xref: /titanic_50/usr/src/man/man7p/arp.7p (revision 31c6d826a7f7a4ee7d83c8e99f25d82a4a248076)
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Copyright (c) 2009, Sun Microsystems, Inc. All Rights Reserved.
Copyright 2008 AT&T
The contents of this file are subject to the terms of the Common Development and Distribution License (the "License"). You may not use this file except in compliance with the License.
You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE or http://www.opensolaris.org/os/licensing. See the License for the specific language governing permissions and limitations under the License.
When distributing Covered Code, include this CDDL HEADER in each file and include the License file at usr/src/OPENSOLARIS.LICENSE. If applicable, add the following below this CDDL HEADER, with the fields enclosed by brackets "[]" replaced with your own identifying information: Portions Copyright [yyyy] [name of copyright owner]
ARP 7P "Feb 5, 2009"
NAME
arp, ARP - Address Resolution Protocol
SYNOPSIS

#include <sys/fcntl.h>

#include <sys/socket.h>

#include <net/if_arp.h>

#include <netinet/in.h>

s = socket(AF_INET, SOCK_DGRAM, 0);

d = open ("/dev/arp", oflag);
DESCRIPTION

ARP is a protocol used to map dynamically between Internet Protocol (IP) and Ethernet addresses. It is used by all Ethernet datalink providers (network drivers) and can be used by other datalink providers that support broadcast, including FDDI and Token Ring. The only network layer supported in this implementation is the Internet Protocol, although ARP is not specific to that protocol.

ARP caches IP-to-link-layer address mappings. When an interface requests a mapping for an address not in the cache, ARP queues the message that requires the mapping and broadcasts a message on the associated network requesting the address mapping. If a response is provided, ARP caches the new mapping and transmits any pending message. ARP will queue a maximum of four packets while awaiting a response to a mapping request. ARP keeps only the first four transmitted packets.

APPLICATION PROGRAMMING INTERFACE

The STREAMS device /dev/arp is not a Transport Level Interface (TLI) transport provider and may not be used with the TLI interface.

To facilitate communications with systems that do not use ARP, ioctl() requests are provided to enter and delete entries in the IP-to-link address tables. Ioctls that change the table contents require sys_net_config privilege. See privileges(5).

#include <sys/sockio.h>
#include <sys/socket.h>
#include <net/if.h>
#include <net/if_arp.h>
struct arpreq arpreq;
ioctl(s, SIOCSARP, (caddr_t)&arpreq);
ioctl(s, SIOCGARP, (caddr_t)&arpreq);
ioctl(s, SIOCDARP, (caddr_t)&arpreq);

SIOCSARP, SIOCGARP and SIOCDARP are BSD compatible ioctls. These ioctls do not communicate the mac address length between the user and the kernel (and thus only work for 6 byte wide Ethernet addresses). To manage the ARP cache for media that has different sized mac addresses, use SIOCSXARP, SIOCGXARP and SIOCDXARP ioctls.

#include <sys/sockio.h>
#include <sys/socket.h>
#include <net/if.h>
#include <net/if_dl.h>
#include <net/if_arp.h>
struct xarpreq xarpreq;
ioctl(s, SIOCSXARP, (caddr_t)&xarpreq);
ioctl(s, SIOCGXARP, (caddr_t)&xarpreq);
ioctl(s, SIOCDXARP, (caddr_t)&xarpreq);

Each ioctl() request takes the same structure as an argument. SIOCS[X]ARP sets an ARP entry, SIOCG[X]ARP gets an ARP entry, and SIOCD[X]ARP deletes an ARP entry. These ioctl() requests may be applied to any Internet family socket descriptors, or to a descriptor for the ARP device. Note that SIOCS[X]ARP and SIOCD[X]ARP require a privileged user, while SIOCG[X]ARP

does not.

The arpreq structure contains

/*
* ARP ioctl request
*/
struct arpreq {
 struct sockaddr arp_pa; /* protocol address */
 struct sockaddr arp_ha; /* hardware address */
 int arp_flags; /* flags */
};

The xarpreq structure contains:

/*
* Extended ARP ioctl request
*/
struct xarpreq {
 struct sockaddr_storage xarp_pa; /* protocol address */
 struct sockaddr_dl xarp_ha; /* hardware address */
 int xarp_flags; /* arp_flags field values */
};
#define ATF_COM 0x2 /* completed entry (arp_ha valid) */
#define ATF_PERM 0x4 /* permanent (non-aging) entry */
#define ATF_PUBL 0x8 /* publish (respond for other host) */
#define ATF_USETRAILERS 0x10 /* send trailer pckts to host */
#define ATF_AUTHORITY 0x20 /* hardware address is authoritative */

The address family for the [x]arp_pa sockaddr must be AF_INET. The ATF_COM flag bits ([x]arp_flags) cannot be altered. ATF_USETRAILERS is not implemented on Solaris and is retained for compatibility only. ATF_PERM makes the entry permanent (disables aging) if the ioctl() request succeeds. ATF_PUBL specifies that the system should respond to ARP requests for the indicated protocol address coming from other machines. This allows a host to act as an ARP server, which may be useful in convincing an ARP-only machine to talk to a non-ARP machine. ATF_AUTHORITY indicates that this machine owns the address. ARP does not update the entry based on received packets.

The address family for the arp_ha sockaddr must be AF_UNSPEC.

Before invoking any of the SIOC*XARP ioctls, user code must fill in the xarp_pa field with the protocol (IP) address information, similar to the BSD variant. The SIOC*XARP ioctls come in two (legal) varieties, depending on xarp_ha.sdl_nlen:

1. if sdl_nlen = 0, it behaves as an extended BSD ioctl. The kernel uses the IP address to determine the network interface.

