The DHCP relay feature c g 13 bootp enables the switch to forward a client request for an IP address to two BOOTP servers with IP addresses that have been configured on the switch When a switch receives a UDP broadcast on port 67 from a DHCP client requesting an IP address the switch acts as a proxy for the client replacing the client source IP SIP and destination IP DIP addresses The request is then forwarded as a UDP Unicast MAC layer message to two BOOTP servers whose IP addresses are configured on the switch The servers respond as a UDP Unicast message back to the switch with the default gateway and IP address for the client The destination IP address in the server response represents the interface address on the switch that received the client request This interface address tells the switch on which VLAN to send the server response to the client 112 Basic IP routing DHCP relay agent configuration To enable the switch to be the BOOTP forwarder you need to configure the DHCP BOOTP server IP addresses on the switch Generally you should configure the command on the switch IP interface closest to the client so that the DHCP server knows from which IP subnet the newly allocated IP address sh
201. the configuration gt gt RMON Alarm 6 apply Make your changes active gt gt RMON Alarm 6 save Save for restore after reboot This configuration creates an RMON alarm that checks if InOctets on port 20 once every hour If the statistic exceeds two billion an alarm is generated that triggers event index 6 161 Remote monitoring Configure RMON Alarms CLI example 2 1 Configure the RMON Alarm parameters to track ICMP messages gt gt cfg rmon alarm 5 Select RMON Alarm 5 gt gt RMON Alarm 5 oid 1 3 6 1 2 1 5 8 0 gt gt RMON Alarm 5 intrval 60 gt gt RMON Alarm 5 almtype rising gt gt RMON Alarm 5 rlimit 200 gt gt RMON Alarm 5 revtidx 5 gt gt RMON Alarm 5 sample delta gt gt RMON Alarm 5 owner Alarm for icmpInEchos 2 Apply and save the configuration gt gt RMON Alarm 5 apply Make your changes active gt gt RMON Alarm 5 save Save for restore after reboot This configuration creates an RMON alarm that checks icmpInEchos on the switch once every minute If the statistic exceeds 200 within a 60 second interval an alarm is generated that triggers event index 5 Configure RMON Alarms BBI example 1 1 Configure an RMON Alarm group a Click the Configure context button b Open the Switch folder and select RMON gt Alarm gt Add Alarm Group HP 10Gb Ethernet BL c Switch E System EG Switch Ports E Port Based Port Mirroring Layer2
202. the topology without forming a loop so that both VLANs can forward packets between the switches without losing connectivity Figure 10 Two VLANs on separate instances of Spanning Tree Protocol VLAN 1 STG 1 20 20 Switch 1 21 21 Switch 2 VLAN 2 STG 1 Spanning Tree Group 1 VLAN 1 Spanning Tree Group 2 VLAN 2 VLAN participation in Spanning Tree Groups The following table shows which switch ports participate in each Spanning Tree Group By default server ports ports 1 16 do not participate in Spanning Tree even though they are members of their respective VLANs Table 12 VLAN participation in Spanning Tree Groups VLAN 1 VLAN 2 Switch 1 Spanning Tree Group 1 Spanning Tree Group 2 Port 20 Port 21 Switch 2 Spanning Tree Group 1 Spanning Tree Group 2 Port 20 Port 21 72 Spanning Tree Protocol Configuring Multiple Spanning Tree Groups This section explains how to assign each VLAN to its own Spanning Tree Group on the switches 1 and 2 By default Spanning Tree Groups 2 127 are empty and Spanning Tree Group 1 contains all configured VLANs until individual VLANs are explicitly assigned to other Spanning Tree Groups Except for the default Spanning Tree Group 1 which may contain more than one VLAN Spanning Tree Groups 2 128 may contain only one VLAN each NOTE Each instance of Spanning Tree Group is enabled by default Configuring Switch 1 CLI example 1 2 Configure port
203. tton b Open the Virtual LANs folder and select Add VLAN Open SI HP 10Gb Ethernet BL c Switch System Eg Switch Ports GA Port Based Port Mirroring 53 Layer 2 802 1x Virtual LANs Select Add Add VLAN 9 Spanning Tree Groups MSTP RSTP E Trunk Groups E Trunk Hash HLACP E UpLink Fast 181 High availability c Configure port 20 as a member of VLAN 10 and port 21 as a member of VLAN 20 Enable each VLAN d Click Submit 2 Configure the following client and server interfaces IF 1 IP address 192 168 1 100 Subnet mask 255 255 255 0 VLAN 10 IF 2 IP address 10 10 12 1 Subnet mask 255 255 255 0 VLAN 20 IF 3 IP address 10 10 12 1 Subnet mask 255 255 255 0 IF 4 IP address 10 10 12 1 Subnet mask 255 255 255 0 182 High availability a Open the IP Interfaces folder and select Add IP Interface HP 10Gb Ethernet BL c Switch i System i Switch Ports i Port Based Port Mirroring Layer 2 RMON Menu Layer3 IP Interfaces Select sdd Add IP Interface Open b ova an IP interface Enter the IP address subnet mask and VLAN membership Enable the intertace c Click Submit 183 High availability 3 Configure the default gateways Each default gateway points to one of the Layer 2 routers a Open the Default Gateways folder and select Add Default Gateway Open HP 10Gb Ethernet BL c Switch fo System GM Switch
