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Versions: 00 01 02 03 04 05 06 07 RFC 6886

Document: draft-cheshire-nat-pmp-02.txt                  Stuart Cheshire
Internet-Draft                                             Marc Krochmal
Category: Standards Track                           Apple Computer, Inc.
Expires 14th March 2007                                      Kiren Sekar
                                                         Sharpcast, Inc.
                                                     14th September 2006

                   NAT Port Mapping Protocol (NAT-PMP)

                     <draft-cheshire-nat-pmp-02.txt>

Status of this Memo

   By submitting this Internet-Draft, each author represents that any
   applicable patent or other IPR claims of which he or she is aware
   have been or will be disclosed, and any of which he or she becomes
   aware will be disclosed, in accordance with Section 6 of BCP 79.
   For the purposes of this document, the term "BCP 79" refers
   exclusively to RFC 3979, "Intellectual Property Rights in IETF
   Technology", published March 2005.

   Internet-Drafts are working documents of the Internet Engineering
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   Internet-Drafts are draft documents valid for a maximum of six months
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Abstract

   This document describes a protocol for automating the process of
   creating Network Address Translation (NAT) port mappings. Included
   in the protocol is a method for retrieving the public IP address of
   a NAT gateway, thus allowing a client to make this public IP address
   and port number known to peers that may wish to communicate with it.
   This protocol is implemented in current Apple products including
   Mac OS X, Bonjour for Windows, and AirPort wireless base stations.










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1. Introduction

   Network Address Translation (NAT) is a method of sharing one public
   internet address with a number of devices. This document is focused
   on what "IP Network Address Translator (NAT) Terminology and
   Considerations" [RFC 2663] calls "NAPTs" (Network Address/Port
   Translators). A full description of NAT is beyond the scope of this
   document. The following brief overview will cover the aspects
   relevant to this port mapping protocol. For more information on
   NAT, see "Traditional IP Network Address Translator" [RFC 3022].

   NATs have one or more public IP addresses. A private network is set
   up behind the NAT. Devices behind the NAT are assigned private
   addresses and the private address of the NAT device is used as the
   gateway.

   When a packet from any device behind the NAT is sent to an address on
   the public internet, the packet first passes through the NAT box. The
   NAT box looks at the source port and address. In some cases, a NAT
   will also keep track of the destination port and address. The NAT
   then creates a mapping from the private address and private port to a
   public address and public port if a mapping does not already exist.
   The NAT box replaces the private address and port number in the
   packet with the public entries from the mapping and sends the packet
   on to the next gateway.

   When a packet from any address on the internet is received on the
   NAT's public side, the NAT will look up the destination port (public
   port) in the list of mappings. If an entry is found, it will contain
   the private address and port that the packet should be sent to. The
   NAT gateway will then rewrite the destination address and port with
   those from the mapping. The packet will then be forwarded to the new
   destination addresses. If the packet did not match any mapping, the
   packet will most likely be dropped. Various NATs implement different
   strategies to handle this. The important thing to note is that if
   there is no mapping, the NAT does not know which private address the
   packet should be sent to.

   Mappings are usually created automatically as a result of observing
   outbound traffic. There are a few exceptions. Some NATs may allow
   manually-created permanent mappings that map a public port to a
   specific private IP address and port. Such a mapping allows incoming
   connections to the device with that private address. Some NATs also
   implement a default mapping where any inbound traffic that does not
   match a mapping will always be forwarded to a specific private
   address. Both types of mappings are usually set up manually through
   some configuration tool.

   Without these manually-created inbound port mappings, clients behind
   the NAT would be unable to receive inbound connections, which
   represents a loss of connectivity when compared to the original


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   Internet architecture [ETEAISD]. For those who view this loss of
   connectivity as a bad thing, NAT-PMP allows clients to operate much
   more like a host directly connected to the unrestricted public
   Internet, with an unrestricted public IP address. NAT-PMP allows
   client hosts to communicate with the NAT gateway to request the
   creation of inbound mappings on demand. Having created a NAT mapping
   to allow inbound connections, the client can then record its public
   IP address and public port number in a public registry (e.g. the
   world-wide Domain Name System) or otherwise make it accessible to
   peers that wish to communicate with it.


2. Conventions and Terminology Used in this Document

   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
   document are to be interpreted as described in "Key words for use in
   RFCs to Indicate Requirement Levels" [RFC 2119].


3. Protocol and Packet Format

   NAT Port Mapping Protocol runs over UDP. Every packet starts with an
   8 bit version followed by an 8 bit operation code.

   This document specifies version 0 of the protocol. Any NAT-PMP
   gateway implementing this version of the protocol, receiving a
   packet with a version number other than 0, MUST return result code 1
   (Unsupported Version).

   Opcodes between 0 and 127 are client requests. Opcodes from 128 to
   255 are server responses. Responses always contain a 16 bit result
   code in network byte order. A result code of zero indicates success.
   Responses also contain a 32 bit unsigned integer corresponding to the
   number of seconds since the NAT gateway was rebooted or since its
   port mapping state was reset.

