Configuring IPv4

This chapter describes how to configure Internet Protocol version 4 (IPv4), which includes addressing, Address Resolution Protocol (ARP), and Internet Control Message Protocol (ICMP), on the Cisco NX-OS switch.

This chapter includes the following sections:

About IPv4

You can configure IP on the switch to assign IP addresses to network interfaces. When you assign IP addresses, you enable the interfaces and allow communication with the hosts on those interfaces.

You can configure an IP address as primary or secondary on a switch. An interface can have one primary IP address and multiple secondary addresses. All networking switches on an interface should share the same primary IP address because the packets that are generated by the switch always use the primary IPv4 address. Each IPv4 packet is based on the information from a source or destination IP address. See the Multiple IPv4 Addresses section.

You can use a subnet to mask the IP addresses. A mask is used to determine what subnet an IP address belongs to. An IP address contains the network address and the host address. A mask identifies the bits that denote the network number in an IP address. When you use the mask to subnet a network, the mask is then referred to as a subnet mask. Subnet masks are 32-bit values that allow the recipient of IP packets to distinguish the network ID portion of the IP address from the host ID portion of the IP address.

The IP feature in the Cisco NX-OS system is responsible for handling IPv4 packets, as well as the forwarding of IPv4 packets, which includes IPv4 unicast and multicast route lookup, reverse path forwarding (RPF) checks, and software access control list (ACL) forwarding. The IP feature also manages the network interface IP address configuration, duplicate address checks, static routes, and packet send and receive interface for IP clients.

Multiple IPv4 Addresses

The Cisco NX-OS system supports multiple IP addresses per interface. You can specify an unlimited number of secondary addresses for a variety of situations. The most common situations are as follows:

  • When there are not enough host IP addresses for a particular network interface. For example, if your subnet allows up to 254 hosts per logical subnet, but on one physical subnet you must have 300 host addresses, then you can use secondary IP addresses on the routers or access servers to allow you to have two logical subnets using one physical subnet.

  • Two subnets of a single network might otherwise be separated by another network. You can create a single network from subnets that are physically separated by another network by using a secondary address. In these instances, the first network is extended, or layered on top of the second network. A subnet cannot appear on more than one active interface of the router at a time.


Note


If any switch on a network segment uses a secondary IPv4 address, all other switches on that same network interface must also use a secondary address from the same network or subnet. The inconsistent use of secondary addresses on a network segment can quickly cause routing loops.


Address Resolution Protocol

Networking switches and Layer 3 switches use Address Resolution Protocol (ARP) to map IP (network layer) addresses to (Media Access Control [MAC]-layer) addresses to enable IP packets to be sent across networks. Before a switch sends a packet to another switch, it looks in its own ARP cache to see if there is a MAC address and corresponding IP address for the destination switch. If there is no entry, the source switch sends a broadcast message to every switch on the network.

Each switch compares the IP address to its own. Only the switch with the matching IP address replies to the switch that sends the data with a packet that contains the MAC address for the switch. The source switch adds the destination switch MAC address to its ARP table for future reference, creates a data-link header and trailer that encapsulates the packet, and proceeds to transfer the data. The following figure shows the ARP broadcast and response process.

Figure 1. ARP Process

When the destination switch lies on a remote network which is beyond another router, the process is the same except that the switch that sends the data sends an ARP request for the MAC address of the default gateway. After the address is resolved and the default gateway receives the data packet, the default gateway broadcasts the destination IP address over the networks connected to it. The switch on the destination switch network uses ARP to obtain the MAC address of the destination switch and delivers the packet. ARP is enabled by default.

The default system-defined CoPP policy rate-limits ARP broadcast packets. The default system-defined CoPP policy prevents an ARP broadcast storm from affecting the control plane traffic but does not affect bridged packets.

ARP Caching

ARP caching minimizes broadcasts and limits wasteful use of network resources. The mapping of IP addresses to MAC addresses occurs at each hop (switch) on the network for every packet sent over an internetwork, which may affect network performance.

