Reference Guide
Table Of Contents
- OS10 Enterprise Edition User Guide Release 10.3.0E
- Getting Started
- Download OS10 image and license
- Installation
- Log into OS10
- Install OS10 license
- Remote access
- Upgrade OS10
- CLI Basics
- User accounts
- Key CLI features
- CLI command modes
- CLI command hierarchy
- CLI command categories
- CONFIGURATION Mode
- Command help
- Check device status
- Candidate configuration
- Backup or restore configuration
- Reload system image
- Filter show commands
- Alias command
- Batch mode commands
- Linux shell commands
- SSH commands
- OS9 environment commands
- Common OS10 Commands
- alias
- batch
- boot
- commit
- configure
- copy
- delete
- dir
- discard
- do
- feature config-os9-style
- exit
- license
- lock
- management route
- move
- no
- reload
- show alias
- show boot
- show candidate-configuration
- show environment
- show inventory
- show ip management-route
- show ipv6 management-route
- show license status
- show running-configuration
- show startup-configuration
- show system
- show version
- system
- terminal
- traceroute
- unlock
- write
- Interfaces
- Enable Ethernet interfaces
- L2 mode configuration
- L3 mode configuration
- Management interface
- VLAN interfaces
- Loopback interfaces
- Port-channel interfaces
- Create port-channel
- Add port member
- Minimum links
- Assign IP address
- Remove or disable port-channel
- Load balance traffic
- Change hash algorithm
- Configure interface ranges
- Configure FEC
- View interface configuration
- Interface commands
- channel-group
- description (Interface)
- duplex
- fec
- interface breakout
- interface ethernet
- interface loopback
- interface mgmt
- interface null
- interface port-channel
- interface range
- interface vlan
- link-bundle-utilization
- mgmt
- mtu
- show interface
- show link-bundle-utilization
- show port-channel summary
- show vlan
- shutdown
- speed
- switchport access vlan
- switchport mode
- switchport trunk allowed vlan
- Layer 2
- 802.1X
- Link aggregation control protocol
- Link layer discovery protocol
- Protocol data units
- Optional TLVs
- Organizationally-specific TLVs
- Media endpoint discovery
- Network connectivity device
- LLDP-MED capabilities TLV
- Network policies TLVs
- Define network policies
- Packet timer values
- Disable and re-enable LLDP
- Advertise TLVs
- Network policy advertisement
- Fast start repeat count
- View LLDP configuration
- Adjacent agent advertisements
- Time to live
- LLDP commands
- Media Access Control
- Multiple spanning-tree protocol
- Rapid per-VLAN spanning-tree plus
- Rapid spanning-tree protocol
- Virtual LANs
- Port monitoring
- Layer 3
- Border gateway protocol
- Sessions and peers
- Route reflectors
- Multiprotocol BGP
- Attributes
- Selection criteria
- Weight and local preference
- Multiexit discriminators
- Origin
- AS path and next-hop
- Best path selection
- More path support
- Advertise cost
- 4-Byte AS numbers
- AS number migration
- Configure border gateway protocol
- Enable BGP
- Configure Dual Stack
- Peer templates
- Neighbor fall-over
- Fast external fallover
- Passive peering
- Local AS
- AS number limit
- Redistribute routes
- Additional paths
- MED attributes
- Local preference attribute
- Weight attribute
- Enable multipath
- Route-map filters
- Route reflector clusters
- Aggregate routes
- Confederations
- Route dampening
- Timers
- Neighbor soft-reconfiguration
- BGP commands
- Equal cost multi-path
- IPv4 routing
- IPv6 routing
- Open shortest path first
- Autonomous system areas
- Areas, networks, and neighbors
- Router types
- Designated and backup designated routers
- Link-state advertisements
- Router priority
- Enable OSPF
- Assign router identifier
- Stub areas
- Passive interfaces
- Fast convergence
- Interface parameters
- Redistribute routes
- Troubleshoot OSPF
- OSPFv3
- OSPF commands
- OSPFv3 Commands
- Object tracking manager
- Policy-based routing
- Virtual router redundancy protocol
- Border gateway protocol
- System management
- Access Control Lists
- IP ACLs
- MAC ACLs
- IP fragment handling
- L3 ACL rules
- Assign sequence number to filter
- L2 and L3 ACLs
- Assign and apply ACL filters
- Ingress ACL filters
- Egress ACL filters
- Clear access-list counters
- IP prefix-lists
- Route-maps
- Match routes
- Set conditions
- continue Clause
- ACL flow-based monitoring
- Enable flow-based monitoring
- ACL commands
- clear ip access-list counters
- clear ipv6 access-list counters
- clear mac access-list counters
- deny
- deny (IPv6)
- deny (MAC)
- deny icmp
- deny icmp (IPv6)
- deny ip
- deny ipv6
- deny tcp
- deny tcp (IPv6)
- deny udp
- deny udp (IPv6)
- description
- ip access-group
- ip access-list
- ip as-path deny
- ip as-path permit
- ip community-list standard deny
- ip community–list standard permit
- ip extcommunity-list standard deny
- ip extcommunity-list standard permit
- ip prefix-list description
- ip prefix-list deny
- ip prefix-list permit
- ip prefix-list seq deny
- ip prefix-list seq permit
- ipv6 access-group
- ipv6 access-list
- ipv6 prefix-list deny
- ipv6 prefix-list description
- ipv6 prefix-list permit
- ipv6 prefix-list seq deny
- ipv6 prefix-list seq permit
- mac access-group
- mac access-list
- permit
- permit (IPv6)
- permit (MAC)
- permit icmp
- permit icmp (IPv6)
- permit ip
- permit ipv6
- permit tcp