204. ual Link 1 nbr 10 10 14 1 Specify the router ID gt gt OSPF Virtual Link 1 enable Specify a virtual link number Specify the transit area for the virtual link of the recipient Enable the virtual link and save the configuration changes gt gt OSPF Interface 2 apply gt gt OSPF Interface 2 save Apply all changes Save all changes Configuring OSPF for a virtual link on Switch B 1 Configure IP interfaces on each network that will be attached to OSPF areas 2 Two IP interfaces are needed on Switch B one for the transit area network on 10 10 12 0 24 and one for the stub area network on 10 10 24 0 24 gt gt cfg 13 if 1 Select menu for IP interface 1 gt gt IP Interface 1 addr 10 10 12 2 Set IP address gt gt IP Interface 1 mask 255 255 255 0 Set IP mask gt gt IP Interface 1 enable gt gt IP Interface 1 if 2 gt gt IP Interface 2 gt gt IP Interface 2 gt gt IP Interface 2 enable addr 10 10 24 1 Set IP address on stub area network mask 255 255 255 0 Set IP mask on stub area network on transit area network on transit area network Enable IP interface 1 Select menu for IP interface 2 Enable IP interface 2 Configure the router ID A router ID is required when configuring virtual links This router ID should be the same one specified as the target virtual neighbor nbr on Switch A gt gt IP Interface 2
205. ual Router Redundancy Protocol Select EJ Add Virtual Router GH VRRP Interfaces General 187 High availability h Configure the IP address for Virtual Router 2 VR2 Enable tracking on ports but set the priority to 100 default value Enable The Virtual Router i Click Submit 5 Turn off Spanning Tree globally a Open the Spanning Tree Groups folder and select Add Spanning Tree Group Open HP 10Gb Ethernet BL c Switch GM Switch Ports GA Port Based Port Mirroring 53 Layer 2 Ga 902 1 Virtual LANs Select 5 Spanning Tree Groups GA MSTP RSTP b Select a Spanning Tree Group 188 High availability 189 High availability c Enter Spanning Tree Group ID 1 and set the Switch Spanning Tree State to off Switch Spanning Tree Group Configuration Spanning Tree Group ID 1 128 Switch Spanning Tree State Bridge Priority 0 65535 Bridge Hello Time 1 10secs Bridge Max Age 6 40secs Bridge Forward Delay 4 30secs VLANs Available VLANs in STG Vian ID Name Vian ID Name 2 VLAN Name Add gt gt 1 Default VLAN ENN emove Switch Spanning Tree Port Configuration Switch Port Port Priority Port Path Cost Port Spanning Tree State 128 2 off 128 2 off d Click Submit 6 Apply verify and save the configuration h tell ip CONFIGURE STATISTICS DASHBOARD invent Apply Save Revert Diff Dump 1 Apply 2 Verify 3 Save 190
206. umber and others Packet classifiers identify flows for more processing The HP 10GbE switch supports up to 384 ACLs Each ACL defines one filter rule Each filter rule is a collection of matching criteria and can include an action permit or deny the packet For example ACL 200 VLAN 1 SIP 10 10 10 1 255 255 255 0 Action permit e Access Control Groups An Access Control Group ACL Group is a collection of ACLs For example ACL Group 1 ACL 382 VLAN 1 SIP 10 10 10 1 255 255 255 0 Action permit ACL 383 VLAN 2 SIP 10 10 10 2 255 255 255 0 Action deny ACL 384 PRI 7 DIP 10 10 10 3 255 255 0 0 Action permit In the example above each ACL defines a filter rule ACL 383 has a higher precedence than ACL 382 based on its number Use ACL Groups to create a traffic profile by gathering ACLs into an ACL Group and assigning the ACL Group to a port The HP TOGbE switch supports up to 384 ACL Groups Each ACL group supports up to 96 ACLs 90 Quality of Service ACL Metering and Re marking You can define a profile for the aggregate traffic flowing through the HP 10GbE switch by configuring a QoS meter if desired and assigning ACL Groups to ports When you add ACL Groups to a port make sure they are ordered correctly in terms of precedence For example consider two ACL Groups ACL Group 1 and ACL Group 2 Each contains three levels of precedence If you add
