TOC 
behaveX. Li, Ed.
Internet-DraftC. Bao, Ed.
Intended status: InformationalCERNET Center/Tsinghua University
Expires: April 29, 2009F. Baker, Ed.
 Cisco Systems
 October 26, 2008


IP/ICMP Translation Algorithm
draft-baker-behave-v4v6-translation-00

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.

Internet-Drafts are working documents of the Internet Engineering Task Force (IETF), its areas, and its working groups. Note that other groups may also distribute working documents as Internet-Drafts.

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This Internet-Draft will expire on April 29, 2009.

Abstract

This document specifies an update to the Stateless IP/ICMP Translation Algorithm (SIIT) described in RFC 2765. The algorithm translates between IPv4 and IPv6 packet headers (including ICMP headers).

This specification addresses both a stateful and a stateless mode. In the stateful mode, translation state is maintained between IPv4 address/transport/port tuples and IPv6 address/transport/port tuples, enabling IPv6 systems to open sessions with IPv4 systems. In the stateless mode, translation information is carried in the address itself, permitting both IPv4->IPv6 and IPv6->IPv4 session establishment with neither state nor configuration in the translator. The choice of operational mode is made by the operator deploying the network and is critical to the operation of the applications using it.

Significant issues exist in the stateful mode that are not addressed in this document, related to the maintenance of the translation tables. This document confines itself to the actual translation.

Acknowledgement of previous work

This document is a product of the 2008-2009 effort to define a replacement for NAT-PT. It is an update to and directly derivative from Erik Nordmark's [RFC2765] (Nordmark, E., “Stateless IP/ICMP Translation Algorithm (SIIT),” February 2000.), which similarly provides both stateless and stateful translation between IPv4 (Postel, J., “Internet Protocol,” September 1981.) [RFC0791] and IPv6 (Deering, S. and R. Hinden, “Internet Protocol, Version 6 (IPv6) Specification,” December 1998.) [RFC2460], and between ICMPv4 (Postel, J., “Internet Control Message Protocol,” September 1981.) [RFC0792] and ICMPv6 (Conta, A., Deering, S., and M. Gupta, “Internet Control Message Protocol (ICMPv6) for the Internet Protocol Version 6 (IPv6) Specification,” March 2006.) [RFC4443]. The original document was a product of the NGTRANS working group. Some text had been extracted from an old Internet Draft titled "IPAE: The SIPP Interoperability and Transition Mechanism" authored by R. Gilligan, E. Nordmark, and B. Hinden.

The changes in this document reflect five components:

  1. Updating references
  2. Redescribing the network model to map to present and projected usage
  3. Moving the address format to the framework document, to coordinate with other drafts on the topic
  4. Some changes in ICMP.
  5. Description of both stateful and stateless operation.


Table of Contents

1.  Introduction and Motivation
    1.1.  Applicability and Limitations
    1.2.  Assumptions
    1.3.  Stateless vs Stateful Mode
    1.4.  Impact Outside the Network Layer
2.  Terminology
3.  Requirements
4.  Translating from IPv4 to IPv6
    4.1.  Translating IPv4 Headers into IPv6 Headers
    4.2.  Translating UDP over IPv4
    4.3.  Translating ICMPv4 Headers into ICMPv6 Headers
    4.4.  Translating ICMPv4 Error Messages into ICMPv6
    4.5.  Knowing when to Translate
5.  Translating from IPv6 to IPv4
    5.1.  Translating IPv6 Headers into IPv4 Headers
    5.2.  Translating ICMPv6 Headers into ICMPv4 Headers
    5.3.  Translating ICMPv6 Error Messages into ICMPv4
    5.4.  Knowing when to Translate
6.  Implications for IPv6-Only Nodes
7.  IANA Considerations
8.  Security Considerations
9.  Acknowledgements
10.  References
    10.1.  Normative References
    10.2.  Informative References
§  Authors' Addresses
§  Intellectual Property and Copyright Statements




 TOC 

1.  Introduction and Motivation

An understanding of the framework presented in [FRAMEWORK] (Baker, F., “Framework for IPv4/IPv6 Translation - baker-behave-v4v6-framework,” October 2008.) is presumed in this document. With that remark...

The transition mechanisms specified in [RFC4213] (Nordmark, E. and R. Gilligan, “Basic Transition Mechanisms for IPv6 Hosts and Routers,” October 2005.) handle the case of dual IPv4/IPv6 hosts interoperating with both dual hosts and IPv4-only hosts, which is needed early in the transition to IPv6. The dual hosts are assigned both an IPv4 and one or more IPv6 addresses. The number of available globally unique IPv4 addresses will become smaller and smaller as the Internet grows; we expect that there will be a desire to take advantage of the large IPv6 address and not require that every new Internet node have a permanently assigned IPv4 address.