- permit tcp (IPv6)
- permit udp
- permit udp (IPv6)
- remark
- seq deny
- seq deny (IPv6)
- seq deny (MAC)
- seq deny icmp
- seq deny icmp (IPv6)
- seq deny ip
- seq deny ipv6
- seq deny tcp
- seq deny tcp (IPv6)
- seq deny udp
- seq deny udp (IPv6)
- seq permit
- seq permit (IPv6)
- seq permit (MAC)
- seq permit icmp
- seq permit icmp (IPv6)
- seq permit ip
- seq permit ipv6
- seq permit tcp
- seq permit tcp (IPv6)
- seq permit udp
- seq permit udp (IPv6)
- show access-group
- show access-lists
- show ip as-path-access-list
- show ip community-list
- show ip extcommunity-list
- show ip prefix-list
- Route-map commands
- continue
- match as-path
- match community
- match extcommunity
- match interface
- match ip address
- match ip next-hop
- match ipv6 address
- match ipv6 next-hop
- match metric
- match origin
- match route-type
- match tag
- route-map
- set comm-list delete
- set community
- set extcomm-list delete
- set extcommunity
- set local-preference
- set metric
- set metric-type
- set next-hop
- set origin
- set tag
- set weight
- show route-map
- Quality of service
- Configure quality of service
- Class-map configuration
- Policy-map configuration
- Ingress traffic priorities
- Queue selection
- Strict priority queuing
- Class of service or dot1p classification
- Mark traffic
- Traffic metering
- Bandwidth allocation
- Service-policy rate-shaping
- Policy-based rate-policing
- Control-plane policing
- Congestion avoidance
- Verify configuration
- Egress queue statistics
- QoS commands
- bandwidth
- class
- class-map
- clear interface priority-flow-control
- clear qos statistics
- clear qos statistics type
- control-plane
- flowcontrol
- match
- match cos
- match dscp
- match precedence
- match qos-group
- match vlan
- mtu
- pause
- pfc-cos
- pfc-shared-buffer-size
- police
- policy-map
- priority
- priority-flow-control mode
- qos-group dot1p
- qos-group dscp
- queue-limit
- queue qos-group
- random-detect
- service-policy
- set cos
- set dscp
- set qos-group
- shape
- show class-map
- show control-plane info
- show control-plane statistics
- show interface priority-flow-control
- show qos interface
- show policy-map
- show qos control-plane
- show qos egress bufffers interface
- show egress buffer-stats interface
- show qos ingress buffers interface
- show ingress buffer-stats interface
- show queuing statistics
- show qos system
- show qos system buffers
- show qos maps
- system qos
- trust
- trust dot1p-map
- trust dscp-map
- qos-map traffic-class
- trust-map
- Virtual link trunking
- Converged data center services
- sFlow
- Troubleshoot OS10
- Support resources
Stateless autoconguration uses three mechanisms for IPv6 address conguration:
Prex advertisement Routers use router advertisement messages to announce the network prex. Hosts use their interface-identier
MAC address to generate a valid IPv6 address.
Duplicate address
detection
An IPv6 host node device checks whether that address is used anywhere on the network duplicate address
detection (DAD) before conguring its IPv6 address.
Prex renumbering Transparent renumbering of hosts in the network when an organization changes its service provider.
As an alternative to stateless autoconguration, network hosts can obtain their IPv6 addresses using DHCP servers via stateful
autoconguration.
IPv6 provides the exibility to add prexes on router advertisements (RA) to advertise responses to router solicitations (RS). RA response
messages are sent when an RS message is received by default. The system manipulation of IPv6 stateless autoconguration supports the
router side only. Neighbor discovery (ND) messages advertise so the neighbor can use this information to auto-congure its address.
Received ND messages are not used to create an IPv6 address.
Inconsistencies in router advertisement values between routers are logged. The values checked for consistency include:
• Current hop limit
• M and O ags
• Reachable time
• Retransmission timer
• MTU options
• Preferred and valid lifetime values for the same prex
The router redirect functionality in the NDP is similar to IPv4 router redirect messages. NDP uses ICMPv6 redirect messages (Type 137) to
inform nodes that a better router exists on the link.
DHCP address assignment
DHCPv6 enables DHCP servers to pass conguration parameters (such as IPv6 network addresses) to IPv6 clients. The address
assignment feature manages non-duplicate address assignment in the correct prex based on the network where the host is connected.
Assigned IPv6 addresses can be from one or multiple prex pools. Additional options, such as default domain and DNS name-server
address, can be passed back to the client. Address pools can be assigned for use on a specic interface, on multiple interfaces, or the
server can automatically nd the appropriate pool.
Static routing
Static routes are manually congured and dene an explicit route between two networking devices. Static routes are useful for smaller
networks with only one path to an outside network or to provide security for certain types of trac in a larger network.
IPv6 addresses
IPv6 128-bit addresses are represented as a series of eight 16-bit hexadecimal elds separated by colons in the format: n:n:n:n:n:n:n:n. This
is an example of an IPv6 address:
2001:0db8:0000:0000:0000:0000:1428:57a
254
Layer 3