ARP caching stores network addresses and the associated data-link addresses in memory for a period of time, which minimizes the use of valuable network resources to broadcast for the same address each time a packet is sent. You must maintain the cache entries since the cache entries are set to expire periodically because the information might become outdated. Every switch on a network updates its tables as addresses are broadcast.

Devices That Do Not Use ARP

When a network is divided into two segments, a bridge joins the segments and filters traffic to each segment based on MAC addresses. The bridge builds its own address table that uses MAC addresses only, as opposed to a switch, which has an ARP cache that contains both IP addresses and the corresponding MAC addresses.

Passive hubs are central-connection switches that physically connect other switches in a network. They send messages out on all their ports to the switches and operate at Layer 1 but do not maintain an address table.

Layer 2 switches determine which port is connected to a device to which the message is addressed and send only to that port, unlike a hub, which sends the message out all of its ports. However, Layer 3 switches are switches that build an ARP cache (table).

Reverse ARP

Reverse ARP (RARP) as defined by RFC 903 works the same way as ARP, except that the RARP request packet requests an IP address instead of a MAC address. RARP often is used by diskless workstations because this type of device has no way to store IP addresses to use when they boot. The only address that is known is the MAC address because it is burned into the hardware.

Use of RARP requires an RARP server on the same network segment as the router interface. The following figure illustrates how RARP works.

Figure 2. Reverse ARP

There are several limitations of RARP. Because of these limitations, most businesses use DHCP to assign IP addresses dynamically. DHCP is cost effective and requires less maintenance than RARP. The following are the most important limitations:

  • Because RARP uses hardware addresses, if the internetwork is large with many physical networks, a RARP server must be on every segment with an additional server for redundancy. Maintaining two servers for every segment is costly.

  • Each server must be configured with a table of static mappings between the hardware addresses and IP addresses. Maintenance of the IP addresses is difficult.

  • RARP only provides IP addresses of the hosts and not subnet masks or default gateways.

Proxy ARP

Proxy ARP enables a switch that is physically located on one network appear to be logically part of a different physical network connected to the same switch or firewall. Proxy ARP allows you to hide a switch with a public IP address on a private network behind a router and still have the switch appear to be on the public network in front of the router. By hiding its identity, the router accepts responsibility for routing packets to the real destination. Proxy ARP can help switches on a subnet reach remote subnets without configuring routing or a default gateway.

When switches are not in the same data link layer network but in the same IP network, they try to transmit data to each other as if they are on the local network. However, the router that separates the switches does not send a broadcast message because routers do not pass hardware-layer broadcasts and the addresses cannot be resolved.

When you enable Proxy ARP on the switch and it receives an ARP request, it identifies the request as a request for a system that is not on the local LAN. The switch responds as if it is the remote destination for which the broadcast is addressed, with an ARP response that associates the MAC address of the switch with the IP address of the remote destination. The local switch believes that it is directly connected to the destination, while in reality its packets are being forwarded from the local subnetwork toward the destination subnetwork by their local switch. By default, Proxy ARP is disabled.

Local Proxy ARP

You can use local Proxy ARP to enable a switch to respond to ARP requests for IP addresses within a subnet where normally no routing is required. When you enable local Proxy ARP, ARP responds to all ARP requests for IP addresses within the subnet and forwards all traffic between hosts in the subnet. Use this feature only on subnets where hosts are intentionally prevented from communicating directly by the configuration on the switch to which they are connected.

Gratuitous ARP

Gratuitous ARP sends a request with identical source IP address and destination IP address to detect duplicate IP addresses. Cisco NX-OS supports enabling or disabling gratuitous ARP requests or ARP cache updates.

Glean Throttling

When forwarding an incoming IP packet, if the Address Resolution Protocol (ARP) request for the next-hop is not resolved, packets are punted to the central processing unit (CPU) for ARP resolution. The CPU resolves the MAC address for the next-hop and programs the hardware.

The device hardware has glean rate limiters to protect the supervisor from the glean traffic. If the maximum number of entries is exceeded, the packets for which the ARP request is not resolved continues to be processed in the software instead of getting dropped in the hardware.