There are several different scenarios where there might be IPv6-only hosts that need to communicate with IPv4-only hosts. These IPv6 hosts might be IPv4-capable, i.e. include an IPv4 implementation but not be assigned an IPv4 address, or they might not even include an IPv4 implementation. Examples include:

However, there are other potential solutions in this area:

This document specifies an algorithm that is one of the components needed to make IPv6-only nodes interoperate with IPv4-only nodes.

The IPv4 address will be used as an IPv4-translated IPv6 address as specified in [FRAMEWORK] (Baker, F., “Framework for IPv4/IPv6 Translation - baker-behave-v4v6-framework,” October 2008.) and the packets will travel through an IP/ICMP translator that will translate the packet headers between IPv4 and IPv6 and translate the addresses in those headers between IPv4 addresses on one side and IPv4-translated or IPv4-mapped IPv6 addresses on the other side. There is provision for both stateless and stateful mappings. Translated IPv4 addresses will always use the mapped format; the source address of an IPv6 datagram translated from IPv4 will always use the mapped form. The use of the mapped form in the IPv6 network is, however, at the administration's discretion. Three obvious models emerge:

This specification does not cover the mechanisms used for assignment of IPv4-mapped addresses to IPv6 nodes or their registration in the DNS. One might expect IPv4-mapped addresses to be allocated by mechanisms similar to and derived from similar tools in IPv4 networks.

The figures below show how the IP/ICMP Translation algorithm is used in networks that use translation. We show three cases, that of a single translator, that of multiple translators, and that of a domain that has both stateless and stateful translation.



     --------          --------
   //  IPv4  \\      //  IPv6  \\
  /   Domain   \    /   Domain   \
 /             +----+      +--+   \
|              |XLAT|      |S2|    |  Sn: Servers
| +--+         +----+      +--+    |  Hn: Clients
| |S1|         +----+              |
| +--+         |DNS |      +--+    |  XLAT: V4/V6 NAT
 \     +--+    +----+      |H2|   /   DNS:  DNS Server
  \    |H1|    /    \      +--+  /
   \\  +--+  //      \\        //
     --------          --------
 Figure 1: Using translation for a single interchange point 

Figure 1 (Using translation for a single interchange point) shows a routing domain in which IPv4 is implemented (whether IPv4-only or dual stack) and another domain in which only IPv6 routing, and potentially only IPv6-only hosts, are implemented. There is a translator on the boundary between them, and a DNS server that can serve on both sides of the translator. The translator advertises an IPv4 route for the prefix mapped into IPv6 addresses in the IPv4 domain, and an IPv6 route for its prefix mapping the IPv4 routing domain into the IPv6 domain.

By extension, one could imagine a case in which S2 has an IPv4-mapped address and H2 has a general IPv6 address - any legal IPv6 address other than one that the translator recognizes as an IPv4-mapped address. In this case, should S2 (an IPv6 device using an IPv4-mapped address) access an IPv4 system, the behavior is as previously described. However, should H2 seek to access S1, the behavior is similar to the familiar IPv4 NAT; the translator saves H2's address and source port number and an overlay IPv4 address and source port number in a database, and

A stateful mapping of this kind requires appropriate handling of port numbers and checksums, and of creation and deletion of state, as described in [I‑D.bagnulo‑behave‑nat64] (Bagnulo, M., Matthews, P., and I. Beijnum, “NAT64: Network Address and Protocol Translation from IPv6 Clients to IPv4 Servers,” March 2009.).



     --------          --------
   //  IPv4  \\      //  IPv6  \\
  /   Domain   \    /   Domain   \
 /             +----+      +--+   \
|              |XLAT|      |S3|    |  Sn: Servers
| +--+         +----+      +--+    |  Hn: Clients
| |S1|         +----+              |
| +--+         |DNS |      +--+    |  XLAT: V4/V6 NAT
 \     +--+    +----+      |H3|   /   DNS:  DNS Server
  \    |H1|    /    \      +--+  /
   \   +--+   /      \          /
  /            \    /            \
 /             +----+             \
| +--+         |XLAT|     +--+     |
| |S2|         +----+     |S4|     |
| +--+         +----+     +--+     |
|      +--+    |DNS |       +--+   |
 \     |H2|    +----+       |H4|  /
  \    +--+    /    \       +--+ /
   \\        //      \\        //
     --------          --------

 Figure 2: Using translation with multiple interchange points 

Figure 2 (Using translation with multiple interchange points) similarly shows a routing domain in which IPv4 is implemented (whether IPv4-only or dual stack) and another domain in which only IPv6 routing, and potentially only IPv6-only hosts, are implemented. The difference from Figure 1 (Using translation for a single interchange point) is that there are more than one translation point on the boundary between them, and more than one DNS server. As in the previous case, each translator advertises an IPv4 route for the prefix mapped into IPv6 addresses in the IPv4 domain, and an IPv6 route for its prefix mapping the IPv4 routing domain into the IPv6 domain. If these are run by the same administration, they are likely to use the same prefix. They could also use different prefixes at the network administration's option, and if they have different administrations they likely would - and might apply various policies to such routing.

