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Network Working Group                                Smoot Carl-MitchellRequest for Comments: 1027                     Texas Internet Consulting                                                      John S. Quarterman                                               Texas Internet Consulting                                                            October 1987Using ARP to Implement Transparent Subnet GatewaysStatus of this Memo    This RFC describes the use of the Ethernet Address Resolution    Protocol (ARP) by subnet gateways to permit hosts on the connected    subnets to communicate without being aware of the existence of    subnets, using the technique of "Proxy ARP" [6].  It is based onRFC-950 [1],RFC-922 [2], andRFC-826 [3] and is a restricted subset    of the mechanism ofRFC-925 [4].  Distribution of this memo is    unlimited.Acknowledgment    The work described in this memo was performed while the authors were    employed by the Computer Sciences Department of the University of    Texas at Austin.Introduction    The purpose of this memo is to describe in detail the implementation    of transparent subnet ARP gateways using the technique of Proxy ARP.    The intent is to document this widely used technique.1.  Motivation    The Ethernet at the University of Texas at Austin is a large    installation connecting over ten buildings.  It currently has more    than one hundred hosts connected to it [5].  The size of the    Ethernet and the amount of traffic it handles prohibit tying it    together by use of repeaters.  The use of subnets provided an    attractive alternative for separating the network into smaller    distinct units.    This is exactly the situation for which Internet subnets as    described inRFC-950 are intended.  Unfortunately, many vendors had    not yet implemented subnets, and it was not practical to modify the    more than half a dozen different operating systems running on hosts    on the local networks.Carl-Mitchell & Quarterman                                      [Page 1]

RFC 1027          ARP and Transparent Subnet Gateways       October 1987    Therefore a method for hiding the existence of subnets from hosts    was highly desirable.  Since all the local area networks supported    ARP, an ARP-based method (commonly known as "Proxy ARP" or the "ARP    hack") was chosen.  In this memo, whenever the term "subnet" occurs    the "RFC-950 subnet method" is assumed.2.  Design2.1  Basic method    On a network that supports ARP, when host A (the source) broadcasts    an ARP request for the network address corresponding to the IP    address of host B (the target), host B will recognize the IP address    as its own and will send a point-to-point ARP reply.  Host A keeps    the IP-to-network-address mapping found in the reply in a local    cache and uses it for later communication with host B.    If hosts A and B are on different physical networks, host B will not    receive the ARP broadcast request from host A and cannot respond to    it.  However, if the physical network of host A is connected by a    gateway to the physical network of host B, the gateway will see the    ARP request from host A.  Assuming that subnet numbers are made to    correspond to physical networks, the gateway can also tell that the    request is for a host that is on a different physical network from    the requesting host.  The gateway can then respond for host B,    saying that the network address for host B is that of the gateway    itself.  Host A will see this reply, cache it, and send future IP    packets for host B to the gateway.  The gateway will forward such    packets to host B by the usual IP routing mechanisms.  The gateway    is acting as an agent for host B, which is why this technique is    called "Proxy ARP"; we will refer to this as a transparent subnet    gateway or ARP subnet gateway.    When host B replies to traffic from host A, the same algorithm    happens in reverse: the gateway connected to the network of host B    answers the request for the network address of host A, and host B    then sends IP packets for host A to gateway.  The physical networks    of host A and B need not be connected to the same gateway. All that    is necessary is that the networks be reachable from the gateway.    With this approach, all ARP subnet handling is done in the ARP    subnet gateways.  No changes to the normal ARP protocol or routing    need to be made to the source and target hosts.  From the host point    of view, there are no subnets, and their physical networks are    simply one big IP network.  If a host has an implementation of    subnets, its network masks must be set to cover only the IP network    number, excluding the subnet bits, for the system to work properly.Carl-Mitchell & Quarterman                                      [Page 2]