When an ARP request is sent, the software adds a /32 drop adjacency in the hardware to prevent the packets to the same next-hop IP address to be forwarded to the supervisor. When the ARP is resolved, the hardware entry is updated with the correct MAC address. If the ARP entry is not resolved before a timeout period, the entry is removed from the hardware.


Note


Glean throttling is supported for IPv4 and IPv6, but IPv6 link-local addresses are not supported.

ICMP

You can use ICMP to provide message packets that report errors and other information that is relevant to IP processing. ICMP generates error messages, such as ICMP destination unreachable messages, ICMP Echo Requests (which send a packet on a round trip between two hosts) and Echo Reply messages. ICMP also provides many diagnostic functions and can send and redirect error packets to the host. By default, ICMP is enabled.

Some of the ICMP message types are as follows:

  • Network error messages

  • Network congestion messages

  • Troubleshooting information

  • Timeout announcements


Note


ICMP redirects are disabled on interfaces where the local proxy ARP feature is enabled.


ICMP Unreachable Support to Set Source Interface

You can configure an interface IP address for the ICMP source IP field to handle ICMP error messages. When ICMP packets are constructed in a network stack, the packets use the configured interface IP address. You can select Ethernet, loopback, or port channel interfaces to configure the IP address.

Virtualization Support

IPv4 supports Virtual Routing and Forwarding instances (VRFs). By default, Cisco NX-OS places you in the default VRF unless you specifically configure another VRF. For more information, see Configuring Layer 3 Virtualization.

IPv4 Routes with ECMP

If all next-hops for a route are glean, drop, or punt, all next-hops are programmed as-is in the Multipath hardware table.

If some next-hops for a route are glean, drop, or punt, and the remaining next-hops are not, then only non glean, drop, or punt next-hops are programmed in the Multipath hardware table.

When a specific next-hop for ECMP route is resolved (ARP ND resolved), then the Multipath hardware table is updated accordingly.

Prerequisites for IPv4

IPv4 has the following prerequisites:

  • IPv4 can only be configured on Layer 3 interfaces.

Guidelines and Limitations

IPv4 has the following configuration guidelines and limitations:

  • You can configure a secondary IP address only after you configure the primary IP address.

  • If the switch is used as a Layer 2 or Layer 3 termination switch, Cisco recommends that you set the mac-address-table-aging-time to 1800 (higher than the default ARP aging time of 1500 seconds) on all VLANs.

  • The switch does not support per-VLAN cam aging timers.

  • For Cisco Nexus 3600-R platform switches, internet-peering mode is only intended to be used with the prefix pattern as distributed in the global internet routing table. In this mode, other prefix distributions or patterns can operate, but not predictably. As a result, maximum achievable LPM/LEM scale is reliable only when the prefix patterns are actual internet prefix patterns. In internet-peering mode, if route prefix patterns other than those in the global internet routing table are used, the switch might not successfully achieve documented scalability numbers.

  • Beginning with Cisco NX-OS Release 10.4(1)F, out of subnet ARP resolution support is provided on Cisco Nexus 3600 Series platform switches for the following L3 interfaces:

    • Ethernet

    • Sub-interfaces

    • Port-channel

    • FEX

    • IP unnumbered interface


    Note


    • The out of subnet ARP resolution feature is not supported on SVI L3 interfaces and on vPC or HSRP or VXLAN deployments.


  • Beginning with Cisco NX-OS Release 10.4(2)F, the ip arp cache intf-limit configuration is supported to limit the ARP cache entries per interface on Cisco NX-OS devices with the following capabilities:

    • Supported on global and interface modes. However, interface mode configuration takes the precedence over global mode.

    • Supported only on the following L3 interfaces:

      • SVI

      • SVI Unnumbered Interfaces

    • Not supported on the following L3 interfaces:

      • Ethernet

      • Subinterfaces

      • Port-channel

      • Unnumbered interfaces

    • If the configuration is applied to non-supporting interfaces, this configuration will be applied to the global mode.

