IP addressing occurs at Layer 2 (data link) and Layer 3 (network) of the Open System Interconnection (OSI) reference model. OSI is an architectural network model developed by ISO and ITU-T that consists of seven layers, each of which specifies particular network functions such as addressing, flow control, error control, encapsulation, and reliable message transfer.

Layer 2 addresses are used for local transmissions between devices that are directly connected. Layer 3 addresses are used for indirectly connected devices in an internetwork environment. Each network uses addressing to identify and group devices so that transmissions can be sent and received. Ethernet (802.2, 802.3, Ethernet II, and Subnetwork Access Protocol [SNAP]), Token Ring, and Fiber Distributed Data Interface (FDDI) use media access control (MAC) addresses that are "burned in" to the network interface card (NIC). The most commonly used network types are Ethernet II and SNAP.

Note	For the supported interface types, see the data sheet for your hardware platform.

In order for devices to be able to communicate with each when they are not part of the same network, the 48-bit MAC address must be mapped to an IP address. Some of the Layer 3 protocols used to perform the mapping are:

• Address Resolution Protocol (ARP)
• Reverse ARP (RARP)
• Serial Line ARP (SLARP)
• Inverse ARP

For the purposes of IP mapping, Ethernet, Token Ring, and FDDI frames contain the destination and source addresses. Frame Relay and Asynchronous Transfer Mode (ATM) networks, which are packet-switched, data packets take different routes to reach the same destination. At the receiving end, the packet is reassembled in the correct order.

In a Frame Relay network, there is one physical link that has many logical circuits called virtual circuits (VCs). The address field in the frame contains a data-link connection identifier (DLCI), which identifies each VC. For example, in the figure below, the Frame Relay switch to which device Fred is connected receives frames; the switch forwards the frames to either Barney or Betty based on the DLCI that identifies each VC. So Fred has one physical connection but multiple logical connections.

Figure 1

Frame Relay Network

ATM networks use point-to-point serial links with the High-Level Data Link Control (HDLC) protocol. HDLC includes a meaningless address field included in five bytes of the frame header frame with the recipient implied since there can be only one.

The Address Resolution Protocol (ARP) was developed to enable communications on an internetwork and is defined by RFC 826. Layer 3 devices need ARP to map IP network addresses to MAC hardware addresses so that IP packets can be sent across networks. Before a device sends a datagram to another device, it looks in its ARP cache to see if there is a MAC address and corresponding IP address for the destination device. If there is no entry, the source device sends a broadcast message to every device on the network. Each device compares the IP address to its own. Only the device with the matching IP address replies to the sending device with a packet containing the MAC address for the device (except in the case of "proxy ARP"). The source device adds the destination device 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 figure below illustrates the ARP broadcast and response process.

Figure 2

ARP Process

When the destination device lies on a remote network, one beyond another Layer 3 device, the process is the same except that the sending device sends an ARP request for the MAC address of the default gateway. After the address is resolved and the default gateway receives the packet, the default gateway broadcasts the destination IP address over the networks connected to it. The Layer 3 device on the destination device network uses ARP to obtain the MAC address of the destination device and delivers the packet.

Encapsulation of IP datagrams and ARP requests and replies on IEEE 802 networks other than Ethernet use Subnetwork Access Protocol (SNAP).

The ARP request message has the following fields:

• HLN--Hardware address length. Specifies how long the hardware addresses are in the message. For IEEE 802 MAC addresses (Ethernet) the value is 6.
• PLN--Protocol address length. Specifies how long the protocol (Layer 3) addresses are in the message. For IPv4, the value is 4.
• OP--Opcode. Specifies the nature of the message by code:
  • 1--ARP request.
  • 2--ARP reply.
  • 3 through 9--RARP and Inverse ARP requests and replies.
• SHA--Sender hardware address. Specifies the Layer 2 hardware address of the device sending the message.
• SPA--Sender protocol address. Specifies the IP address of the sending device.
• THA--Target hardware address. Specifies the Layer 2 hardware address of the receiving device.
• TPA--Target protocol address. Specifies the IP address of the receiving device.

Because the mapping of IP addresses to media access control (MAC) addresses occurs at each hop (Layer 3 device) on the network for every datagram sent over an internetwork, performance of the network could be compromised. To minimize broadcasts and limit wasteful use of network resources, Address Resolution Protocol (ARP) caching was implemented.

ARP caching is the method of storing network addresses and the associated data-link addresses in memory for a period of time as the addresses are learned. This minimizes the use of valuable network resources to broadcast for the same address each time a datagram is sent. The cache entries must be maintained because the information could become outdated, so it is critical that the cache entries are set to expire periodically. Every device on a network updates its tables as addresses are broadcast.

There are static ARP cache entries and dynamic ARP cache entries. Static entries are manually configured and kept in the cache table on a permanent basis. Static entries are best for devices that have to communicate with other devices usually in the same network on a regular basis. Dynamic entries are added by Cisco software, kept for a period of time, and then removed.