   This protocol SHOULD only be used when the client determines that
   its primary IPv4 address is in one of the private IP address ranges
   defined in "Address Allocation for Private Internets" [RFC 1918].
   This includes the address ranges 10/8, 172.16/12, and 192.168/16.

   Clients always send their Port Mapping Protocol requests to their
   default gateway, as learned via DHCP [RFC 2131], or similar means.
   This protocol is designed for small home networks, with a single
   logical link (subnet) where the client's default gateway is also the
   NAT translator for that network. For more complicated networks where
   the NAT translator is some device other than the client's default
   gateway, this protocol is not appropriate.




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3.1 Requests and Responses

   NAT gateways are often low-cost devices, with limited memory and
   CPU speed. For this reason, to avoid making excessive demands on
   the NAT gateway, clients machines SHOULD NOT issue multiple requests
   simultaneously in parallel. If a client needs to perform multiple
   requests (e.g. on boot, wake from sleep, network connection, etc.)
   it SHOULD queue them and issue them serially one at a time. Once the
   NAT gateway responds to one request the client machine may issue the
   next. In the case of a fast NAT gateway, the client may be able to
   complete requests at a rate of hundreds per second. In the case of
   a slow NAT gateway that takes perhaps half a second to respond to
   a NAT-PMP request, the client SHOULD respect this and allow the
   NAT gateway to operate at the pace it can manage, and not overload
   it by issuing requests faster than the rate it's answering them.

   To determine the puclic IP address or request a port mapping,
   a NAT-PMP client sends its request packet to port 5351 of its
   configured gateway address, and waits 250ms for a response. If no
   NAT-PMP response is received from the gateway after 250ms, the client
   retransmits its request and waits 500ms. The client SHOULD repeat
   this process with the interval between attempts doubling each time.
   If, after sending its 9th attempt (and then waiting for 64 seconds),
   the client has still received no response, then it SHOULD conclude
   that this gateway does not support NAT Port Mapping Protocol and
   MAY log an error message indicating this fact. In addition, if the
   NAT-PMP client receives an "ICMP Port Unreachable" message from the
   gateway for port 5351 then it can skip any remaining retransmissions
   and conclude immediately that the gateway does not support NAT-PMP.

   As a performance optimization the client MAY record this information
   and use it to suppress further attempts to use NAT-PMP, but the
   client should not retain this information for too long. In
   particular, any event that may indicate a potential change of gateway
   or a change in gateway configuration (hardware link change
   indication, change of gateway MAC address, acquisition of new DHCP
   lease, receipt of NAT-PMP announcement packet from gateway, etc.)
   should cause the client to discard its previous information regarding
   the gateway's lack of NAT-PMP support, and send its next NAT-PMP
   request packet normally.


3.2 Determining the Public Address

   To determine the public address, the client behind the NAT sends the
   following UDP payload to port 5351 of the configured gateway address:

    0                   1
    0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   | Vers = 0      | OP = 0        |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

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   A compatible NAT gateway MUST generate a response with the following
   format:

    0                   1                   2                   3
    0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   | Vers = 0      | OP = 128 + 0  | Result Code                   |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   | Seconds Since Start of Epoch                                  |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   | Public IP Address (a.b.c.d)                                   |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

   This response indicates that the NAT gateway implements this version
   of the protocol and returns the public IP address of the NAT gateway.
   If the result code is non-zero, the value of Public IP Address is
   undefined (MUST be set to zero on transmission, and MUST be ignored
   on reception).

   The NAT gateway MUST fill in the "Seconds Since Start of Epoch" field
   with the time elapsed since its port mapping table was initialized on
   startup or reset for any other reason (see Section 3.6 "Seconds Since
   Start of Epoch").

   Upon receiving the response packet, the client MUST check the source
   IP address, and silently discard the packet if the address is not the
   address of the gateway to which the request was sent.


3.2.1 Announcing Address Changes

   When the public IP address of the NAT changes, the NAT gateway MUST
   send a gratuitous response to the link-local multicast address
   224.0.0.1, port 5351 with the packet format above to notify clients
   of the new public IP address. To accommodate packet loss, the
   NAT gateway SHOULD multicast 10 address change notifications.
   The interval between the first two notifications SHOULD be 250ms,
   and the interval between each subsequent notification SHOULD double.

   Upon receiving a gratuitous address change announcement packet,
   the client MUST check the source IP address, and silently discard
   the packet if the address is not the address of the client's
   current configured gateway. This is to guard against inadvertent
   misconfigurations where there may be more than one NAT gateway
   active on the network.








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3.3 Creating a Mapping

   To create a mapping, the client sends a UDP packet to port 5351
   of the gateway's private IP address with the following format:

    0                   1                   2                   3
    0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   | Vers = 0      | OP = x        | Reserved (MUST be zero)       |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   | Private Port                  | Requested Public Port         |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   | Requested Port Mapping Lifetime in Seconds                    |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

   Opcodes supported:
   1 - Map UDP
   2 - Map TCP

   The Reserved field MUST be set to zero on transmission and MUST
   be ignored on reception.