In both cases, if the "IPv4 network" is in fact dual stack and contains dual stack hosts, direct IPv6 connectivity is precisely that - direct. There is no translation even if the addresses used are mapped IPv4 addresses, because the routing is provided by more specific prefixes; the only datagrams translated are those that follow the more general route to the translator.

The protocol translators are assumed to fit around some piece of topology that includes some IPv6-only nodes and that may also include IPv4 nodes as well as dual nodes. There has to be a translator on each path used by routing the "translatable" packets in and out of this cloud to ensure that such packets always get translated. This does not require a translator at every physical connection between the cloud and the rest of the Internet since the routing can be used to deliver the packets to the translator.

The IPv6-only node communicating with an IPv4 node through a translator will see an IPv4-mapped address for the peer and use an IPv4-translatable address for its local address for that communication. When the IPv6-only node sends packets the IPv4-mapped address indicates that the translator needs to translate the packets. When the IPv4 node sends packets those will translated to have the IPv4-translatable address as a destination; it is not possible to use an IPv4-mapped or an IPv4-compatible address as a destination since that would either route the packet back to the translator (for the IPv4-mapped address) or make the packet be encapsulated in IPv4 (for the IPv4-compatible address). Thus this specification introduces the new notion of an IPv4-translatable address.



 TOC 

1.1.  Applicability and Limitations

The use of this translation algorithm assumes that the IPv6 network is somehow well connected i.e. when an IPv6 node wants to communicate with another IPv6 node there is an IPv6 path between them. Various tunneling schemes exist that can provide such a path, but those mechanisms and their use is outside the scope of this document.

The translating function as specified in this document does not translate any IPv4 options and it does not translate IPv6 routing headers, hop-by-hop extension headers, or destination options headers. It could be possible to define a translation between source routing in IPv4 and IPv6. However such a translation would not be semantically correct due to the slight differences between the IPv4 and IPv6 source routing. Also, the usefulness of source routing when going through a header translator might be limited since all the IPv6-only routers would need to have an IPv4-translated IPv6 address since the IPv4-only node will send a source route option containing only IPv4 addresses.

[RFC5382] (Guha, S., Biswas, K., Ford, B., Sivakumar, S., and P. Srisuresh, “NAT Behavioral Requirements for TCP,” October 2008.) describes the issues and algorithms in the translation of datagrams containing TCP segments. The considerations of that document are applicable in this case as well.

At first sight it might appear that the IPsec functionality [RFC4301] (Kent, S. and K. Seo, “Security Architecture for the Internet Protocol,” December 2005.)[RFC4302] (Kent, S., “IP Authentication Header,” December 2005.)[RFC4303] (Kent, S., “IP Encapsulating Security Payload (ESP),” December 2005.) can not be carried across the translator. However, since the translator does not modify any headers above the logical IP layer (IP headers, IPv6 fragment headers, and ICMP messages) packets encrypted using ESP in Transport-mode can be carried through the translator. [Note that this assumes that the key management can operate between the IPv6-only node and the IPv4-only node.] The AH computation covers parts of the IPv4 header fields such as IP addresses, and the identification field (fields that are either immutable or predictable by the sender) [RFC4302] (Kent, S., “IP Authentication Header,” December 2005.). While the translation algorithm is specified so that those IPv4 fields can be predicted by the IPv6 sender it is not possible for the IPv6 receiver to determine the value of the IPv4 Identification field in packets sent by the IPv4 node. Thus as the translation algorithm is specified in this document it is not possible to use end-to-end AH through the translator.

For ESP Tunnel-mode to work through the translator the IPv6 node would have to be able to both parse and generate "inner" IPv4 headers since the inner IP will be encrypted together with the transport protocol.

Thus in practise, only ESP transport mode is relatively easy to make work through a translator, unless an ESP tunnel is explicitly carrying IPv4 inner and IPv6 outer headers.

IPv4 multicast addresses can not be mapped to IPv6 multicast addresses. For instance, 224.1.2.3 is an IPv4 multicast address, but an IPv6 address mapped to general IPv4 addresses and containing that value is not an IPv6 multicast address. While the IP/ICMP header translation aspect of this memo in theory works for multicast packets this address mapping limitation makes it impossible to apply the techniques in this memo for multicast traffic.



 TOC 

1.2.  Assumptions

The IPv6 nodes using the translator must have an IPv4-translated IPv6 address while it is communicating with IPv4-only nodes.

Fragmented IPv4 UDP packets that do not contain a UDP checksum (i.e. the UDP checksum field is zero) are not of significant use over wide-areas in the Internet and will not be translated by the translator. An informal trace (Miller, G., “Email to the ngtrans mailing list,” March 1999.) [Miller] in the backbone showed that out of 34,984,468 IP packets there were 769 fragmented UDP packets with a zero checksum. However, all of them were due to malicious or broken behavior; a port scan and first fragments of IP packets that are not a multiple of 8 bytes.