207. ure the RMON agent on the switch so the switch can exchange network monitoring data High Availability describes how the HP 10GbE switch supports high availability network topologies This release provides Uplink Failure Detection and Virtual Router Redundancy Protocol VRRP Troubleshooting tools describes Port Mirroring and other troubleshooting techniques Accessing the switch Additional references Additional information about installing and configuring the switch is available in the following guides which are available at http www hp com go bladesystem documentation HP 10Gb Ethernet BL c Switch User Guide HP 10Gb Ethernet BL c Switch Command Reference Guide HP 10Gb Ethernet BL c Switch ISCLI Reference Guide HP 10Gb Ethernet BL c Switch Browser based Interface Reference Guide HP 10Gb Ethernet BL c Switch Quick Setup Instructions Typographical conventions The following table describes the typographic styles used in this guide Table 1 Typographic conventions Typeface or Meaning Example symbol AaBbCc123 This type depicts onscreen computer output and prompts Main AaBbCc123 This type displays in command examples and shows text Main sys that must be typed in exactly as shown lt AaBbCc123 gt This bracketed type displays in command examples asa To establish a Telnet session enter parameter placeholder Replace the indicated text with host telnet lt IP address gt the appropriate real na
208. uting updates RIP sends routing update messages at regular intervals and when the network topology changes Each router advertises routing information by sending a routing information update every 30 seconds If a router doesn t receive an update from another router for 180 seconds those routes provided by that router are declared invalid After another 120 seconds without receiving an update for those routes the routes are removed from the routing table and respective regular updates When a router receives a routing update that includes changes to an entry it updates its routing table to reflect the new route The metric value for the path is increased by 1 and the sender is indicated as the next hop RIP routers maintain only the best route the route with the lowest metric value to a destination For more information see The Configuration Menu Routing Information Protocol Configuration cfg 13 rip in the HP 10Gb Ethernet BL c Switch Command Reference 114 Routing Information Protocol RIPv I RIP version 1 use broadcast User Datagram Protocol UDP data packets for the regular routing updates The main disadvantage is that the routing updates do not carry subnet mask information Hence the router cannot determine whether the route is a subnet route or a host route It is of limited usage after the introduction of RIPv2 For more information about RIPv1 and RIPv2 refer to RFC 1058 and RFC 2453 RIPv2 RIPv2 is the most popular
209. vides security to ports of the HP 1OGbE switch that connect to servers Port based Traffic Control allows the switch to guard against broadcast storms VLANs describes how to configure Virtual Local Area Networks VLANs for creating separate network segments including how to use VLAN tagging for devices that use multiple VLANs Spanning Tree Protocol discusses how spanning trees configure the network so that the switch uses the most efficient path when multiple paths exist Rapid Spanning Tree Protocol Multiple Spanning Tree Protocol describes extensions to the Spanning Tree Protocol that provide rapid convergence of spanning trees for fast reconfiguration of the network Quality of Service discusses Quality of Service features including IP filtering using Access Control Lists Differentiated Services and IEEE 802 1p priority values Basic IP Routing describes how to configure the HP 10GbE switch for IP routing using IP subnets and DHCP Relay Routing Information Protocol describes how the HP 10GbE switch software implements standard Routing Information Protocol RIP for exchanging TCP IP route information with other routers IGMP Snooping describes how to use IGMP to conserve bandwidth in a multicast switching environment OSPF describes OSPF concepts how OSPF is implemented and examples of how to configure your switch for OSPF support Remote Monitoring describes how to config
210. vior The DSCP value determines the Per Hop Behavior PHB of each packet The PHB is the forwarding treatment given to packets at each hop QoS policies are built by applying a set of rules to packets based on the DSCP value as they hop through the network The HP 10GbE switch default settings are based on the following standard PHBs as defined in the IEEE standards e Expedited Forwarding EF This PHB has the highest egress priority and lowest drop precedence level EF traffic is forwarded ahead of all other traffic EF PHB is described in RFC 2598 e Assured Forwarding AF This PHB contains four service levels each with a different drop precedence as shown below Routers use drop precedence to determine which packets to discard last when the network becomes congested AF PHB is described in RFC 2597 Table 17 Assured forwarding drop down precedence Drop Precedence Class 1 Class 2 Class 3 Class 4 Low AF11 DSCP 10 AF21 DSCP 18 AF31 DSCP 26 AF41 DSCP 34 Medium AF12 DSCP 12 AF22 DSCP 20 AF32 DSCP 28 AF42 DSCP 36 High AF13 DSCP 14 AF23 DSCP 22 AF33 DSCP 30 AF43 DSCP 38 Quality of Service e Class Selector CS This PHB has eight priority classes with CS7 representing the highest priority and CSO representing the lowest priority as shown below CS PHB is described in RFC 2474 Table 18 Class selector priority classes Priority Class Selector DSCP Highest CS7 5