   The Private Port is set to the local port on which the client is
   listening.

   The Requested Public Port SHOULD usually be set to the same value as
   the local Private Port, or zero if the client has no preference for
   what port is assigned. However, the gateway is not obliged to assign
   the port requested, and may choose not to, either for policy reasons
   (e.g. port 80 is reserved and clients may not request it) or because
   that port has already been assigned to some other client. Because
   of this, some product developers have questioned the value of having
   the Requested Public Port field at all. The reason is for failure
   recovery. Most low-cost home NAT gateways do not record temporary
   port mappings in persistent storage, so if the gateway crashes or is
   rebooted, all the mappings are lost. A renewal packet is formatted
   identically to an initial mapping request packet, except that for
   renewals the client sets the Requested Public Port field to the
   port the gateway actually assigned, rather than the port the client
   originally wanted. When a freshly-rebooted NAT gateway receives a
   renewal packet from a client, it appears to the gateway just like
   an ordinary initial request for a port mapping, except that in this
   case the Requested Public Port is likely to be one that the NAT
   gateway *is* willing to allocate (it allocated it to this client
   right before the reboot, so it should presumably be willing to
   allocate it again).

   The RECOMMENDED Port Mapping Lifetime is 3600 seconds.





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   After sending the port mapping request, the client then waits for the
   NAT gateway to respond. If after 250ms, the gateway doesn't respond,
   the client SHOULD re-issue its request as described above in Section
   3.1 "Requests and Responses".

   The NAT gateway responds with the following packet format:

    0                   1                   2                   3
    0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   | Vers = 0      | OP = 128 + x  | Result Code                   |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   | Seconds Since Start of Epoch                                  |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   | Private Port                  | Mapped Public Port            |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   | Port Mapping Lifetime in Seconds                              |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

   The 'x' in the OP field MUST match what the client requested. Some
   NAT gateways are incapable of creating a UDP port mapping without
   also creating a corresponding TCP port mapping, and vice versa, and
   these gateways MUST NOT implement NAT Port Mapping Protocol until
   this deficiency is fixed. A NAT gateway which implements this
   protocol MUST be able to create TCP-only and UDP-only port mappings.

   If a NAT gateway silently creates a pair of mappings for a client
   that only requested one mapping, then it may expose that client to
   receiving inbound UDP packets or inbound TCP connection requests
   that it did not ask for and does not want.

   While a NAT gateway MUST NOT automatically create mappings for TCP
   when the client requests UDP, and vice versa, the NAT gateway MUST
   reserve the companion port so the same client can choose to map it
   in the future. For example, if a client requests to map TCP port 80,
   as long as the client maintains the lease for that TCP port mapping,
   another client with a different IP address MUST NOT be able to
   successfully acquire the mapping for UDP port 80.

   The client normally requests the public port matching the private
   port. If that public port is not available, the NAT gateway MUST
   return a public port that is available or return an error code if
   no ports are available.

   The source address of the packet MUST be used for the private address
   in the mapping. This protocol is not intended to facilitate one
   device behind a NAT creating mappings for other devices. If there
   are legacy devices that require inbound mappings, permanent mappings
   can be created manually by the administrator, just as they are today.




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   If a mapping already exists for a given private port on a given local
   client (whether that mapping was created explicitly using NAT-PMP,
   implicitly as a result of an outgoing TCP SYN packet, or manually by
   a human administrator) and that client requests another mapping for
   the same private port (possibly requesting a different public port)
   then the mapping request should succeed, returning the already-
   assigned public port. This is necessary to handle the case where
   a client requests a mapping with requested public port X, and is
   granted a mapping with actual public port Y, but the acknowledgement
   packet gets lost. When the client retransmits its mapping request,
   it should get back the same positive acknowledgement as was sent (and
   lost) the first time.

   The NAT gateway SHOULD NOT accept mapping requests destined to the
   NAT gateway's public IP address or received on its public network
   interface. Only packets received on the private interface(s) with
   a destination address matching the private address(es) of the NAT
   gateway should be allowed.

   The NAT gateway MUST fill in the "Seconds Since Start of Epoch" field
   with the time elapsed since its port mapping table was initialized on
   startup or reset for any other reason (see Section 3.6 "Seconds Since
   Start of Epoch").

   The Port Mapping Lifetime is an unsigned integer in seconds. The NAT
   gateway MAY reduce the lifetime from what the client requested. The
   NAT gateway SHOULD NOT offer a lease lifetime greater than that
   requested by the client.

   Upon receiving the response packet, the client MUST check the source
   IP address, and silently discard the packet if the address is not the
   address of the gateway to which the request was sent.

   The client SHOULD begin trying to renew the mapping halfway to expiry
   time, like DHCP. The renewal packet should look exactly the same as
   a request packet, except that the client SHOULD set the requested
   public port to what the NAT gateway previously mapped, not what the
   client originally requested. As described above, this enables the
   gateway to automatically recover its mapping state after a crash or
   reboot.