 TOC 

1.3.  Stateless vs Stateful Mode

The translator has two possible modes of operation: stateless and stateful. In both cases, we assume that a system that has an IPv4 address but not an IPv6 address is communicating with a system that has an IPv6 address but no IPv4 address, or that the two systems do not have contiguous routing connectivity in either domain and hence are forced to have their communications translated.

In the stateless mode, one system has an IPv4 address and one has an address of the form specified in [FRAMEWORK] (Baker, F., “Framework for IPv4/IPv6 Translation - baker-behave-v4v6-framework,” October 2008.), which is explicitly mapped to an IPv4 address. In this mode, there is no need to concern oneself with port translation or translation tables, as the IPv4 and IPv6 counterparts are algorithmically related.

In the stateful mode, the system with the IPv4 address will be represented by that same address type, but the IPv6 system may use any [RFC4291] (Hinden, R. and S. Deering, “IP Version 6 Addressing Architecture,” February 2006.) address except one in that range. In this case, a translation table is required.



 TOC 

1.4.  Impact Outside the Network Layer

The potential existence of IP/ICMP translators is already taken care of from a protocol perspective in [RFC2460] (Deering, S. and R. Hinden, “Internet Protocol, Version 6 (IPv6) Specification,” December 1998.). However, an IPv6 node that wants to be able to use translators needs some additional logic in the network layer.

The network layer in an IPv6-only node, when presented by the application with either an IPv4 destination address or an IPv4-mapped IPv6 destination address, is likely to drop the packet and return some error message to the application. In order to take advantage of translators such a node should instead send an IPv6 packet where the destination address is the IPv4-mapped address and the source address is the node's temporarily assigned IPv4-translated address. If the node does not have a temporarily assigned IPv4-translated address it should acquire one using mechanisms that are not discussed in this document.

Note that the above also applies to a dual IPv4/IPv6 implementation node which is not configured with any IPv4 address.

There are no extra changes needed to applications to operate through a translator beyond what applications already need to do to operate on a dual node. The applications that have been modified to work on a dual node already have the mechanisms to determine whether they are communicating with an IPv4 or an IPv6 peer. Thus if the applications need to modify their behavior depending on the type of the peer, such as ftp determining whether to fallback to using the PORT/PASV command when EPRT/EPSV fails (as specified in [RFC2428] (Allman, M., Ostermann, S., and C. Metz, “FTP Extensions for IPv6 and NATs,” September 1998.)), they already need to do that when running on dual nodes and the presence of translators does not add anything. For example, when using the socket API [RFC3493] (Gilligan, R., Thomson, S., Bound, J., McCann, J., and W. Stevens, “Basic Socket Interface Extensions for IPv6,” February 2003.) the applications know that the peer is IPv6 if they get an AF_INET6 address from the name service and the address is not an IPv4-mapped address (i.e., IN6_IS_ADDR_V4MAPPED returns false). If this is not the case, i.e., the address is AF_INET or an IPv4-mapped IPv6 address, the peer is IPv4.

One way of viewing the translator, which might help clarify why applications do not need to know that a translator is used, is to look at the information that is passed from the transport layer to the network layer. If the transport passes down an IPv4 address (whether or not is in the IPv4-mapped encoding) this means that at some point there will be IPv4 packets generated. In a dual node the generation of the IPv4 packets takes place in the sending node. In an IPv6-only node conceptually the only difference is that the IPv4 packet is generated by the translator - all the information that the transport layer passed to the network layer will be conveyed to the translator in some form. That form just "happens" to be in the form of an IPv6 header.



 TOC 

2.  Terminology

This documents uses the terminology defined in [RFC2460] (Deering, S. and R. Hinden, “Internet Protocol, Version 6 (IPv6) Specification,” December 1998.) and [RFC4213] (Nordmark, E. and R. Gilligan, “Basic Transition Mechanisms for IPv6 Hosts and Routers,” October 2005.) with these clarifications:

IPv4 capable node:
A node which has an IPv4 protocol stack. In order for the stack to be usable the node must be assigned one or more IPv4 addresses.
IPv4 enabled node:
A node which has an IPv4 protocol stack and is assigned one or more IPv4 addresses. Both IPv4-only and IPv6/IPv4 nodes are IPv4 enabled.
IPv6 capable node:
A node which has an IPv6 protocol stack. In order for the stack to be usable the node must be assigned one or more IPv6 addresses.
IPv6 enabled node:
A node which has an IPv6 protocol stack and is assigned one or more IPv6 addresses. Both IPv6-only and IPv6/IPv4 nodes are IPv6 enabled.


 TOC 

3.  Requirements

The keywords MUST, MUST NOT, REQUIRED, SHALL, SHALL NOT, SHOULD, SHOULD NOT, RECOMMENDED, MAY, and OPTIONAL, when they appear in this document, are to be interpreted as described in [RFC2119] (Bradner, S., “Key words for use in RFCs to Indicate Requirement Levels,” March 1997.).