Default Settings

The following table lists the default settings for IP parameters.

Table 1. Default IP Parameters

Parameters

Default

ARP timeout

1500 seconds

Proxy ARP

Disabled

Configuring IPv4

Configuring IPv4 Addressing

You can assign a primary IP address for a network interface.

SUMMARY STEPS

  1. configure terminal
  2. interface ethernet number
  3. no switchport
  4. ip address ip-address / length [ secondary ]
  5. (Optional) show ip interface
  6. (Optional) copy running-config startup-config

DETAILED STEPS

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

interface ethernet number

Example:

switch(config)# interface ethernet 2/3
switch(config-if)#

Enters interface configuration mode.

Step 3

no switchport

Example:

switch(config-if)# no switchport

Configures the interface as a Layer 3 routed interface.

Step 4

ip address ip-address / length [ secondary ]

Example:

switch(config-if)# ip address 192.2.1.1 255.0.0.0

Specifies a primary or secondary IPv4 address for an interface.

  • The network mask can be a four-part dotted decimal address. For example, 255.0.0.0 indicates that each bit equal to 1 means the corresponding address bit belongs to the network address.

  • The network mask can be indicated as a slash (/) and a number - a prefix length. The prefix length is a decimal value that indicates how many of the high-order contiguous bits of the address comprise the prefix (the network portion of the address). A slash must precede the decimal value and there is no space between the IP address and the slash.

Step 5

(Optional) show ip interface

Example:

switch(config-if)# show ip interface
(Optional)

Displays interfaces configured for IPv4.

Step 6

(Optional) copy running-config startup-config

Example:

switch(config-if)# copy running-config startup-config
(Optional)

Saves this configuration change.

Example

This example shows how to assign an IPv4 address:

switch# configure terminal
switch(config)# interface ethernet 2/3
switch(config-if)# no switchport
switch(config-if)# ip address 192.2.1.1 255.0.0.0
switch(config-if)# copy running-config startup-config

Configuring Multiple IP Addresses

You can only add secondary IP addresses after you configure primary IP addresses.

SUMMARY STEPS

  1. configure terminal
  2. interface ethernet number
  3. no switchport
  4. ip address ip-address / length [secondary ]
  5. (Optional) show ip interface
  6. (Optional) copy running-config startup-config

DETAILED STEPS

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

interface ethernet number

Example:

switch(config)# interface ethernet 2/3
switch(config-if)#

Enters interface configuration mode.

Step 3

no switchport

Example:

switch(config-if)# no switchport

Configures the interface as a Layer 3 routed interface.

Step 4

ip address ip-address / length [secondary ]

Example:

switch(config-if)# ip address 192.2.1.1 255.0.0.0 secondary

Specifies the configured address as a secondary IPv4 address.

Step 5

(Optional) show ip interface

Example:

switch(config-if)# show ip interface
(Optional)

Displays interfaces configured for IPv4.

Step 6

(Optional) copy running-config startup-config

Example:

switch(config-if)# copy running-config startup-config
(Optional)

Saves this configuration change.

Configuring LPM Internet-Peering Routing Mode

Beginning with Cisco NX-OS Release 9.3(1), you can configure LPM Internet-peering routing mode in order to support IPv4 and IPv6 LPM Internet route entries. This mode supports dynamic Trie (tree bit lookup) for IPv4 prefixes (with a prefix length up to /32) and IPv6 prefixes (with a prefix length up to /83). The Cisco Nexus 3600-R platform switches support this routing mode.


Note


This configuration impacts both the IPv4 and IPv6 address families.



Note


For LPM Internet-peering routing mode scale numbers, see the Cisco Nexus 3600 Series NX-OS Verified Scalability Guide. Cisco Nexus 3600-R platform switches in LPM Internet-peering mode scale out prectably only if they use internet-peering prefixes. If a Cisco Nexus 3600-R platform switch uses other prefix patterns, it might not achieve documented scalability numbers.