3.4 Destroying a Mapping

   A mapping may be destroyed in a variety of ways. If a client fails
   to renew a mapping, then when its lifetime expires the mapping MUST
   be automatically deleted. In the common case where the gateway
   device is a combined DHCP server and NAT gateway, when a client's
   DHCP address lease expires, the gateway device MAY automatically
   delete any mappings belonging to that client. Otherwise a new client
   being assigned the same IP address could receive unexpected inbound


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   UDP packets or inbound TCP connection requests that it did not ask
   for and does not want.

   A client MAY also send an explicit packet to request deletion of a
   mapping that is no longer needed. A client requests explicit
   deletion of a mapping by sending a message to the NAT gateway
   requesting the mapping, with the Requested Lifetime in Seconds set
   to 0. The requested public port MUST be set to zero by the client
   on sending, and MUST be ignored by the gateway on reception.

   When a mapping is destroyed successfully as a result of the client
   explicitly requesting the deletion, the NAT gateway MUST send a
   response packet which is formatted as defined in section 3.3
   "Creating a Mapping". The response MUST contain a result code of 0,
   the private port as indicated in the deletion request, a public port
   of 0, and a lifetime of 0. The NAT gateway MUST respond to a request
   to destroy a mapping that does not exist as if the request were
   successful. This is because of the case where the acknowledgement is
   lost, and the client retransmits its request to delete the mapping.
   In this case the second request to delete the mapping MUST return the
   same response packet as the first request.

   If the deletion request was unsuccessful, the response MUST contain a
   non-zero result code and the requested mapping; the lifetime is
   undefined (MUST be set to zero on transmission, and MUST be ignored
   on reception). If the client attempts to delete a port mapping which
   was manually assigned by some kind of configuration tool, the NAT
   gateway MUST respond with a 'Not Authorized' error, result code 2.

   When a mapping is destroyed as a result of its lifetime expiring or
   for any other reason, if the NAT gateway's internal state indicates
   that there are still active TCP connections traversing that now-
   defunct mapping, then the NAT gateway SHOULD send appropriately-
   constructed TCP RST (reset) packets both to the local client and to
   the remote peer on the Internet to terminate that TCP connection.

   A client can request the explicit deletion of all its UDP or TCP
   mappings by sending the same deletion request to the NAT gateway
   with public port, private port, and lifetime set to 0. A client MAY
   choose to do this when it first acquires a new IP address in order to
   protect itself from port mappings that were performed by a previous
   owner of the IP address. After receiving such a deletion request,
   the gateway MUST delete all its UDP or TCP port mappings (depending
   on the opcode). The gateway responds to such a deletion request with
   a response as described above, with the private port set to zero. If
   the gateway is unable to delete a port mapping, for example, because
   the mapping was manually configured by the administrator, the gateway
   MUST still delete as many port mappings as possible, but respond with
   a non-zero result code. The exact result code to return depends on
   the cause of the failure. If the gateway is able to successfully
   delete all port mappings as requested, it MUST respond with a result
   code of 0.

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3.5 Result Codes

   Currently defined result codes:
   0 - Success
   1 - Unsupported Version
   2 - Not Authorized/Refused
       (e.g. box supports mapping, but user has turned feature off)
   3 - Network Failure
       (e.g. NAT box itself has not obtained a DHCP lease)
   4 - Out of resources
       (NAT box cannot create any more mappings at this time)
   5 - Unsupported opcode

   If the result code is non-zero, the format of the packet following
   the result code may be truncated. For example, if the client sends a
   request to the server with an opcode of 17 and the server does not
   recognize that opcode, the server SHOULD respond with a message where
   the opcode is 17 + 128 and the result code is 5 (opcode not
   supported). Since the server does not understand the format of
   opcode 17, it may not know what to place after the result code. In
   some cases, relevant data may follow the opcode to identify the
   operation that failed. For example, a client may request a mapping
   but that mapping may fail due to resource exhaustion. The server
   SHOULD respond with the result code to indicate resource exhaustion
   (4) followed by the requested port mapping so the client may identify
   which operation failed.

   Clients MUST be able to properly handle result codes not defined in
   this document. Undefined results codes MUST be treated as fatal
   errors of the request.


3.6 Seconds Since Start of Epoch

   Every packet sent by the NAT gateway includes a "Seconds since start
   of epoch" field (SSSOE). If the NAT gateway resets or loses the
   state of its port mapping table, due to reboot, power failure, or any
   other reason, it MUST reset its epoch time and begin counting SSSOE
   from 0 again. Whenever a client receives any packet from the NAT
   gateway, either gratuitously or in response to a client request, the
   client computes its own conservative estimate of the expected SSSOE
   value by taking the SSSOE value in the last packet it received from
   the gateway and adding 7/8 (87.5%) of the time elapsed since that
   packet was received. If the SSSOE in the newly received packet is
   less than the client's conservative estimate by more than one second,
   then the client concludes that the NAT gateway has undergone a reboot
   or other loss of port mapping state, and the client MUST immediately
   renew all its active port mapping leases as described in Section 3.7
   "Recreating Mappings On NAT Gateway Reboot".