211. w Main Menu info Information Menu stats Statistics Menu cfg Configuration Menu oper Operations Command Menu boot Boot Options Menu maint Maintenance Menu diff Show pending config changes global command apply Apply pending config changes global command save Save updated config to FLASH global command revert Revert pending or applied changes global command exit Exit global command always available For complete information about the AOS CLI see the HP 10Gb Ethernet Bl c Switch Command Reference Guide The ISCLI provides a tree based command structure for users familiar with similar products An example of a typical ISCLI command is displayed below Switch config spanning tree stp 1 enable For complete information about the ISCLI refer to the ISCLI Reference Guide Configuring an IP interface An IP interface address must be set on the switch to provide management access to the switch over an IP network By default the management interface is set up to request its IP address from a Bootstrap Protocol BOOTP server If you have a BOOTP server on your network add the Media Access Control MAC address of the switch to the BOOTP configuration file located on the BOOTP server The MAC address can be found on a small white label on the back panel of the switch The MAC address can also be found in the System Information menu see the HP 10Gb Ethernet Bl c Switch Command Reference Guide or ISCLI Guide If you are using
212. w and the current configurations e putcfg apply runs the apply command after the putcfg is done e putcfg apply save saves the new configuration to the flash after putcfg apply is done e The putcfg apply and putcfg apply save commands are provided because extra apply and save commands are usually required after a putcfg SSH and SCP encryption of management messages The following encryption and authentication methods are supported for SSH and SCP e Server Host Authentication Client RSA authenticates the switch at the beginning of every connection e Key Exchange RSA e Encryption AES256 CBC AES192 CBC 3DES CBC 3DES ARCFOUR e User Authentication Local password authentication RADIUS TACACS Generating RSA host and server keys for SSH access To support the SSH server feature two sets of RSA keys host and server keys are required The host key is 1024 bits and is used to identify the switch The server key is 768 bits and is used to make it impossible to decipher a captured session by breaking into the switch at a later time When the SSH server is first enabled and applied the switch automatically generates the RSA host and server keys and is stored in the flash memory To configure RSA host and server keys first connect to the switch console connection commands are not available via Telnet connection and enter the following commands to generate them manually gt gt cfg sys sshd hkeygen Generates the host ke
213. westnumbered ACL has the lowest precedence level and the highest numbered ACL has the highest precedence level However the other ACLs within the Precedence Group have an unspecified precedence level as follows ACL 1 lowest precedence level within Precedence Group 1 ACL 2 unspecified precedence level within Precedence Group 1 ACL 3 unspecified precedence level within Precedence Group 1 ACL 126 unspecified precedence level within Precedence Group 1 ACL 127 unspecified precedence level within Precedence Group 1 ACL 128 highest precedence level within Precedence Group 1 89 Quality of Service Using ACL Groups Access Control Lists ACLs allow you to classify packets according to a particular content in the packet header such as the source address destination address source port number destination port number and others Packet classifiers identify flows for more processing You can define a traffic profile by compiling a number of ACLs into an ACL Group and assigning the ACL Group to a port ACL Groups are assigned and enabled on a per port basis Each ACL can be used by itself or in combination with other ACLs or ACL Groups on a given switch port ACLs can be grouped in the following manner e Access Control Lists Access Control Lists ACLs allow you to classify packets according to a particular content in the packet header such as the source address destination address source port number destination port n