 TOC 

4.  Translating from IPv4 to IPv6

When an IPv4-to-IPv6 translator receives an IPv4 datagram addressed to a destination that lies outside of the attached IPv4 island, it translates the IPv4 header of that packet into an IPv6 header. It then forwards the packet based on the IPv6 destination address. The original IPv4 header on the packet is removed and replaced by an IPv6 header. Except for ICMP packets the transport layer header and data portion of the packet are left unchanged.




+-------------+                 +-------------+
|    IPv4     |                 |    IPv6     |
|   Header    |                 |   Header    |
+-------------+                 +-------------+
|  Transport  |                 |  Fragment   |
|   Layer     |      ===>       |   Header    |
|   Header    |                 |(not always) |
+-------------+                 +-------------+
|             |                 |  Transport  |
~    Data     ~                 |   Layer     |
|             |                 |   Header    |
+-------------+                 +-------------+
                                |             |
                                ~    Data     ~
                                |             |
                                +-------------+

 Figure 3: IPv4-to-IPv6 Translation 

One of the differences between IPv4 and IPv6 is that in IPv6 path MTU discovery is mandatory but it is optional in IPv4. This implies that IPv6 routers will never fragment a packet - only the sender can do fragmentation.

When the IPv4 node performs path MTU discovery (by setting the DF bit in the header) the path MTU discovery can operate end-to-end i.e. across the translator. In this case either IPv4 or IPv6 routers might send back ICMP "packet too big" messages to the sender. When these ICMP errors are sent by the IPv6 routers they will pass through a translator which will translate the ICMP error to a form that the IPv4 sender can understand. In this case an IPv6 fragment header is only included if the IPv4 packet is already fragmented.

However, when the IPv4 sender does not perform path MTU discovery the translator has to ensure that the packet does not exceed the path MTU on the IPv6 side. This is done by fragmenting the IPv4 packet so that it fits in 1280 byte IPv6 packet since IPv6 guarantees that 1280 byte packets never need to be fragmented. Also, when the IPv4 sender does not perform path MTU discovery the translator MUST always include an IPv6 fragment header to indicate that the sender allows fragmentation. That is needed should the packet pass through an IPv6-to-IPv4 translator.

The above rules ensure that when packets are fragmented either by the sender or by IPv4 routers that the low-order 16 bits of the fragment identification is carried end-end to ensure that packets are correctly reassembled. In addition, the rules use the presence of an IPv6 fragment header to indicate that the sender might not be using path MTU discovery i.e. the packet should not have the DF flag set should it later be translated back to IPv4.

Other than the special rules for handling fragments and path MTU discovery the actual translation of the packet header consists of a simple mapping as defined below. Note that ICMP packets require special handling in order to translate the content of ICMP error message and also to add the ICMP pseudo-header checksum.



 TOC 

4.1.  Translating IPv4 Headers into IPv6 Headers

If the DF flag is not set and the IPv4 packet will result in an IPv6 packet larger than 1280 bytes the IPv4 packet MUST be fragmented prior to translating it. Since IPv4 packets with DF not set will always result in a fragment header being added to the packet the IPv4 packets must be fragmented so that their length, excluding the IPv4 header, is at most 1232 bytes (1280 minus 40 for the IPv6 header and 8 for the Fragment header). The resulting fragments are then translated independently using the logic described below.

If the DF bit is set and the packet is not a fragment (i.e., the MF flag is not set and the Fragment Offset is zero) then there is no need to add a fragment header to the packet. The IPv6 header fields are set as follows:

Version:
6
Traffic Class:
By default, copied from IP Type Of Service and Precedence field (all 8 bits are copied). According to [RFC2474] (Nichols, K., Blake, S., Baker, F., and D. Black, “Definition of the Differentiated Services Field (DS Field) in the IPv4 and IPv6 Headers,” December 1998.) the semantics of the bits are identical in IPv4 and IPv6. However, in some IPv4 environments these fields might be used with the old semantics of "Type Of Service and Precedence". An implementation of a translator SHOULD provide the ability to ignore the IPv4 "TOS" and always set the IPv6 traffic class to zero.
Flow Label:
0 (all zero bits)
Payload Length:
Total length value from IPv4 header, minus the size of the IPv4 header and IPv4 options, if present.
Next Header:
Protocol field copied from IPv4 header
Hop Limit:
TTL value copied from IPv4 header. Since the translator is a router, as part of forwarding the packet it needs to decrement either the IPv4 TTL (before the translation) or the IPv6 Hop Limit (after the translation). As part of decrementing the TTL or Hop Limit the translator (as any router) needs to check for zero and send the ICMPv4 or ICMPv6 "ttl exceeded" error.
Source Address:
The the address is derived from the IPv4 address as specified in [FRAMEWORK] (Baker, F., “Framework for IPv4/IPv6 Translation - baker-behave-v4v6-framework,” October 2008.).
Destination Address:
In stateless mode, which is to say that if the IPv4 destination address is within the range of the stateless translation prefix described in Section 1.3 (Stateless vs Stateful Mode), the address is derived from the IPv4 address as specified in [FRAMEWORK] (Baker, F., “Framework for IPv4/IPv6 Translation - baker-behave-v4v6-framework,” October 2008.).
In stateful mode, which is to say that if the IPv4 destination address is among the statefully-translated addresses, the IPv6 address and transport layer destination port corresponding to the IPv4 destination address and source port are derived from the database reflecting current session state in the translator.