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3.7 Recreating Mappings On NAT Gateway Reboot

   The NAT gateway MAY store mappings in persistent storage so when it
   is powered off or rebooted, it remembers the port mapping state of
   the network.

   However, maintaining this state is not essential for correct
   operation. When the NAT gateway powers on or clears its port mapping
   state as the result of a configuration change, it MUST reset the
   epoch time and re-announce its IP address as described in Section
   3.2.1 "Announcing Address Changes". Reception of this packet where
   time has apparently gone backwards serves as a hint to clients
   on the network that they SHOULD immediately send renewal packets
   (to immediately recreate their mappings) instead of waiting until
   the originally scheduled time for those renewals. Clients who miss
   receiving those gateway announcement packets for any reason will
   still renew their mappings at the originally scheduled time and cause
   their mappings to be recreated; it will just take a little longer for
   these clients.

   A mapping renewal packet is formatted identically to an original
   mapping request; from the point of view of the client it is a
   renewal of an existing mapping, but from the point of view of the
   freshly-rebooted NAT gateway it appears as a new mapping request.

   This self-healing property of the protocol is very important.

   The remarkable reliability of the Internet as a whole derives
   in large part from the fact that important state is held in the
   endpoints, not in the network itself [ETEAISD]. Power-cycling an
   Ethernet switch results only in a brief interruption in the flow
   of packets; established TCP connections through that switch are not
   broken, merely delayed for a few seconds. Indeed, an old Ethernet
   switch can even be replaced with a new one, and as long as the cables
   are transferred over reasonably quickly, after the upgrade all the
   TCP connections that were previously going though the old switch will
   be unbroken and now going through the new one. The same is true of
   IP routers, wireless base stations, etc. The one exception is NAT
   gateways. Because the port mapping state is required for the NAT
   gateway to know where to forward inbound packets, loss of that state
   breaks connectivity through the NAT gateway. By allowing clients to
   detect when this loss of NAT gateway state has occurred, and recreate
   it on demand, we turn hard state in the network into soft state, and
   allow it to be recovered automatically when needed.

   Without this automatic recreation of soft state in the NAT gateway,
   reliable long-term networking would not be achieved. As mentioned
   above, the reliability of the Internet does not come from trying
   to build a perfect network in which errors never happen, but from
   accepting that in any sufficiently large system there will always be
   some component somewhere that's failing, and designing mechanisms


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   that can handle those failures and recover. To illustrate this point
   with an example, consider the following scenario: Imagine a network
   security camera that has a web interface and accepts incoming
   connections from web browser clients. Imagine this network security
   camera uses NAT-PMP or a similar protocol to set up an inbound
   port mapping in the NAT gateway so that it can receive incoming
   connections from clients the other side of the NAT gateway.
   Now, this camera may well operate for weeks, months, or even years.
   During that time it's possible that the NAT gateway could experience
   a power failure or be rebooted. The user could upgrade the NAT
   gateway's firmware, or even replace the entire NAT gateway device
   with a newer model. The general point is that if the camera operates
   for a long enough period of time, some kind of disruption to the NAT
   gateway becomes inevitable. The question is not whether the NAT
   gateway will lose its port mappings, but when, and how often.
   If the network camera and devices like it on the network can detect
   when the NAT gateway has lost its port mappings, and recreate them
   automatically, then these disruptions are self-correcting and
   invisible to the end user. If, on the other hand, the disruptions are
   not self-correcting, and after a NAT gateway reboot the user has to
   manually reset or reboot all the other devices on the network too,
   then these disruptions are *very* visible to the end user. This
   aspect of the design is what makes the difference between a protocol
   that keeps on working indefinitely over a time scale of months or
   years, and a protocol that works in brief testing, but in the real
   world is continually failing and requiring manual intervention to get
   it going again.

   When a client renews its port mappings as the result of receiving
   a packet where the "Seconds since start of epoch" field (SSSOE)
   indicates that a reboot or similar loss of state has occurred,
   the client MUST first delay by a random amount of time selected
   with uniform random distribution in the range 0 to 5 seconds, and
   then send its first port mapping request. After that request is
   acknowledged by the gateway, the client may then send its second
   request, and so on, as rapidly as the gateway allows. The requests
   SHOULD be issued serially, one at a time; the client SHOULD NOT issue
   multiple requests simultaneously in parallel.

   The discussion in this section focusses on recreating inbound port
   mappings after loss of NAT gateway state, because that is the more
   serious problem. Losing port mappings for outgoing connections
   destroys those currently active connections, but does not prevent
   clients from establishing new outgoing connections. In contrast,
   losing inbound port mappings not only destroys all existing inbound
   connections, but also prevents the reception of any new inbound
   connections until the port mapping is recreated. Accordingly,
   we consider recovery of inbound port mappings the more important
   priority. However, clients that want outgoing connections to survive
   a NAT gateway reboot can also achieve that using NAT-PMP. After
   initiating an outbound TCP connection (which will cause the NAT


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   gateway to establish an implicit port mapping) the client should send
   the NAT gateway a port mapping request for the source port of its TCP
   connection, which will cause the NAT gateway to send a response
   giving the public port it allocated for that mapping. The client can
   then store this information, and use later to recreate the mapping
   if it determines that the NAT gateway has lost its mapping state.