RFC 1027          ARP and Transparent Subnet Gateways       October 19872.2  Routing    As part of the implementation of subnets, it is expected that the    elements of routing tables will include network numbers including    both the IP network number and the subnet bits, as specified by the    subnet mask, where appropriate.  When an ARP request is seen, the    ARP subnet gateway can determine whether it knows a route to the    target host by looking in the ordinary routing table.  If attempts    to reach foreign IP networks are eliminated early (see Sanity Checks    below), only a request for an address on the local IP network will    reach this point.  We will assume that the same network mask applies    to every subnet of the same IP network.  The network mask of the    network interface on which the ARP request arrived can then be    applied to the target IP address to produce the network part to be    looked up in the routing table.    In 4.3BSD (and probably in other operating systems), a default route    is possible.  This default route specifies an address to forward a    packet to when no other route is found.  The default route must not    be used when checking for a route to the target host of an ARP    request.  If the default route were used, the check would always    succeed.  But the host specified by the default route is unlikely to    know about subnet routing (since it is usually an Internet gateway),    and thus packets sent to it will probably be lost.  This special    case in the routing lookup method is the only implementation change    needed to the routing mechanism.    If the network interfaces on which the request was received and    through which the route to the target passes are the same, the    gateway must not reply.  In this case, either the target host is on    the same physical network as the gateway (and thus the host should    reply for itself), or this gateway is not on the most direct path to    the desired network, i.e., there is another gateway on the same    physical network that is on a more direct path and the other gateway    should respond.RFC-925 [4] describes a general mechanism for dynamic subnet routing    using Proxy ARP and routing caches in the gateways.  Our technique    is restricted subset ofRFC-925, in which we use static subnet    routes which are determined administratively.  As a result, our    transparent subnet gateways require no new network routing table    entries nor ARP cache entries; the only tables which are affected    are the ARP caches in the host.    In our implementation, routing loops are prevented by proper    administration of the subnet routing tables in the gateways.Carl-Mitchell & Quarterman                                      [Page 3]

RFC 1027          ARP and Transparent Subnet Gateways       October 19872.3  Multiple gateways    The simplest subnet organization to administer is a tree structure,    which cannot have loops.  However, it may be desirable for    reliability or traffic accommodation to have more than one gateway    (or path) between two physical networks.  ARP subnet gateways may be    used in such a situation:  a requesting host will use the first ARP    response it receives, even if more than one gateway supplies one.    This may even provide a rudimentary load balancing service, since if    two gateways are otherwise similar, the one most lightly loaded is    the more likely to reply first.    More complex mechanisms could be built in the form of gateway-to-    gateway protocols, and will no doubt become necessary in networks    with large numbers of subnets and gateways, in the same way that    gateway-to-gateway protocols are generally necessary among IP    gateways.2.4  Sanity checks    Care must be taken by the network and gateway administrators to keep    the network masks the same on all the subnet gateway machines.  The    most common error is to set the network mask on a host without a    subnet implementation to include the subnet number.  This causes the    host to fail to attempt to send packets to hosts not on its local    subnet.  Adjusting its routing tables will not help, since it will    not know how to route to subnets.    If the IP networks of the source and target hosts of an ARP request    are different, an ARP subnet gateway implementation should not    reply.  This is to prevent the ARP subnet gateway from being used to    reach foreign IP networks and thus possibly bypass security checks    provided by IP gateways.    An ARP subnet gateway implementation must not reply if the physical    networks of the source and target of an ARP request are the same.    In this case, either the target host is presumably either on the    same physical network as the source host and can answer for itself,    or the target host lies in the same direction from the gateway as    does the source host, and an ARP reply from the would cause a loop.    An ARP request for a broadcast address must elicit no reply,    regardless of the source address or physical networks involved.  If    the gateway were to respond with an ARP reply in this situation, it    would be inviting the original source to send actual traffic to a    broadcast address.  This could result in the "Chernobyl effect"    wherein every host on the network replies to such traffic, causing    network "meltdown".Carl-Mitchell & Quarterman                                      [Page 4]