If IPv4 options are present in the IPv4 packet, they are ignored i.e., there is no attempt to translate them. However, if an unexpired source route option is present then the packet MUST instead be discarded, and an ICMPv4 "destination unreachable/source route failed" (Type 3/Code 5) error message SHOULD be returned to the sender.

If there is need to add a fragment header (the DF bit is not set or the packet is a fragment) the header fields are set as above with the following exceptions:

IPv6 fields:
Payload Length:
Total length value from IPv4 header, plus 8 for the fragment header, minus the size of the IPv4 header and IPv4 options, if present.
Next Header:
Fragment Header (44).
Fragment header fields:
Next Header:
Protocol field copied from IPv4 header.
Fragment Offset:
Fragment Offset copied from the IPv4 header.
M flag
More Fragments bit copied from the IPv4 header.
Identification
The low-order 16 bits copied from the Identification field in the IPv4 header. The high-order 16 bits set to zero.


 TOC 

4.2.  Translating UDP over IPv4

If a UDP packet has a zero UDP checksum then a valid checksum must be calculated in order to translate the packet. A stateless translator can not do this for fragmented packets but [MILLER] indicates that fragmented UDP packets with a zero checksum appear to only be used for malicious purposes. Thus this is not believed to be a noticeable limitation.

When a translator receives the first fragment of a fragmented UDP IPv4 packet and the checksum field is zero the translator SHOULD drop the packet and generate a system management event specifying at least the IP addresses and port numbers in the packet. When it receives fragments other than the first it SHOULD silently drop the packet, since there is no port information to log.

When a translator receives an unfragmented UDP IPv4 packet and the checksum field is zero the translator MUST compute the missing UDP checksum as part of translating the packet. Also, the translator SHOULD maintain a counter of how many UDP checksums are generated in this manner.



 TOC 

4.3.  Translating ICMPv4 Headers into ICMPv6 Headers

All ICMP messages that are to be translated require that the ICMP checksum field be updated as part of the translation since ICMPv6 unlike ICMPv4 has a pseudo-header checksum just like UDP and TCP.

In addition all ICMP packets need to have the Type value translated and for ICMP error messages the included IP header also needs translation.

The actions needed to translate various ICMPv4 messages are:

ICMPv4 query messages:
Echo and Echo Reply (Type 8 and Type 0)
Adjust the type to 128 and 129, respectively, and adjust the ICMP checksum both to take the type change into account and to include the ICMPv6 pseudo-header.
Information Request/Reply (Type 15 and Type 16)
Obsoleted in ICMPv4 Silently drop.
Timestamp and Timestamp Reply (Type 13 and Type 14)
Obsoleted in ICMPv6 Silently drop.
Address Mask Request/Reply (Type 17 and Type 18)
Obsoleted in ICMPv6 Silently drop.
ICMP Router Advertisement (Type 9)
Single hop message. Silently drop.
ICMP Router Solicitation (Type 10)
Single hop message. Silently drop.
Unknown ICMPv4 types
Silently drop.
IGMP messages:
While the MLD messages [RFC2710] (Deering, S., Fenner, W., and B. Haberman, “Multicast Listener Discovery (MLD) for IPv6,” October 1999.)[RFC3590] (Haberman, B., “Source Address Selection for the Multicast Listener Discovery (MLD) Protocol,” September 2003.)[RFC3810] (Vida, R. and L. Costa, “Multicast Listener Discovery Version 2 (MLDv2) for IPv6,” June 2004.) are the logical IPv6 counterparts for the IPv4 IGMP messages all the "normal" IGMP messages are single-hop messages and should be silently dropped by the translator. Other IGMP messages might be used by multicast routing protocols and, since it would be a configuration error to try to have router adjacencies across IPv4/IPv6 translators those packets should also be silently dropped.
ICMPv4 error messages:
Destination Unreachable (Type 3)
For all that are not explicitly listed below set the Type to 1.
Translate the code field as follows:
Code 0, 1 (net, host unreachable):
Set Code to 0 (no route to destination).
Code 2 (protocol unreachable):
Translate to an ICMPv6 Parameter Problem (Type 4, Code 1) and make the Pointer point to the IPv6 Next Header field.
Code 3 (port unreachable):
Set Code to 4 (port unreachable).
Code 4 (fragmentation needed and DF set):
Translate to an ICMPv6 Packet Too Big message (Type 2) with code 0. The MTU field needs to be adjusted for the difference between the IPv4 and IPv6 header sizes. Note that if the IPv4 router did not set the MTU field i.e. the router does not implement [RFC1191] (Mogul, J. and S. Deering, “Path MTU discovery,” November 1990.), then the translator must use the plateau values specified in [RFC1191] (Mogul, J. and S. Deering, “Path MTU discovery,” November 1990.) to determine a likely path MTU and include that path MTU in the ICMPv6 packet. (Use the greatest plateau value that is less than the returned Total Length field.)
Code 5 (source route failed):
Set Code to 0 (no route to destination). Note that this error is unlikely since source routes are not translated.
Code 6,7:
Set Code to 0 (no route to destination).
Code 8:
Set Code to 0 (no route to destination).
Code 9, 10 (communication with destination host administratively prohibited):
Set Code to 1 (communication with destination administratively prohibited)
Code 11, 12:
Set Code to 0 (no route to destination).
Redirect (Type 5)
Single hop message. Silently drop.
Source Quench (Type 4)
Obsoleted in ICMPv6 Silently drop.
Time Exceeded (Type 11)
Set the Type field to 3. The Code field is unchanged.
Parameter Problem (Type 12)
Set the Type field to 4. The Pointer needs to be updated to point to the corresponding field in the translated include IP header.