3.8 NAT Gateways with NAT Function Disabled

   Note that *only* devices currently acting in the role of NAT gateway
   should participate in NAT-PMP protocol exchanges with clients.
   A network device that is capable of NAT (and NAT-PMP), but is
   currently configured not to perform that function, (e.g. it is
   acting as a traditional IP router, forwarding packets without
   modifying them), MUST NOT respond to NAT-PMP requests from clients,
   or send spontaneous NAT-PMP address-change announcements.

   In particular, a network device not currently acting in the role of
   NAT gateway should not even respond to NAT-PMP requests by returning
   an error code such as "2 - Not Authorized/Refused", since to do so
   is misleading to clients -- it suggests that NAT port mapping is
   necessary on this network for the client to successfully receive
   inbound connections, but is not available because the administrator
   has chosen to disable that functionality.

   Clients should also be careful to avoid making unfounded assumptions,
   such as the assumption that if the client has an IPv4 address in
   one of the RFC 1918 private IP address ranges then that means
   NAT necessarily must be in use. Net 10/8 has enough addresses
   to build a private network with millions of hosts and thousands
   of interconnected subnets, all without any use of NAT. Many
   organizations have built such private networks that benefit from
   using standard TCP/IP technology, but by choice do not connect
   to the public Internet. The purpose of NAT-PMP is to mitigate some
   of the damage caused by NAT. It would be an ironic and unwanted
   side-effect of this protocol if it were to lead well-meaning but
   misguided developers to create products that refuse to work on a
   private network *unless* they can find a NAT gateway to talk to.
   Consequently, a client finding that NAT-PMP is not available on its
   network should not give up, but should proceed on the assumption
   that the network may be a traditional routed IP network, with no
   address translation being used. This assumption may not always be
   true, but it is better than the alternative of falsely assuming
   the worst and not even trying to use normal (non-NAT) IP networking.

   If a network device not currently acting in the role of NAT gateway
   receives UDP packets addressed to port 5351, it SHOULD respond
   immediately with an "ICMP Port Unreachable" message to tell the
   client that it needn't continue with timeouts and retransmissions,
   and it should assume that NAT-PMP is not available and not needed
   on this network.

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4. UNSAF Considerations

   The document "IAB Considerations for UNSAF Across NAT" [RFC 3424]
   covers a number of issues when working with NATs. RFC 3424 outlines
   some requirements for any document that attempts to work around
   problems associated with NATs. This section addresses those
   requirements.


4.1 Scope

   This protocol addresses the needs of TCP and UDP transport peers that
   are separated from the public internet by exactly one NAT. Such
   peers must have access to some form of directory server for
   registering the public IP address and port at which they can be
   reached.


4.2 Transition Plan

   Any client making use of this protocol SHOULD implement IPv6 support.
   If a client supports IPv6 and is running on a device with a global
   IPv6 address, that IPv6 address SHOULD be preferred to the IPv4
   public address using this NAT mapping protocol. In case other
   clients do not have IPv6 connectivity, both the IPv4 and IPv6
   addresses SHOULD be registered with whatever form of directory server
   is used. Preference SHOULD be given to IPv6 addresses when
   available. By implementing support for IPv6 and using this protocol
   for IPv4, vendors can ship products today that will work under both
   scenarios. As IPv6 is more widely deployed, clients of this protocol
   following these recommendations will transparently make use of IPv6.


4.3 Failure Cases

   Aside from NATs that do not implement this protocol, there are a
   number of situations where this protocol may not work.


4.3.1 NAT Behind NAT

   Some people's primary IP address, assigned by their ISP, may itself
   be a NAT address. In addition, some people may have a public IP
   address, but may then double NAT themselves, perhaps by choice or
   perhaps by accident. Although it might be possible in principle for
   one NAT gateway to recursively request a mapping from the next one,
   this document does not advocate that and does not try to prescribe
   how it would be done.

   It would be a lot of work to implement nested NAT port mapping
   correctly, and there are a number of reasons why the end result might


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   not be as useful as we might hope. Consider the case of an ISP that
   offers each of its customers only a single NAT address. This ISP
   could instead have chosen to provide each customer with a single
   public IP address, or, if the ISP insists on running NAT, it could
   have chosen to allow each customer a reasonable number of addresses,
   enough for each customer device to have its own NAT address directly
   from the ISP. If instead this ISP chooses to allow each customer
   just one and only one NAT address, forcing said customer to run
   nested NAT in order to use more than one device, it seems unlikely
   that such an ISP would be so obliging as to provide a NAT service
   that supports NAT Port Mapping Protocol. Supposing that such an ISP
   did wish to offer its customers NAT service with NAT-PMP so as to
   give them the ability to receive inbound connections, this ISP could
   easily choose to allow each client to request a reasonable number of
   DHCP addresses from that gateway. Remember that Net 10/8 [RFC 1918]
   allows for over 16 million addresses, so NAT addresses are not in any
   way in short supply. A single NAT gateway with 16 million available
   addresses is likely to run out of packet forwarding capacity before
   it runs out of private addresses to hand out. In this way the ISP
   could offer single-level NAT with NAT-PMP, obviating the need to
   support nested NAT-PMP. In addition, an ISP that is motivated to
   provide their customers with unhindered access to the Internet by
   allowing incoming as well as outgoing connections has better ways
   to offer this service. Such an ISP could offer its customers real
   public IP addresses instead of NAT addresses, or could even choose
   to offer its customers full IPv6 connectivity, where no mapping or
   translation is required at all.


