- Index
- Preface
- Product Overview
- Command-Line Interfaces
- Smart Port Macros
- Virtual Switching Systems (VSS)
- Enhanced Fast Software Ugrade (eFSU)
- NSF with SSO Supervisor Engine Redundancy
- RPR Supervisor Engine Redundancy
- Interface Configuration
- UniDirectional Link Detection (UDLD)
- Power Management and Environmental Monitoring
- EnergyWise
- Online Diagnostics
- Onboard Failure Logging
- Switch Fabric Functionality
- Cisco IP Phone Support
- Power over Ethernet
- Layer 2 LAN Ports
- Flex Links
- EtherChannels
- mLACP for Server Access
- IEEE 802.1ak MVRP and MRP
- VLAN Trunking Protocol (VTP)
- VLANs
- Private VLANs (PVLANs)
- Private Hosts
- IEEE 802.1Q Tunneling
- Layer 2 Protocol Tunneling
- STP and MST
- Optional STP Features
- Layer 3 Interface Configuration
- Unidirectional Ethernet (UDE) and unidirectional link routing (UDLR)
- Multiprotocol Label Switching (MPLS)
- L2VPN Advanced VPLS (A-VPLS)
- IP Unicast Layer 3 Switching
- IPv6 Multicast Layer 3 Switching
- MLD Snooping for IPv6 Multicast Traffic
- IPv4 Multicast Layer 3 Switching
- IGMP Snooping and MVR for IPv4 Multicast Traffic
- Configuring MVR for IPv4 Multicast Traffic
- IPv4 IGMP Filtering and Router Guard
- PIM Snooping
- IPv4 Multicast VPN Support
- PFC QoS
- AutoQoS
- MPLS QoS
- PFC QoS Statistics Data Export
- Network Security
- AutoSecure
- Cisco IOS ACL Support
- Cisco TrustSec (CTS)
- Port ACLs (PACLs) and VLAN ACLs (VACLs)
- Denial of Service Protection
- Control Plane Policing (CoPP)
- DHCP Snooping
- IP Source Guard
- Dynamic ARP Inspection
- Traffic Storm Control
- Unknown Unicast and Multicast Flood Control
- Network Admission Control (NAC)
- IEEE 802.1X Port-Based Authentication
- Web-Based Authentication
- Port Security
- NetFlow
- NetFlow Data Export (NDE)
- Call Home
- System Event Archive (SEA)
- Backplane Platform Monitoring
- SPAN, RSPAN, and ERSPAN
- SNMP IfIndex Persistence
- Top-N Reports
- Layer 2 Traceroute Utility
- Mini Protocol Analyzer
- Ethernet Services Line Cards
- Online Diagnostic Tests
- Acronyms
Configuring IP Unicast Layer 3 Switching
This chapter describes how to configure IP unicast Layer 3 switching in Cisco IOS Release 12.2SX.
Note 
For complete syntax and usage information for the commands used in this chapter, see these publications:
•The Cisco IOS Master Command List, at this URL:
http://www.cisco.com/en/US/docs/ios/mcl/allreleasemcl/all_book.html
•The Release 12.2 publications at this URL:
Tip For additional information about Cisco Catalyst 6500 Series Switches (including configuration examples and troubleshooting information), see the documents listed on this page:
http://www.cisco.com/en/US/products/hw/switches/ps708/tsd_products_support_series_home.html
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This chapter consists of these sections:
•Understanding Layer 3 Switching
•Default Hardware Layer 3 Switching Configuration
•Configuration Guidelines and Restrictions
•Configuring Hardware Layer 3 Switching
•Displaying Hardware Layer 3 Switching Statistics
Note•IPX traffic is fast switched on the route proccessor (RP). For more information, see this URL:
http://www.cisco.com/en/US/docs/ios/12_2/atipx/configuration/guide/fatipx_c.html
•For information about IP multicast Layer 3 switching, see Chapter 37 "Configuring IPv4 Multicast Layer 3 Switching."
Understanding Layer 3 Switching
These sections describe Layer 3 switching:
•Understanding Hardware Layer 3 Switching
•Understanding Layer 3-Switched Packet Rewrite
Understanding Hardware Layer 3 Switching
Hardware Layer 3 switching allows the PFC and DFCs, instead of the RP, to forward IP unicast traffic between subnets. Hardware Layer 3 switching provides wire-speed forwarding on the PFC and DFCs, instead of in software on the RP. Hardware Layer 3 switching requires minimal support from the RP. The RP routes any traffic that cannot be hardware Layer 3 switched.