Static routing requires an administrator to manually enter into a table IP addresses, subnet masks, gateways, and corresponding Media Access Control (MAC) addresses for each interface of each device. Static routing enables more control but requires more work to maintain the table. The table must be updated each time routes are added or changed.

Dynamic routing uses protocols that enable the devices in a network to exchange routing table information with each other. The table is built and changed automatically. No administrative tasks are needed unless a time limit is added, so dynamic routing is more efficient than static routing. The default time limit is 4 hours. If the network has many routes that are added and deleted from the cache, the time limit should be adjusted.

The routing protocols that dynamic routing uses to learn routes, such as distance-vector and link-state routing protocols, are beyond the scope of this document.

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

Passive hubs are central-connection devices that physically connect other devices in a network. They send messages out all ports to the devices and operate at Layer 1, but they 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 the message only to that port, unlike a hub, which sends the message out all its ports. However, Layer 3 switches are routers that build an ARP cache (table).

Inverse ARP, which is enabled by default in ATM networks, builds an ATM map entry and is necessary to send unicast packets to a server (or relay agent) on the other end of a connection. Inverse ARP is supported only for the aal5snap encapsulation type.

For multipoint interfaces, an IP address can be acquired using other encapsulation types because broadcast packets are used. However, unicast packets to the other end will fail because there is no ATM map entry and thus DHCP renewals and releases also fail.

For more information about Inverse ARP and ATM networks, see the "Configuring ATM" feature module in the Asynchronous Transfer Mode Configuration Guide.

Reverse ARP (RARP) as defined by RFC 903 works the same way as the Address Resolution Protocol (ARP), except that the RARP request packet requests an IP address instead of a media access control (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 in to the hardware.

RARP requires a RARP server on the same network segment as the device interface. The figure below illustrates how RARP works.

Figure 3

RARP Process

Because of the limitations with RARP, most businesses use Dynamic Host Configuration Protocol (DHCP) to assign IP addresses dynamically. DHCP is cost-effective and requires less maintenance than RARP. The most important limitations with RARP are as follows:

• 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 the IP addresses. Maintenance of the IP addresses is difficult.
• RARP only provides IP addresses of the hosts but not subnet masks or default gateways.

Cisco software attempts to use RARP if it does not know the IP address of an interface at startup to respond to RARP requests that it is able to answer. The AutoInstall feature of the software automates the configuration of Cisco devices.

AutoInstall supports RARP and enables a network manager to connect a new device to a network, turn it on, and automatically load a pre-existing configuration file. The process begins when no valid configuration file is found in NVRAM. For more information about AutoInstall, see the Configuration Fundamentals Configuration Guide.

Proxy Address Resolution Protocol, as defined in RFC 1027, was implemented to enable devices that are separated into physical network segments connected by a router in the same IP network or subnetwork to resolve IP-to-MAC addresses. When devices are not in the same data link layer network but are in the same IP network, they try to transmit data to each other as if they were on the local network. However, the router that separates the devices will not send a broadcast message because routers do not pass hardware-layer broadcasts. Therefore, the addresses cannot be resolved.

Proxy ARP is enabled by default so the "proxy router" that resides between the local networks responds with its MAC address as if it were the router to which the broadcast is addressed. When the sending device receives the MAC address of the proxy router, it sends the datagram to the proxy router, which in turns sends the datagram to the designated device.

Proxy ARP is invoked by the following conditions:

• The target IP address is not on the same physical network (LAN) on which the request is received.
• The networking device has one or more routes to the target IP address.
• All of the routes to the target IP address go through interfaces other than the one on which the request is received.

When proxy ARP is disabled, a device responds to ARP requests received on its interface only if the target IP address is the same as its IP address or if the target IP address in the ARP request has a statically configured ARP alias.

Serial Line ARP (SLARP) is used for serial interfaces that use High-Level Data Link Control (HDLC) encapsulation. A SLARP server, intermediate (staging) device, and another device providing a SLARP service might be required in addition to a TFTP server. If an interface is not directly connected to a server, the staging device is required to forward the address-resolution requests to the server. Otherwise, a directly connected device with SLARP service is required. Cisco software attempts to use SLARP if it does not know the IP address of an interface at startup to respond to SLARP requests that software is able to answer.

Cisco software automates the configuration of Cisco devices with the AutoInstall feature. AutoInstall supports SLARP and enables a network manager to connect a new device to a network, turn it on, and automatically load a pre-existing configuration file. The process begins when no valid configuration file is found in NVRAM. For more information about AutoInstall, see the Configuration Fundamentals Configuration Guide.

Note	AutoInstall supports serial interfaces that use Frame Relay encapsulation.