2. if (sdl_nlen > 0) and (sdl_nlen < LIFNAMSIZ), the kernel uses the interface name in sdl_data[0] to determine the network interface; sdl_nlen represents the length of the string (excluding terminating null character).

3. if (sdl_nlen >= LIFNAMSIZ), an error (EINVAL) is flagged from the ioctl.

Other than the above, the xarp_ha structure should be 0-filled except for SIOCSXARP, where the sdl_alen field must be set to the size of hardware address length and the hardware address itself must be placed in the LLADDR/sdl_data[] area. (EINVAL will be returned if user specified sdl_alen does not match the address length of the identified interface).

On return from the kernel on a SIOCGXARP ioctl, the kernel fills in the name of the interface (excluding terminating NULL) and its hardware address, one after another, in the sdl_data/LLADDR area; if the two are larger than can be held in the 244 byte sdl_data[] area, an ENOSPC error is returned. Assuming it fits, the kernel will also set sdl_alen with the length of hardware address, sdl_nlen with the length of name of the interface (excluding terminating NULL), sdl_type with an IFT_* value to indicate the type of the media, sdl_slen with 0, sdl_family with AF_LINK and sdl_index (which if not 0) with system given index for the interface. The information returned is very similar to that returned via routing sockets on an RTM_IFINFO message.

The ARP ioctls have several additional restrictions and enhancements when used in conjunction with IPMP:

ARP mappings for IPMP data and test addresses are managed by the kernel and cannot be changed through ARP ioctls, though they may be retrieved using SIOCGARP or SIOCGXARP.

ARP mappings for a given IPMP group must be consistent across the group. As a result, ARP mappings cannot be associated with individual underlying IP interfaces in an IPMP group and must instead be associated with the corresponding IPMP IP interface.

roxy ARP mappings for an IPMP group are automatically managed by the kernel. Specifically, if the hardware address in a SIOCSARP or SIOCSXARP request matches the hardware address of an IP interface in an IPMP group and the IP address is not local to the system, the kernel regards this as a IPMP Proxy ARP entry. This IPMP Proxy ARP entry will have its hardware address automatically adjusted in order to keep the IP address reachable (provided the IPMP group has not entirely failed).

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ARP performs duplicate address detection for local addresses. When a logical interface is brought up (IFF_UP) or any time the hardware link goes up (IFF_RUNNING), ARP sends probes (ar$spa == 0) for the assigned address. If a conflict is found, the interface is torn down. See ifconfig(1M) for more details.

ARP watches for hosts impersonating the local host, that is, any host that responds to an ARP request for the local host's address, and any address for which the local host is an authority. ARP defends local addresses and logs those with ATF_AUTHORITY set, and can tear down local addresses on an excess of conflicts.

ARP also handles UNARP messages received from other nodes. It does not generate these messages.

PACKET EVENTS

The arp driver registers itself with the netinfo interface. To gain access to these events, a handle from net_protocol_lookup must be acquired by passing it the value NHF_ARP. Through this interface, two packet events are supported:

Physical in - ARP packets received via a network inter face

Physical out - ARP packets to be sent out via a network interface

For ARP packets, the hook_pkt_event structure is filled out as follows: hpe_ifp

Identifier indicating the inbound interface for packets received with the physical in event.

hpe_ofp

Identifier indicating the outbound interface for packets received with the physical out event.

hpe_hdr

Pointer to the start of the ARP header (not the ethernet header).

hpe_mp

Pointer to the start of the mblk_t chain containing the ARP packet.

hpe_mb

Pointer to the mblk_t with the ARP header in it.

NETWORK INTERFACE EVENTS

In addition to events describing packets as they move through the system, it is also possible to receive notification of events relating to network interfaces. These events are all reported back through the same callback. The list of events is as follows: plumb

A new network interface has been instantiated.

unplumb

A network interface is no longer associated with ARP.

SEE ALSO

arp(1M), ifconfig(1M), privileges(5), if_tcp(7P), inet(7P), netinfo(9F)

Plummer, Dave, An Ethernet Address Resolution Protocol or Converting Network Protocol Addresses to 48 .bit Ethernet Addresses for Transmission on Ethernet Hardware, RFC 826, STD 0037, November 1982.

Malkin, Gary, ARP Extension - UNARP, RFC 1868, November, 1995

DIAGNOSTICS

Several messages can be written to the system logs (by the IP module) when errors occur. In the following examples, the hardware address strings include colon (:) separated ASCII representations of the link layer addresses, whose lengths depend on the underlying media (for example, 6 bytes for Ethernet). Node %x:%x ... %x:%x is using our IP address %d.%d.%d.%d on %s.

Duplicate IP address warning. ARP has discovered another host on a local network that responds to mapping requests for the Internet address of this system, and has defended the system against this node by re-announcing the ARP entry.

%s has duplicate address %d.%d.%d.%d (in use by %x:%x ... %x:%x); disabled.

Duplicate IP address detected while performing initial probing. The newly-configured interface has been shut down.

%s has duplicate address %d.%d.%d.%d (claimed by %x:%x ... %x:%x); disabled.

Duplicate IP address detected on a running IP interface. The conflict cannot be resolved, and the interface has been disabled to protect the network.

Recovered address %d.%d.%d.%d on %s.

An interface with a previously-conflicting IP address has been recovered automatically and reenabled. The conflict has been resolved.

Proxy ARP problem? Node '%x:%x ... %x:%x' is using %d.%d.%d.%d on %s

This message appears if arp(1M) has been used to create a published permanent (ATF_AUTHORITY) entry, and some other host on the local network responds to mapping requests for the published ARP entry.