SUMMARY STEPS

  1. configure terminal
  2. [no] system routing template-internet-peering
  3. (Optional) show system routing mode
  4. copy running-config startup-config
  5. reload

DETAILED STEPS

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

[no] system routing template-internet-peering

Example:

switch(config)# system routing template-internet-peering

Puts the device in LPM Internet-peering routing mode to support IPv4 and IPv6 LPM Internet route entries.

Step 3

(Optional) show system routing mode

Example:

switch(config)# show system routing mode
Configured System Routing Mode: Internet Peering
Applied System Routing Mode: Internet Peering
(Optional)

Displays the LPM routing mode.

Step 4

copy running-config startup-config

Example:

switch(config)# copy running-config startup-config

Saves this configuration change.

Step 5

reload

Example:

switch(config)# reload

Reboots the entire device.

Additional Configuration for LPM Internet-Peering Routing Mode

When you deploy a Cisco Nexus switch in LPM Internet-peering routing mode in a large-scale routing environment or for routes with an increased number of next hops, you need to increase the memory limits for IPv4 under the VDC resource template.

SUMMARY STEPS

  1. configure terminal
  2. (Optional) show routing ipv4 memory estimate routes routes next-hops hops
  3. vdc switch id id
  4. limit-resource u4route-mem minimum min-limit maximum max-limit
  5. exit
  6. copy running-config startup-config
  7. reload

DETAILED STEPS

  Command or Action Purpose

Step 1

configure terminal

Example:
switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

(Optional) show routing ipv4 memory estimate routes routes next-hops hops

Example:
switch(config)# show routing ipv4 memory estimate routes 262144 next-hops 32
Shared memory estimates:
Current max 512 MB; 78438 routes with 64 nhs
in-use 2 MB; 2642 routes with 1 nhs (average)
Configured max 512 MB; 78438 routes with 64 nhs
Estimate memory with fixed overhead: 1007 MB; 262144 routes with 32 nhs
Estimate with variable overhead included:
- With MVPN enabled VRF: 1136 MB
- With OSPF route (PE-CE protocol): 1375 MB
- With EIGRP route (PE-CE protocol): 1651 M
(Optional)

Displays shared memory estimates to help you determine the memory requirements for routes.

Step 3

vdc switch id id

Example:
switch(config)# vdc switch id 1
switch(config-vdc)#

Specifies the VDC switch ID.

Step 4

limit-resource u4route-mem minimum min-limit maximum max-limit

Example:
switch(config-vdc)# limit-resource u4route-mem minimum 1024 maximum 1024

Configures the limits for IPv4 memory in megabytes.

Step 5

exit

Example:
switch(config-vdc)# exit
switch(config)#

Exits the VDC configuration mode.

Step 6

copy running-config startup-config

Example:
switch(config)# copy running-config startup-config

Saves this configuration change.

Step 7

reload

Example:
switch(config)# reload

Reboots the entire device.

Configuring a Static ARP Entry

You can configure a static ARP entry on the switch to map IP addresses to MAC hardware addresses, including static multicast MAC addresses.

SUMMARY STEPS

  1. configure terminal
  2. interface ethernet number
  3. no switchport
  4. ip arp ipaddr mac_addr
  5. copy running-config startup-config

DETAILED STEPS

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

interface ethernet number

Example:

switch(config)# interface ethernet 2/3
switch(config-if)#

Enters interface configuration mode.

Step 3

no switchport

Example:

switch(config-if)# no switchport

Configures the interface as a Layer 3 routed interface.

Step 4

ip arp ipaddr mac_addr

Example:

switch(config-if)# ip arp 192.2.1.1 0019.076c.1a78

Associates an IP address with a MAC address as a static entry

Step 5

copy running-config startup-config

Example:

switch(config-if)# copy running-config startup-config

Saves this configuration change.

Example

This example shows how to configure a static ARP entry:

switch# configure terminal
switch(config)# interface ethernet 2/3
switch(config-if)# no switchport
switch(config-if)# ip arp 1 92.2.1.1 0019.076c.1a78
switch(config-if)# copy running-config startup-config

Configuring Proxy ARP

You can configure Proxy ARP on the switch to determine the media addresses of hosts on other networks or subnets.