RFC 1027          ARP and Transparent Subnet Gateways       October 19872.5  Multiple logical subnets per physical network    The most straightforward way to assign subnet numbers is one to one    with physical networks.  There are, however, circumstances in which    multiple logical subnets per physical network are quite useful.  One    of the more common is when it is planned that a group of    workstations will be put on their own physical network but the    gateway to the new physical network needs to be tested first.  (A    repeater might be used when the gateway was not usable).  If a rule    of one subnet per physical network is enforced, the addresses of the    workstations must be changed every time the gateway is tested.  If    they may be assigned addresses using a new subnet number while they    are still on the old physical network, no further address changes    are needed.    To permit multiple subnets per physical network, an ARP subnet    gateway must use the physical network interface, not the subnet    number to determine when to reply to an ARP request.  That is, it    should send a proxy ARP reply only when the source network interface    differs from the target network interface. In addition, appropriate    routing table entries for these "phantom" subnets must be added to    the subnet gateway routing tables.2.6  Broadcast addresses    There are two kinds of IP broadcast addresses:  main IP directed    network broadcast and subnet broadcast.  An IP network broadcast    address consists of the network number plus a well-known value in    the rest (local part) of the address.  An IP subnet broadcast is    similar, except both the IP network number and the subnet number    bits are included.RFC-922 standardized the use of all ones in the    local part, but there were two conventions in use before that:  all    ones and all zeros.  For example, 4.2BSD used all zeros, and 4.3BSD    uses all ones.  Thus there are four kinds of IP directed broadcast    addresses still currently in use on many networks.    With transparent subnetting a subnet gateway must not issue an IP    broadcast using the subnet broadcast address, e.g., 128.83.138.255.    Hosts on the physical network that receive the broadcast will not    understand such an address as a broadcast address, since they will    not have subnets enabled (or will not have subnet implementations).    In fact, 4.2BSD hosts (with or without subnet implementations) will    instead treat an address with all ones in the local part as a    specific host address and try to forward the packet.  Since there is    no such target host, there will be no entry in the forwarding host's    ARP tables and it will generate an ARP request for the target host.    This presents the scenario (actually observed) of a 4.3BSD gateway    running the rwho program, which broadcasts a packet once a minute,Carl-Mitchell & Quarterman                                      [Page 5]

RFC 1027          ARP and Transparent Subnet Gateways       October 1987    causing every 4.2BSD host on the local physical network to generate    an ARP request at the same time.  The same problem occurs with any    subnet broadcast address, whether the local part is all zeros or all    ones.    Thus a subnet gateway in a network with hosts that do not understand    subnets must take care not to use subnet broadcast addresses:    instead it must use the IP network directed broadcast address    instead.    Finally, since many hosts running out-of-date software will still be    using (and expecting) old-style all-zeros IP network broadcast    addresses, the gateway must send its broadcast addresses out in that    form, e.g., 128.83.0.0.  It might be safe to also send a duplicate    packet with all ones in the local part, e.g., 128.83.255.255.  It is    not clear whether the local network broadcast address of all ones,    255.255.255.255, will cause ill effects, but it is very likely that    it will not be recognized by many hosts that are running older    software.3.  Implementation in 4.3BSD    Subnet gateways using ARP have been implemented by a number of    different people.  The particular method described in this memo was    first implemented in 4.2BSD on top of retrofitted beta-test 4.3BSD    subnet code, and has since been reimplemented as an add-on to the    distributed 4.3BSD sources.  The latter implementation is described    here.    Most of the new kernel code for the subnet ARP gatewaying function    is in the generic Ethernet interface module, netinet/if_ether.c.  It    consists of eight lines in in_arpinput that perform a couple of    quick checks (to ensure that the facility is enabled on the source    interface and that the source and target addresses are on different    subnets), call a new routine, if_subarp, for further checks, and    then build the ARP response if all checks succeed.  This code is    only reached when an ARP request is received, and does nothing if    the facility is not enabled on the source interface.  Thus    performance of the gateway should be very little degraded by this    addition.  (Performance of the requesting host should also be    similar to the latter case, as the only difference there is between    efficiency of the ARP cache and of the routing tables).    The routine if_subarp (about sixty lines) ensures that the source    and target addresses are on the same IP network and that the target    address is none of the four kinds of directed broadcast address.  It    then attempts to find a path to the target either by finding a    network interface with the desired subnet or by looking in theCarl-Mitchell & Quarterman                                      [Page 6]