 TOC 

4.4.  Translating ICMPv4 Error Messages into ICMPv6

There are some differences between the IPv4 and the IPv6 ICMP error message formats as detailed above. In addition, the ICMP error messages contain the IP header for the packet in error which needs to be translated just like a normal IP header. The translation of this "packet in error" is likely to change the length of the datagram thus the Payload Length field in the outer IPv6 header might need to be updated.




+-------------+                 +-------------+
|    IPv4     |                 |    IPv6     |
|   Header    |                 |   Header    |
+-------------+                 +-------------+
|   ICMPv4    |                 |   ICMPv6    |
|   Header    |                 |   Header    |
+-------------+                 +-------------+
|    IPv4     |      ===>       |    IPv6     |
|   Header    |                 |   Header    |
+-------------+                 +-------------+
|   Partial   |                 |   Partial   |
|  Transport  |                 |  Transport  |
|   Layer     |                 |   Layer     |
|   Header    |                 |   Header    |
+-------------+                 +-------------+

 Figure 4: IPv4-to-IPv6 ICMP Error Translation 

The translation of the inner IP header can be done by recursively invoking the function that translated the outer IP headers.



 TOC 

4.5.  Knowing when to Translate

The translator is assumed to know the pool(s) of IPv4 address that are used to represent the internal IPv6-only nodes. If the translator is implemented in a router providing both translation and normal forwarding, and the address is reachable by a more specific route without translation, the router should forward it without translating it. In general, however, if the IPv4 destination field contains an address that falls in these configured sets of prefixes the packet needs to be translated to IPv6.



 TOC 

5.  Translating from IPv6 to IPv4

When an IPv6-to-IPv4 translator receives an IPv6 datagram addressed to an IPv4-mapped IPv6 address, it translates the IPv6 header of that packet into an IPv4 header. It then forwards the packet based on the IPv4 destination address. The original IPv6 header on the packet is removed and replaced by an IPv4 header. Except for ICMP packets the transport layer header and data portion of the packet are left unchanged.




+-------------+                 +-------------+
|    IPv6     |                 |    IPv4     |
|   Header    |                 |   Header    |
+-------------+                 +-------------+
|  Fragment   |                 |  Transport  |
|   Header    |      ===>       |   Layer     |
|(if present) |                 |   Header    |
+-------------+                 +-------------+
|  Transport  |                 |             |
|   Layer     |                 ~    Data     ~
|   Header    |                 |             |
+-------------+                 +-------------+
|             |
~    Data     ~
|             |
+-------------+

 Figure 5: IPv6-to-IPv4 Translation 

There are some differences between IPv6 and IPv4 in the area of fragmentation and the minimum link MTU that effect the translation. An IPv6 link has to have an MTU of 1280 bytes or greater. The corresponding limit for IPv4 is 68 bytes. Thus, unless there were special measures, it would not be possible to do end-to-end path MTU discovery when the path includes an IPv6-to-IPv4 translator since the IPv6 node might receive ICMP "packet too big" messages originated by an IPv4 router that report an MTU less than 1280. However, [RFC2460] (Deering, S. and R. Hinden, “Internet Protocol, Version 6 (IPv6) Specification,” December 1998.) requires that IPv6 nodes handle such an ICMP "packet too big" message by reducing the path MTU to 1280 and including an IPv6 fragment header with each packet. This allows end-to-end path MTU discovery across the translator as long as the path MTU is 1280 bytes or greater. When the path MTU drops below the 1280 limit the IPv6 sender will originate 1280 byte packets that will be fragmented by IPv4 routers along the path after being translated to IPv4.

The only drawback with this scheme is that it is not possible to use PMTU to do optimal UDP fragmentation (as opposed to completely avoiding fragmentation) at sender since the presence of an IPv6 Fragment header is interpreted that is it OK to fragment the packet on the IPv4 side. Thus if a UDP application wants to send large packets independent of the PMTU, the sender will only be able to determine the path MTU on the IPv6 side of the translator. If the path MTU on the IPv4 side of the translator is smaller then the IPv6 sender will not receive any ICMP "too big" errors and can not adjust the size fragments it is sending.