SUMMARY STEPS

  1. configure terminal
  2. interface ethernet number
  3. no switchport
  4. ip proxy-arp
  5. (Optional) copy running-config startup-config

DETAILED STEPS

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

interface ethernet number

Example:

switch(config)# interface ethernet 2/3
switch(config-if)#

Enters interface configuration mode.

Step 3

no switchport

Example:

switch(config-if)# no switchport

Configures the interface as a Layer 3 routed interface.

Step 4

ip proxy-arp

Example:

switch(config-if)# ip proxy-arp

Enables Proxy ARP on the interface.

Step 5

(Optional) copy running-config startup-config

Example:

switch(config-if)# copy running-config startup-config
(Optional)

Saves this configuration change.

Example

This example shows how to configure Proxy ARP:

switch# configure terminal
switch(config)# interface ethernet 2/3
switch(config-if)# no switchport
switch(config-if)# ip proxy-arp
switch(config-if)# copy running-config startup-config

Configuring Local Proxy ARP

You can configure Local Proxy ARP on the switch.

SUMMARY STEPS

  1. configure terminal
  2. interface ethernet number
  3. no switchport
  4. ip local-proxy-arp
  5. (Optional) copy running-config startup-config

DETAILED STEPS

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

interface ethernet number

Example:

switch(config)# interface ethernet 2/3
switch(config-if)#

Enters interface configuration mode.

Step 3

no switchport

Example:

switch(config-if)# no switchport

Configures the interface as a Layer 3 routed interface

Step 4

ip local-proxy-arp

Example:

switch(config-if)# ip local-proxy-arp

Enables Local Proxy ARP on the interface.

Step 5

(Optional) copy running-config startup-config

Example:

switch(config-if)# copy running-config startup-config
(Optional)

Saves this configuration change.

Example

This example shows how to configure Local Proxy ARP:

switch# configure terminal
switch(config)# interface ethernet 2/3
switch(config-if)# no switchport
switch(config-if)# ip local-proxy-arp
switch(config-if)# copy running-config startup-config

Configuring Gratuitous ARP

You can configure gratuitous ARP on an interface.

SUMMARY STEPS

  1. configure terminal
  2. interface ethernet number
  3. no switchport
  4. ip arp gratuitous { request | update }
  5. copy running-config startup-config

DETAILED STEPS

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

interface ethernet number

Example:

switch(config)# interface ethernet 2/3
switch(config-if)#

Enters interface configuration mode.

Step 3

no switchport

Example:

switch(config-if)# no switchport

Configures the interface as a Layer 3 routed interface.

Step 4

ip arp gratuitous { request | update }

Example:

switch(config-if)# ip arp gratuitous request

Enables gratuitous ARP on the interface. Default is enabled.

Step 5

copy running-config startup-config

Example:

switch(config-if)# copy running-config startup-config

Saves this configuration change.

Example

This example shows how to enable IP glean throttling:

switch# configure terminal
switch(config)# hardware ip glean throttle
switch(config-if)# copy running-config startup-config

Configuring Out of Subnet ARP Resolution

Beginning with Cisco NX-OS Release 10.4(1)F, you can enable or disable out of subnet ARP resolution using the ip arp outside-subnet command.

This command is available on both global and interface mode. There is no impact on config-replace and dual stage commit when this command is enabled.


Note


When this command is enabled, downgrade from Cisco NX-OS Release 10.4(1)F is restricted, and user will be prompted with an error message to remove the out of subnet ARP resolution configuration before proceeding for downgrade.


SUMMARY STEPS

  1. configure terminal
  2. [no] ip arp outside-subnet
  3. (Optional) copy running-config startup-config

DETAILED STEPS

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

[no] ip arp outside-subnet

Example:

switch(config)# ip arp outside-subnet

Enables or disables the ARP out of subnet packet transaction on connected host.

Step 3

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config startup-config
(Optional)

Saves this configuration change.