Hardware Layer 3 switching supports the routing protocols configured on the RP. Hardware Layer 3 switching does not replace the routing protocols configured on the RP.
Hardware Layer 3 switching runs equally on the PF3 and DFCs to provide IP unicast Layer 3 switching locally on each module. Hardware Layer 3 switching provides the following functions:
•Hardware access control list (ACL) switching for policy-based routing (PBR)
•Hardware flow-based switching for TCP intercept and reflexive ACL forwarding decisions
•Hardware Cisco Express Forwarding (CEF) switching for all other IP unicast traffic
Hardware Layer 3 switching on the PFC supports modules that do not have a DFC. The RP forwards traffic that cannot be Layer 3 switched.
Traffic is hardware Layer 3 switched after being processed by access lists and quality of service (QoS).
Hardware Layer 3 switching makes a forwarding decision locally on the ingress-port module for each packet and sends the rewrite information for each packet to the egress port, where the rewrite occurs when the packet is transmitted from the switch.
Hardware Layer 3 switching generates flow statistics for Layer 3-switched traffic. Hardware Layer 3 flow statistics can be used for NetFlow Data Export (NDE). (See Chapter 64 "Configuring NDE".)
Understanding Layer 3-Switched Packet Rewrite
When a packet is Layer 3 switched from a source in one subnet to a destination in another subnet, the switch performs a packet rewrite at the egress port based on information learned from the RP so that the packets appear to have been routed by the RP.
Packet rewrite alters five fields:
•Layer 2 (MAC) destination address
•Layer 2 (MAC) source address
•Layer 3 IP Time to Live (TTL)
•Layer 3 checksum
•Layer 2 (MAC) checksum (also called the frame checksum or FCS)
Note Packets are rewritten with the encapsulation appropriate for the next-hop subnet.
If Source A and Destination B are in different subnets and Source A sends a packet to the RP to be routed to Destination B, the switch recognizes that the packet was sent to the Layer 2 (MAC) address of the RP.
To perform Layer 3 switching, the switch rewrites the Layer 2 frame header, changing the Layer 2 destination address to the Layer 2 address of Destination B and the Layer 2 source address to the Layer 2 address of the RP. The Layer 3 addresses remain the same.
In IP unicast and IP multicast traffic, the switch decrements the Layer 3 TTL value by 1 and recomputes the Layer 3 packet checksum. The switch recomputes the Layer 2 frame checksum and forwards (or, for multicast packets, replicates as necessary) the rewritten packet to Destination B's subnet.
A received IP unicast packet is formatted (conceptually) as follows:
|
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|
|
|
||||
|---|---|---|---|---|---|---|---|
Destination |
Source |
Destination |
Source |
TTL |
Checksum |
||
RP MAC |
Source A MAC |
Destination B IP |
Source A IP |
n |
calculation1 |
||
After the switch rewrites an IP unicast packet, it is formatted (conceptually) as follows:
|
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|
|
|
||||
|---|---|---|---|---|---|---|---|
Destination |
Source |
Destination |
Source |
TTL |
Checksum |
||
Destination B MAC |
RP MAC |
Destination B IP |
Source A IP |
n-1 |
calculation2 |
||
Hardware Layer 3 Switching Examples
Figure 34-1 shows a simple network topology. In this example, Host A is on the Sales VLAN (IP subnet 171.59.1.0), Host B is on the Marketing VLAN (IP subnet 171.59.3.0), and Host C is on the Engineering VLAN (IP subnet 171.59.2.0).
When Host A initiates an HTTP file transfer to Host C, Hardware Layer 3 switching uses the information in the local forwarding information base (FIB) and adjacency table to forward packets from Host A to Host C.
Figure 34-1 Hardware Layer 3 Switching Example Topology
Default Hardware Layer 3 Switching Configuration
Table 34-1 shows the default hardware Layer 3 switching configuration.
|
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|
|---|---|
Hardware Layer 3 switching enable state |
Enabled (cannot be disabled) |
Cisco IOS CEF enable state on RP |
Enabled (cannot be disabled) |
Cisco IOS dCEF1 enable state on RP |
Enabled (cannot be disabled) |
1 dCEF = Distributed Cisco Express Forwarding |
Configuration Guidelines and Restrictions
Follow these guidelines and restrictions when configuring hardware Layer 3 switching:
•Hardware Layer 3 switching supports the following ingress and egress encapsulations:
–Ethernet V2.0 (ARPA)
–802.3 with 802.2 with 1 byte control (SAP1)
Configuring Hardware Layer 3 Switching
Note For information on configuring unicast routing on the RP, see Chapter 30 "Configuring Layer 3 Interfaces."