4.3.2 NATs with Multiple Public IP Addresses

   If a NAT maps private addresses to multiple public addresses,
   then it SHOULD pick one of those addresses as the one it will
   support for inbound connections, and for the purposes of this
   protocol it SHOULD act as if that address were its only address.


4.3.3 NATs and Routed Private Networks

   In some cases, a large network may be subnetted. Some sites
   may install a NAT gateway and subnet the private network.
   Such subnetting breaks this protocol because the router address
   is not necessarily the address of the device performing NAT.

   Addressing this problem is not a high priority. Any site with the
   resources to set up such a configuration should have the resources to
   add manual mappings or attain a range of globally unique addresses.

   Not all NATs will support this protocol. In the case where a client
   is run behind a NAT that does not support this protocol, the software
   relying on the functionality of this protocol may be unusable.


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4.3.4 Communication Between Hosts Behind the Same NAT

   NAT gateways supporting NAT-PMP should also implement "hairpin
   translation". Hairpin translation means supporting communication
   between two local clients being served by the same NAT gateway.

   Suppose device A is listening on private address and port 10.0.0.2:80
   for incoming connections. Using NAT-PMP, device A has obtained a
   mapping to public address and port x.x.x.x:80, and has recorded this
   public address and port in a public directory of some kind. For
   example, it could have created a DNS SRV record containing this
   information, and recorded it, using DNS Dynamic Update [RFC 3007], in
   a publicly accessible DNS server. Suppose then that device B, behind
   the same NAT gateway as device A, but unknowing or uncaring of this
   fact, retrieves device A's DNS SRV record and attempts to open a TCP
   connection to x.x.x.x:80. The outgoing packets addressed to this
   public Internet address will be sent to the NAT gateway for
   translation and forwarding. Having translated the source address and
   port number on the outgoing packet, the NAT gateway needs to be smart
   enough to recognize that the destination address is in fact itself,
   and then feed this packet back into its packet reception engine, to
   perform the destination port mapping lookup to translate and forward
   this packet to device A at address and port 10.0.0.2:80.

4.3.5 Non UDP/TCP Transport Traffic

   Any communication over transport protocols other than TCP and UDP
   will not be served by this protocol. Examples are Generic Routing
   Encapsulation (GRE), Authentication Header (AH) and Encapsulating
   Security Payload (ESP).

4.4 Long Term Solution

   As IPv6 is deployed, clients of this protocol supporting IPv6 will be
   able to bypass this protocol and the NAT when communicating with
   other IPv6 devices. In order to ensure this transition, any client
   implementing this protocol SHOULD also implement IPv6 and use this
   solution only when IPv6 is not available to both peers.

4.5 Existing Deployed NATs

   Existing deployed NATs will not support this protocol. This protocol
   will only work with NATs that are upgraded to support it.










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5. Security Considerations

   As discussed in section 3.2 "Determining the Public Address", only
   clients on the private side of the NAT may create port mappings, and
   only on behalf of themselves. By using IP address spoofing, it's
   possible for one client to delete the port mappings of another
   client. It's also possible for one client to create port mappings on
   behalf of another client. The best way to deal with this
   vulnerability is to use IPSec [RFC 2401].

   Since allowing incoming connections is often a policy decision, any
   NAT gateway implementing this protocol SHOULD have an administrative
   mechanism to disable it.

   Some people view the property that NATs block inbound connections as
   a security benefit which is undermined by this protocol. The authors
   of this document have a different point of view. In the days before
   NAT, all hosts had unique public IP addresses, and had unhindered
   ability to communicate with any other host on the Internet. When NAT
   came along it broke this unhindered connectivity, relegating many
   hosts to second-class status, unable to receive inbound connections.
   This protocol goes some way to undo some of that damage. The purpose
   of a NAT gateway should be to allow several hosts to share a single
   address, not to simultaneously impede those host's ability to
   communicate freely. Security is most properly provided by end-to-end
   cryptographic security, and/or by explicit firewall functionality, as
   appropriate. Blocking of certain connections should occur only as a
   result of explicit and intentional firewall policy, not as an
   accidental side-effect of some other technology.


6. IANA Considerations

   No IANA services are required by this document.


7. Acknowledgments

   The concepts described in this document have been explored, developed
   and implemented with help from Bob Bradley, Josh Graessley, Rob
   Newberry, Roger Pantos, John Saxton, and James Woodyatt.