Configuring ARP Cache Limit Per SVI Interface

Beginning from Cisco NX-OS Release 10.4(2)F, you can set the number of maximum ARP cache entries to be allowed per SVI interface on the Cisco NX-OS devices. This configuration is supported on both global and interface modes.

SUMMARY STEPS

  1. configure terminal
  2. interface vlan vlan-id
  3. [no] ip arp cache intf-limit value
  4. (Optional) copy running-config startup-config

DETAILED STEPS

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

interface vlan vlan-id

Example:

switch(config)# interface vlan 5
switch(config-if)#

Creates a VLAN interface and enters the configuration mode for the SVI.

Step 3

[no] ip arp cache intf-limit value

Example:

switch(config-if)# ip arp cache intf-limit 50000
switch(config-if)#

Configures the set limit of ARP cache entries for the SVI interface. Range of valid ARP entries is 1-128000.

intf-limit : Specifies the number of valid dynamic ARP entries per interface.

The no form of this command removes the configuration.

Step 4

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config startup-config
(Optional)

Saves this configuration change.

Configuring IP Directed Broadcasts

An IP directed broadcast is an IP packet whose destination address is a valid broadcast address for some IP subnet, but which originates from a node that is not itself part of that destination subnet.

A switch that is not directly connected to its destination subnet forwards an IP directed broadcast in the same way it would forward unicast IP packets destined to a host on that subnet. When a directed broadcast packet reaches a switch that is directly connected to its destination subnet, that packet is “exploded” as a broadcast on the destination subnet. The destination address in the IP header of the packet is rewritten to the configured IP broadcast address for the subnet, and the packet is sent as a link-layer broadcast.

If directed broadcast is enabled for an interface, incoming IP packets whose addresses identify them as directed broadcasts intended for the subnet to which that interface is attached will be exploded as broadcasts on that subnet.

To enable IP directed broadcasts, use the following command in interface configuration mode:

Command

Purpose

ip directed-broadcast

Enables the translation of a directed broadcast to physical broadcasts

Configuring IP Glean Throttling

Cisco NX-OS software supports glean throttling rate limiters to protect the supervisor from the glean traffic.


Note


We recommend that you configure the IP glean throttle feature by using the hardware ip glean throttle command to filter the unnecessary glean packets that are sent to the supervisor for ARP resolution for the next-hops that are not reachable or do not exist. IP glean throttling boosts software performance and helps to manage traffic more efficiently.

Note


Glean throttling is supported for IPv4 and IPv6, but IPv6 link-local addresses are not supported.

SUMMARY STEPS

  1. configure terminal
  2. hardware ip glean throttle
  3. no hardware ip glean throttle
  4. (Optional) copy running-config startup-config

DETAILED STEPS

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

hardware ip glean throttle

Example:

switch(config)# hardware ip glean throttle

Enables ARP throttling.

Step 3

no hardware ip glean throttle

Example:

switch(config)# no hardware ip glean throttle

Disables ARP throttling.

Step 4

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config startup-config
(Optional)

Saves this configuration change.

Example

This example shows how to enable IP glean throttling:

switch# configure terminal
switch(config)# hardware ip glean throttle
switch(config-if)# copy running-config startup-config

Configuring the Hardware IP Glean Throttle Timeout

You can configure a timeout for the installed drop adjacencies to remain in the FIB.

SUMMARY STEPS

  1. configure terminal
  2. hardware ip glean throttle maximum timeout timeout-in-seconds
  3. [no] hardware ip glean throttle maximum timeout timeout-in-seconds
  4. (Optional) copy running-config startup-config

DETAILED STEPS

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

hardware ip glean throttle maximum timeout timeout-in-seconds

Example:

switch(config)# hardware ip glean
throttle maximum timeout 300

Configures the timeout for the installed drop adjacencies to remain in the FIB.

Step 3

[no] hardware ip glean throttle maximum timeout timeout-in-seconds

Example:

switch(config)# no hardware ip glean
throttle maximum timeout 300

Applies the default limits.

The timeout value is in seconds. The range is from 300 seconds (5 minutes) to 1800 seconds (30 minutes).