RFC 1027          ARP and Transparent Subnet Gateways       October 1987    routing tables.  Even if a network interface is found that leads to    the target, for a reply to be sent the ARP gateway must be enabled    on that interface and the target and source interfaces must be    different.    The file netinet/route.c has a static routing entry structure    definition added, and modifications of about eight lines are made to    the main routing table lookup routine, rtalloc, to recognize a    pointer to that structure (when passed by if_subarp) as a direction    to not use the default route in this routing check.  The processor    priority level (critical section protection) around the inner    routing lookup check is changed to a higher value, as the routine    may now be called from network interface interrupts as well as from    the internal software interrupts that drive processing of IP and    other high level protocols.  This raised processor priority could    conceivably slow the whole kernel somewhat if there are many routing    checks, but since the critical section is fast, the effect should be    small.    A key kernel modification is about fifteen lines added to the    routine ip_output in netinet/ip_output.c.  It changes subnet    broadcast addresses in packets originating at the gateway to IP    network broadcast addresses so that hosts without subnet code (or    with their network masks set to ignore subnets) will recognize them    as broadcast addresses.  This section of code is only used if the    ARP gateway is turned on for the outgoing interface, and only    affects subnet broadcast addresses.    A new routine, in_mainnetof, of about fifteen lines, is added to    netinet/in.c to return the IP network number (without subnet number)    from an IP address.  It is called from if_subarp and ip_output.    Two kernel parameter files have one line added to each:  net/if.h    has a definition of a bit in the network interface structure to    indicate whether subnet ARP gateways are enabled, and netinet/in.h    refers to in_mainnetof.    In addition to these approximately 110 lines of kernel source    additions, there is one user-level modification.  The source to the    command ifconfig, which is used to set addresses and network masks    of network interfaces, has four lines added to allow it to turn the    subnet ARP gateway facility on or off, for each interface.  This is    documented in eleven new lines in the manual entry for that command.Carl-Mitchell & Quarterman                                      [Page 7]

RFC 1027          ARP and Transparent Subnet Gateways       October 19874.  Availability    The 4.3BSD implementation is currently available by anonymous FTP    (login anonymous, password guest) from sally.utexas.edu as    pub/subarp, which is a 4.3BSD "diff -c" listing from the 4.3BSD    sources that were distributed in September 1986.    This implementation was not included in the 4.3BSD distribution    proper because U.C. Berkeley CSRG thought that that would reduce the    incentive for vendors to implement subnets perRFC-950.  The authors    concur.  Nonetheless, there are circumstances in which the use of    transparent subnet ARP gateways is indispensable.References   1.  Mogul, J., and J. Postel, "Internet Standard Subnetting       Procedure",RFC-950, Stanford University and USC/Information       Sciences Institute, August 1985.   2.  Mogul, J., "Broadcasting Internet Datagrams in the Presence of       Subnets",RFC-922, Computer Science Department, Stanford       University, October 1984.   3.  Plummer, D., "An Ethernet Address Resolution Protocol or       Converting Network Protocol Addresses to 48-bit Ethernet       Addresses for Transmission on Ethernet Hardware",RFC-826,       Symbolics, November 1982.   4.  Postel, J., "Multi-LAN Address Resolution",RFC-925,       USC/Information Sciences Institute, October 1984.   5.  Carl-Mitchell, S., and J. S. Quarterman, "Nameservers in a Campus       Domain", SIGCUE Outlook, Vol.19, No.1/2, pp.78-88, ACM SIG       Computer Uses in Education, P.O. Box 64145, Baltimore, MD 21264,       Spring/Summer 1986.   6.  Braden, R., and J. Postel, "Requirements for Internet Gateways",RFC-1009, USC/Information Sciences Institute, June 1987.Carl-Mitchell & Quarterman                                      [Page 8]