8. Deployment History

   NAT-PMP client software first became available to the public
   through Apple's Darwin Open Source code in August 2004.
   NAT-PMP implementations began shipping to end users in large
   volumes (i.e. millions) with the launch of Mac OS X 10.4 Tiger
   and Bonjour for Windows 1.0 in April 2005.



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   The NAT-PMP client in Mac OS X 10.4 Tiger and Bonjour for Windows
   exists as part of the mDNSResponder system service. When a client
   advertises a service using Wide Area Bonjour [DNS-SD], and the
   machine is behind a NAT-PMP-capable NAT gateway, then if the machine
   is so configured, the mDNSResponder system service automatically uses
   NAT-PMP to set up an inbound port mapping, and then records the
   public IP address and port in the global DNS. Existing client
   software using the existing Bonjour programming APIs [Bonjour]
   gets this functionality automatically. The logic is that if client
   software publishes its information into the global DNS via Wide Area
   Bonjour service advertising, then it's reasonable to infer an
   expectation that this information should be usable by the peers
   retrieving it. Generally speaking, recording a private IP address
   like 10.0.0.2 in the public DNS is completely pointless because that
   address is not reachable from clients on the other side of the NAT
   gateway. In the case of a home user with a single computer directly
   connected to their Cable or DSL modem, with a single global IPv4
   address and no NAT gateway (a surprisingly common configuration),
   publishing that IP address into the global DNS is useful because that
   IP address is reachable. In contrast, a home user using a NAT gateway
   to share a single global IPv4 address between several computers loses
   this ability to receive inbound connections easily. This breaks many
   peer-to-peer collaborative applications, like the multi-user text
   editor SubEthaEdit [SEE]. Automatically creating the necessary
   inbound port mappings helps remedy this unintended side-effect of
   NAT.

   The server side of the NAT-PMP protocol is implemented in Apple's
   "AirPort Extreme" and "AirPort Express" wireless base stations.


9. Copyright Notice

   Copyright (C) The Internet Society (2006).

   This document is subject to the rights, licenses and restrictions
   contained in BCP 78, and except as set forth therein, the authors
   retain all their rights. For the purposes of this document,
   the term "BCP 78" refers exclusively to RFC 3978, "IETF Rights
   in Contributions", published March 2005.

   This document and the information contained herein are provided on
   an "AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE
   REPRESENTS OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY AND THE
   INTERNET ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES, EXPRESS OR
   IMPLIED, INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF
   THE INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED
   WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.





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10. Normative References

   [RFC 1918] Y. Rekhter et.al., "Address Allocation for Private
              Internets", RFC 1918, February 1996.

   [RFC 2119] RFC 2119 - Key words for use in RFCs to Indicate
              Requirement Levels


11. Informative References

   [Bonjour]  Apple "Bonjour" <http://developer.apple.com/bonjour/>

   [ETEAISD]  J. Saltzer, D. Reed and D. Clark: "End-to-end arguments in
              system design", ACM Trans. Comp. Sys., 2(4):277-88, Nov.
              1984

   [DNS-SD]   Cheshire, S., and M. Krochmal, "DNS-Based Service
              Discovery", Internet-Draft (work in progress),
              draft-cheshire-dnsext-dns-sd-04.txt, August 2006.

   [mDNS]     Cheshire, S., and M. Krochmal, "Multicast DNS",
              Internet-Draft (work in progress),
              draft-cheshire-dnsext-multicastdns-06.txt, August 2006.

   [RFC 2131] R. Droms, "Dynamic Host Configuration Protocol", RFC 2131,
              March 1997.

   [RFC 2401] Atkinson, R. and S. Kent, "Security Architecture for the
              Internet Protocol", RFC 2401, November 1998.

   [RFC 2663] Srisuresh, P. and M. Holdrege, "IP Network Address
              Translator (NAT) Terminology and Considerations", RFC
              2663, August 1999.

   [RFC 3007] Wellington, B., "Simple Secure Domain Name System
              (DNS) Dynamic Update", RFC 3007, November 2000.

   [SEE]      <http://www.codingmonkeys.de/subethaedit/>

   [RFC 3022] RFC 3022 - Network Address Translator

   [RFC 3424] RFC 3424 - IAB Considerations for UNilateral Self-Address
              Fixing (UNSAF) Across Network Address Translation









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12. Authors' Addresses

   Stuart Cheshire
   Apple Computer, Inc.
   1 Infinite Loop
   Cupertino
   California 95014
   USA

   Phone: +1 408 974 3207
   EMail: rfc [at] stuartcheshire [dot] org


   Marc Krochmal
   Apple Computer, Inc.
   1 Infinite Loop
   Cupertino
   California 95014
   USA

   Phone: +1 408 974 4368
   EMail: marc [at] apple [dot] com


   Kiren Sekar
   Sharpcast, Inc.
   250 Cambridge Ave, Suite 101
   Palo Alto
   California 94306
   USA

   Phone: +1 650 323 1960
   EMail: ksekar [at] sharpcast [dot] com




















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