Note

 

After the timeout period is exceeded, the drop adjacencies are removed from the FIB.

Step 4

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config
startup-config
(Optional)

Saves this configuration change.

Example

This example shows how to disable gratuitous ARP requests:


switch# configure terminal
switch(config)# hardware ip glean throttle maximum timeout 300
switch(config-if)# copy running-config startup-config

Configuring the Interface IP Address for the ICMP Source IP Field

You can configure an interface IP address for the ICMP source IP field to handle ICMP error messages.

SUMMARY STEPS

  1. configure terminal
  2. [no] ip source {ethernet slot/port | loopback number | port-channel number} {icmp-errors}

DETAILED STEPS

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

[no] ip source {ethernet slot/port | loopback number | port-channel number} {icmp-errors}

Example:

switch(config)# ip source loopback 0
icmp-errors

Configures an interface IP address for the ICMP source IP field to route ICMP error messages.

Example

This example shows how to configure an interface IP address for the ICMP source IP field:

switch# configure terminal
switch(config)# ip source ethernet 1/1 icmp-errors

This example shows how to configure an interface IP address for the ICMP source IP field:

switch# configure terminal
switch(config)# no ip source ethernet 1/1 icmp-errors

Configuring Logging for Software Forwarding of IP Packets

You can configure the logging conditions for IP packets that are forwarded by the NX-OS software. The conditions consist of the following:
  • A minimum number of packets (the size)

  • An optional period of time (the logging interval)

The logging conditions create the packet per second (pps) threshold. When traffic meets or exceeds the conditions, NX-OS logs a console message. For example:
2019 jul 31 15:28:31 switch-1 %$ VDC-1 %$ %USER-3-SYSTEM_MSG: Packets per second exceeded the configured threshold 40, current PPS: 1262  - netstack

You can set the conditions for forwarded packets through the ip pps threshold unicast-forward command. To disable the feature, use no ip pps threshold unicast-forward .

SUMMARY STEPS

  1. config terminal
  2. ip pps threshold unicast-forward pps-threshold [syslog-interval]
  3. (Optional) show ip pps threshold

DETAILED STEPS

  Command or Action Purpose

Step 1

config terminal

Example:

switch-1# config terminal 
Enter configuration commands, one per line. End with CNTL/Z.
switch-1(config)# 

Enters the configuration terminal.

Step 2

ip pps threshold unicast-forward pps-threshold [syslog-interval]

Example:

switch-1(config)# ip pps threshold unicast-forward 50 5
switch-1(config)# 
Enable the feature and set the conditions:
  • The pps-threshold is from 1 through 30000 packets.

  • The syslog-interval is from 1 through 60 seconds. The default is 1 second.

Step 3

(Optional) show ip pps threshold

Example:

switch-1(config) show ip traffic pps
PPS type : unicast-forward, PPS limit : 50, Log Interval:  5
switch-1(config)# 

Display the current PPS threshold configuration.

Example

This example shows how to configure a console message if the number of packets that get forwarded for a specific flow exceeds the configured packet count and a logging interval of 4000 packets every 2 seconds:

switch-1# configure terminal
switch-1(config)# ip pps threshold unicast-forward 4000 2
switch-1(config)# copy running-config startup-config

Verifying the IPv4 Configuration

To display the IPv4 configuration information, perform one of the following tasks:

Command Purpose
how hardware forwarding ip verify

Displays the IP packet verification configuration.

show ip adjacency

Displays the adjacency table.

show ip arp

Displays the ARP table.

show ip interface

Displays IP-related interface information.

show ip arp statistics [vrf vrf-name]

Displays the ARP statistics.

show ip adjacency summary

Displays the summary of number of throttle adjacencies.

show ip arp summary

Displays the summary of the number of throttle adjacencies.

show ip interface

Displays IP-related interface information.

Configuration Examples for IPv4

This example shows how to configure an IPv4 address:


switch# configure terminal
switch(config)# interface ethernet 1/2
switch(config)# no switchport
switch(config-if)#ip address 192.2.1.1/1