Hardware Layer 3 switching is permanently enabled. No configuration is required.
To display information about Layer 3-switched traffic, perform this task:
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|---|---|
Router# show interface {{type1 slot/port} | {port-channel number}} | begin L3 |
Displays a summary of Layer 3-switched traffic. |
1 type = fastethernet, gigabitethernet, or tengigabitethernet |
This example shows how to display information about hardware Layer 3-switched traffic on Fast Ethernet port 3/3:
Router# show interface fastethernet 3/3 | begin L3
L3 in Switched: ucast: 0 pkt, 0 bytes - mcast: 12 pkt, 778 bytes mcast
L3 out Switched: ucast: 0 pkt, 0 bytes - mcast: 0 pkt, 0 bytes
4046399 packets input, 349370039 bytes, 0 no buffer
Received 3795255 broadcasts, 2 runts, 0 giants, 0 throttles
<...output truncated...>
Router#
Note The Layer 3 switching packet count is updated approximately every five seconds.
Cisco IOS CEF and dCEF are permanently enabled. No configuration is required to support hardware Layer 3 switching.
With a PFC (and DFCs, if present), hardware Layer 3 switching uses per-flow load balancing based on IP source and destination addresses. Per-flow load balancing avoids the packet reordering that can be necessary with per-packet load balancing. For any given flow, all PFC- and DFC-equipped switches make exactly the same load-balancing decision, which can result in nonrandom load balancing.
The Cisco IOS CEF ip load-sharing per-packet, ip cef accounting per-prefix, and ip cef accounting non-recursive commands on the RP apply only to traffic that is CEF-switched in software on the RP. The commands do not affect traffic that is hardware Layer 3 switched on the PFC or on DFC-equipped switching modules.
For information about Cisco IOS CEF and dCEF on the RP, see these publications:
•The "Cisco Express Forwarding" sections at this URL:
http://www.cisco.com/en/US/docs/ios/12_2/switch/configuration/guide/xcfcef.html
•The Cisco IOS Switching Services Command Reference publication at this URL:
http://www.cisco.com/en/US/docs/ios/12_2/switch/command/reference/fswtch_r.html
Displaying Hardware Layer 3 Switching Statistics
Hardware Layer 3 switching statistics are obtained on a per-VLAN basis.
To display hardware Layer 3 switching statistics, perform this task:
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|---|---|
Router# show interfaces {{type1 slot/port} | {port-channel number}} |
Displays hardware Layer 3 switching statistics. |
1 type = fastethernet, gigabitethernet, or tengigabitethernet |
This example shows how to display hardware Layer 3 switching statistics:
Router# show interfaces gigabitethernet 9/5 | include Switched
L2 Switched: ucast: 8199 pkt, 1362060 bytes - mcast: 6980 pkt, 371952 bytes
L3 in Switched: ucast: 0 pkt, 0 bytes - mcast: 0 pkt, 0 bytes mcast
L3 out Switched: ucast: 0 pkt, 0 bytes - mcast: 0 pkt, 0 bytes
To display adjacency table information, perform this task:
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|---|---|
Router# show adjacency [{{type1 slot/port} | {port-channel number}} | detail | internal | summary] |
Displays adjacency table information. The optional detail keyword displays detailed adjacency information, including Layer 2 information. |
1 type = fastethernet, gigabitethernet, or tengigabitethernet |
This example shows how to display adjacency statistics:
Router# show adjacency gigabitethernet 9/5 detail
Protocol Interface Address
IP GigabitEthernet9/5 172.20.53.206(11)
504 packets, 6110 bytes
00605C865B82
000164F83FA50800
ARP 03:49:31
Note Adjacency statistics are updated approximately every 60 seconds.
Tip For additional information about Cisco Catalyst 6500 Series Switches (including configuration examples and troubleshooting information), see the documents listed on this page:
http://www.cisco.com/en/US/products/hw/switches/ps708/tsd_products_support_series_home.html
Participate in the Technical Documentation Ideas forum
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