214. witch e Increases the cost of all of the external ports by 3000 across all VLANs and Spanning Tree Groups This ensures that traffic never flows through the switch to get to another switch unless there is no other path When you disable Fast Uplink Convergence the bridge priorities and path cost are set to their default values for all STP groups Configuring Fast Uplink Convergence Use the following CLI commands to enable Fast Uplink Convergence on external ports gt gt cfg 12 upfast ena Enable Fast Uplink convergence gt gt Layer 2 apply Make your changes active gt gt Layer 2 save Save for restore after reboot 76 RSTP and MSTP Introduction Rapid Spanning Tree Protocol IEEE 802 1w enhances the Spanning Tree Protocol IEEE 802 1d to provide rapid convergence on Spanning Tree Group 1 Multiple Spanning Tree Protocol IEEE 802 1s extends the Rapid Spanning Tree Protocol to provide both rapid convergence and load balancing in a VLAN environment The following topics are discussed in this chapter e Rapid Spanning Tree Protocol RSTP e Multiple Spanning Tree Protocol MSTP Rapid Spanning Tree Protocol Rapid Spanning Tree Protocol RSTP provides rapid convergence of the spanning tree and provides for fast reconfiguration critical for networks carrying delay sensitive traffic such as voice and video RSTP significantly reduces the time to reconfigure the active topology of the network when chang
215. witch allows you to classify packets based on various parameters such as e Ethernet Source MAC address mask Destination MAC address mask VLAN number mask Ethernet type o Ethernet Priority which is the IEEE 802 1p Priority e Pv4 o Source IP address mask O Oo Q o Destination IP address mask o Type of Service value o IP protocol number The protocol number or name as shown in the following table Table 14 Well known protocol types Number Protocol Name 1 icmp 2 igmp 6 tcp 17 udp 87 Quality of Service Table 14 Well known protocol types Number Protocol Name 89 ospf 112 vrrp e TCP UDP o TCP UDP application source port as shown in the table titled Well Known Application Ports o TCP UDP application destination port as shown in the table titled Well Known Application Ports o TCP UDP flag value as shown in the table titled Well Known TCP Flag Values Table 15 Well known application ports Number TCP UDP Number TCP UDP Number TCP UDP Application Application Application 20 ftp data 79 finger 179 irc 21 ftp 80 http 194 imap3 22 ssh 109 pop2 220 ldap 23 telnet 110 pop3 389 https 25 smtp 111 sunrpc 443 rip 37 time 119 nntp 520 rtsp 42 name 123 ntp 554 Radius 43 whois 143 imap 1645 1812 Radius Accounting 53 domain 144 news 1813 hsrp 69 tftp 161 snmp 1985 70 gopher 162 snmptrap Table 16 Well krown TCP flag value
216. witch are configured into a total of four trunk groups two on each switch NOTE The actual mapping of switch ports to NIC interfaces is dependant on the operating system software the type of server blade and the enclosure type For more information see the HP 10Gb Ethernet Bl c Switch User Guide Figure 1 Port trunk group configuration example 10 Gigabit Uplinks 18 19 20 21 21 20 19 18 WS KK lt GP AXONS SS SSS DZ LD I Backplane 123 1123 1 23 1 2 3 12 3 12 3 12 3 pi 4 4 4 4 4 4 4 4 Q wn Q n n n n n o o o oO 2 2 2 2 2 2 2 2 S UT 8 8 8 8 2 N w gt a a s 10958EA The trunk groups are configured as follows Trunk groups 2 5 consist of two 10 Gigabit uplink ports each configured to act as a single link to the upstream routers The trunk groups on each switch are configured so that there is a link to each router for redundancy Prior to configuring each switch in this example you must connect to the appropriate switch CLI as the administrator For details about accessing and using any of the commands described in this example see the HP 10Gb Ethernet BL c Switch Command Reference 39 Ports and trunking Configuring trunk groups CLI example 1 On Switch 1 configure trunk groups 5 and 3 cfg l2 trunk 5 Select trunk group 5 Trunk group 5 add 20 Add port 20 to trunk group 5 Trunk group 5 add 21
217. work 7 5 Va Network a Network EN 10 10 10 1 or HP Blade Chassis Sea Router ID 10 10 14 1 Configuring OSPF for a virtual link on Switch A 1 Configure IP interfaces on each network that will be attached to the switch In this example two IP interfaces are needed on Switch A one for the backbone network on 10 10 7 0 24 and one for the transit area network on 10 10 12 0 24 gt gt cfg 13 if 1 Select menu for IP interface 1 gt gt IP Interface 1 addr 10 10 7 1 Set IP address on backbone network gt gt IP Interface 1 mask 255 255 255 0 Set IP mask on backbone network gt gt IP Interface 1 enable Enable IP interface 1 gt gt IP Interface 1 if 2 Select menu for IP interface 2 2 addr 10 10 12 1 Set IP address on transit area network gt gt IP Interface 2 mask 255 255 255 0 Set IP mask on transit area network gt gt IP Interface 2 enable Enable interface 2 gt gt IP Interface 2 Configure the router ID 3 A router ID is required when configuring virtual links Later when configuring the other end of the virtual link on Switch B the router ID specified here will be used as the target virtual neighbor nbr address gt gt IP Interface 2 cfg 13 rtrid 10 10 10 1 Set static router ID 4 Enable OSPF gt gt IP cfg 13 ospf on 5 Define the backbone gt gt Open Shortest Path First aindex 0 Select menu for area index 0 gt