Perform this task to support a type of encapsulation for a specific network, such as Ethernet, Frame Relay, FDDI, or Token Ring. When Frame Relay encapsulation is specified, the interface is configured for a Frame Relay subnetwork with one physical link that has many logical circuits called virtual circuits (VCs). The address field in the frame contains a data-link connection identifier (DLCI) that identifies each VC. When SNAP encapsulation is specified, the interface is configured for FDDI or Token Ring networks.

Note	The encapsulation type specified in this task should match the encapsulation type specified in the "Defining Static ARP Entries" task.

1.    enable

2.    configure terminal

3.    interface type number

4.    arp {arpa | frame-relay | snap}

5.    end

Perform this task to define static mapping between an IP address (32-bit address) and a Media Access Control (MAC) address (48-bit address) for hosts that do not support dynamic Address Resolution Protocol (ARP). Because most hosts support dynamic address resolution, defining static ARP cache entries is usually not required. Performing this task installs a permanent entry in the ARP cache that never times out. The entries remain in the ARP table until they are removed using the no arp command or the clear arp interface command for each interface.

Note	The encapsulation type specified in this task should match the encapsulation type specified in the "Enabling the Interface Encapsulation" task.

1.    enable

2.    configure terminal

3.    arp {ip-address | vrf vrf-name} hardware-address encap-type [interface-type]

4.    end

1.    enable

2.    configure terminal

3.    interface type number

4.    arp timeout seconds

5.    end

1.    enable

2.    configure terminal

3.    ip arp proxy disable

4.    end

1.    enable

2.    configure terminal

3.    interface type number

4.    no ip proxy-arp

5.    end

1.    show interfaces

2.    show arp

3.    show ip arp

4.    show processes cpu | include (ARP | PID)

Device# show interfaces GigabitEthernet0/0/0

GigabitEthernet0/0/0 is up, line protocol is up 
 Hardware is SPA-8X1GE-V2, address is 001a.3045.4100 (bia 001a.3045.4100) 
 MTU 1500 bytes, BW 1000000 Kbit, DLY 10 usec, 
 reliability 255/255, txload ½55, rxload ½55 
 Encapsulation ARPA, loopback not set 
 Keepalive not supported 
 Full Duplex, 1000Mbps, link type is auto, media type is SX 
 output flow-control is off, input flow-control is off 
 ARP type: ARPA, ARP Timeout 04:00:00 
 Last input never, output 00:00:50, output hang never 
 Last clearing of ''show interface'' counters never 
 Input queue: 0/375/0/0 (size/max/drops/flushes); Total output drops: 0 
 Queueing strategy: fifo 
 Output queue: 0/40 (size/max) 
 5 minute input rate 0 bits/sec, 0 packets/sec 
 5 minute output rate 0 bits/sec, 0 packets/sec 
 0 packets input, 0 bytes, 0 no buffer 
 Received 0 broadcasts (0 IP multicasts) 
 0 runts, 0 giants, 0 throttles 
 0 input errors, 0 CRC, 0 frame, 0 overrun, 0 ignored 
 0 watchdog, 0 multicast, 0 pause input 
 7998 packets output, 3074275 bytes, 0 underruns 
 0 output errors, 0 collisions, 4 interface resets 
 0 babbles, 0 late collision, 0 deferred 
 0 lost carrier, 0 no carrier, 0 pause output 
 0 output buffer failures, 0 output buffers swapped out 

Device# show arp

Protocol    Address       Age (min)   Hardware Addr      Type    Interface
Internet    10.1.1.1      43          001b.53e1.7201     ARPA    GigabitEthernet0/0/6
Internet    10.1.1.2      29          0021.d8ab.0b00     ARPA    GigabitEthernet0/0/6
Internet    10.1.2.1      80          001a.3045.4107     ARPA    GigabitEthernet0/0/7
Internet    10.1.2.1       -          0000.0c02.a03c     ARPA    GigabitEthernet0/0/7

Device# show ip arp

Protocol    Address       Age (min)   Hardware Addr      Type    Interface
Internet    10.1.1.1      43          001b.53e1.7201     ARPA    GigabitEthernet0/0/6
Internet    10.1.1.2      29          0021.d8ab.0b00     ARPA    GigabitEthernet0/0/6
Internet    10.1.2.1      80          001a.3045.4107     ARPA    GigabitEthernet0/0/7
Internet    10.1.2.1       -          0000.0c02.a03c     ARPA    GigabitEthernet0/0/7

Device# show processes cpu | include (ARP | PID)


PID  Runtime(ms)   Invoked      uSecs   5Sec   1Min   5Min TTY Process 
   9          46       515         89  0.00%  0.00%  0.00%   0  ARP Input        
  10           7     19078          0  0.00%  0.00%  0.00%   0  ARP Background   
 110           1         2        500  0.00%  0.00%  0.00%   0  IP ARP Adjacency 
 136           0         7          0  0.00%  0.00%  0.00%   0  ARP HA           
 182           0         8          0  0.00%  0.00%  0.00%   0  RARP Input