218. work so that a switch uses only the most efficient path If that path fails STP automatically sets up another active path on the network to sustain network operations The switch supports IEEE 802 1d Spanning Tree Protocol for STG 1 and Per VLAN Spanning Tree Protocol PVST for STGs 2 128 by default NOTE The switch also supports IEEE 802 1w Rapid Spanning Tree Protocol and IEEE 802 1s Multiple Spanning Tree Protocol For more information see the RSTP and MSTP chapter in this guide Bridge Protocol Data Units To create a spanning tree the application switch generates a configuration Bridge Protocol Data Unit BPDU which it then forwards out of its ports All switches in the Layer 2 network participating in the spanning tree gather information about other switches in the network through an exchange of BPDUs A BPDU is a 64 byte packet that is sent out at a configurable interval which is typically set for two seconds The BPDU is used to establish a path much like a hello packet in IP routing BPDUs contain information about the transmitting bridge and its ports including bridge and MAC addresses bridge priority port priority and port path cost If the ports are tagged each port sends out a special BPDU containing the tagged information The generic action of a switch on receiving a BPDU is to compare the received BPDU to its own BPDU that it will transmit If the received BPDU has a priority value closer to zero than its own
219. y gt gt cfg sys sshd skeygen Generates the server key These two commands take effect immediately without the need of an apply command When the switch reboots it will retrieve the host and server keys from the flash memory If these two keys are not available in the flash memory and if the SSH server feature is enabled the switch automatically generates them during the system reboot This process may take several minutes to complete The switch can also automatically regenerate the RSA server key To set the interval of RSA server key autogeneration use the following command gt gt cfg sys sshd intrval lt number of hours 0 24 gt 33 Accessing the switch A value of O denotes that RSA server key autogeneration is disabled When greater than O the switch will auto generate the RSA server key every specified interval however RSA server key generation is skipped if the switch is busy doing other key or cipher generation when the timer expires The switch will perform only one session of key cipher generation at a time Thus an SSH SCP client will not be able to log in if the switch is performing key generation at that time or if another client has logged in immediately prior Also key generation will fail if an SSH SCP client is logging in at that time SSH SCP integration with RADIUS and TACACS authentication SSH SCP is integrated with RADIUS and TACACS authentication After the RADIUS or TACACS server is e
220. y samples History MIB objects The type of data that can be sampled must be of an iflndex object type as described in RFC1213 and RFC1573 The most common data type for the history sample is as follows 1 3 6 1 2 1 2 2 1 1 x mgmt interfaces ifTable ifIndex interface The last digit x represents the interface on which to monitor which corresponds to the port number 1 16 18 21 History sampling is done per port by utilizing the interface number to specify the port number Configure RMON History CLI example 1 Enable RMON on each port where you wish to collect RMON History gt gt gt gt gt gt gt gt cfg port 21 rmon Select Port 21 RMON P Port 21 RMON apply Port 21 RMON save ort 21 ena Enable RMON Make your changes active Save for restore after reboot 2 Configure the RMON History parameters gt gt gt gt gt gt gt gt gt gt cfg rmon hist 1 RI RI RI RI MON History 1 MON History 1 MON History 1 MON History 1 Select RMON History 1 fold 1 3 46 1 22 222142221 rbnum 30 intrval 120 owner Owner History 1 3 Apply and save the configuration gt gt RMON History 1 apply gt gt RMON History 1 save Make your changes active Save for restore after reboot This configuration creates an RMON History group to monitor port 21 It takes a data sample every two minutes and places the dat
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