Other than the special rules for handling fragments and path MTU discovery the actual translation of the packet header consists of a simple mapping as defined below. Note that ICMP packets require special handling in order to translate the content of ICMP error message and also to add the ICMP pseudo-header checksum.



 TOC 

5.1.  Translating IPv6 Headers into IPv4 Headers

If there is no IPv6 Fragment header the IPv4 header fields are set as follows:

Version:
4
Internet Header Length:
5 (no IPv4 options)
Type of Service (TOS) Octet:
By default, copied from the IPv6 Traffic Class (all 8 bits). According to [RFC2474] (Nichols, K., Blake, S., Baker, F., and D. Black, “Definition of the Differentiated Services Field (DS Field) in the IPv4 and IPv6 Headers,” December 1998.) the semantics of the bits are identical in IPv4 and IPv6. However, in some IPv4 environments these bits might be used with the old semantics of "Type Of Service and Precedence". An implementation of a translator SHOULD provide the ability to ignore the IPv6 traffic class and always set the IPv4 TOS Octet to a specified value.
Total Length:
Payload length value from IPv6 header, plus the size of the IPv4 header.
Identification:
All zero.
Flags:
The More Fragments flag is set to zero. The Don't Fragments flag is set to one.
Fragment Offset:
All zero.
Time to Live:
Hop Limit value copied from IPv6 header. Since the translator is a router, as part of forwarding the packet it needs to decrement either the IPv6 Hop Limit (before the translation) or the IPv4 TTL (after the translation). As part of decrementing the TTL or Hop Limit the translator (as any router) needs to check for zero and send the ICMPv4 or ICMPv6 "ttl exceeded" error.
Protocol:
Next Header field copied from IPv6 header.
Header Checksum:
Computed once the IPv4 header has been created.
Source Address:
In stateless mode, which is to say that if the IPv6 source address is within the range of the stateless translation prefix described in Section 1.3 (Stateless vs Stateful Mode), the address format is derived from the IPv4 address as specified in [FRAMEWORK] (Baker, F., “Framework for IPv4/IPv6 Translation - baker-behave-v4v6-framework,” October 2008.).
In stateful mode, which is to say that if the IPv6 source address is not of the form described in [FRAMEWORK] (Baker, F., “Framework for IPv4/IPv6 Translation - baker-behave-v4v6-framework,” October 2008.), the IPv4 source address and transport layer source port corresponding to the IPv6 source address and source port are derived from the database reflecting current session state in the translator as described in [I‑D.bagnulo‑behave‑nat64] (Bagnulo, M., Matthews, P., and I. Beijnum, “NAT64: Network Address and Protocol Translation from IPv6 Clients to IPv4 Servers,” March 2009.).
Destination Address:
IPv6 packets that are translated have an IPv4-mapped destination address. Thus the address is derived from the IPv6 address as specified in [FRAMEWORK] (Baker, F., “Framework for IPv4/IPv6 Translation - baker-behave-v4v6-framework,” October 2008.).

If any of an IPv6 hop-by-hop options header, destination options header, or routing header with the Segments Left field equal to zero are present in the IPv6 packet, they are ignored i.e., there is no attempt to translate them. However, the Total Length field and the Protocol field would have to be adjusted to "skip" these extension headers.

If a routing header with a non-zero Segments Left field is present then the packet MUST NOT be translated, and an ICMPv6 "parameter problem/ erroneous header field encountered" (Type 4/Code 0) error message, with the Pointer field indicating the first byte of the Segments Left field, SHOULD be returned to the sender.

If the IPv6 packet contains a Fragment header the header fields are set as above with the following exceptions:

Total Length:
Payload length value from IPv6 header, minus 8 for the Fragment header, plus the size of the IPv4 header.
Identification:
Copied from the low-order 16-bits in the Identification field in the Fragment header.
Flags:
The More Fragments flag is copied from the M flag in the Fragment header. The Don't Fragments flag is set to zero allowing this packet to be fragmented by IPv4 routers.
Fragment Offset:
Copied from the Fragment Offset field in the Fragment Header.
Protocol:
Next Header value copied from Fragment header.


 TOC 

5.2.  Translating ICMPv6 Headers into ICMPv4 Headers

All ICMP messages that are to be translated require that the ICMP checksum field be updated as part of the translation since ICMPv6 unlike ICMPv4 has a pseudo-header checksum just like UDP and TCP.

In addition all ICMP packets need to have the Type value translated and for ICMP error messages the included IP header also needs translation.

The actions needed to translate various ICMPv6 messages are:

ICMPv6 informational messages:
Echo Request and Echo Reply (Type 128 and 129)
Adjust the type to 0 and 8, respectively, and adjust the ICMP checksum both to take the type change into account and to exclude the ICMPv6 pseudo-header.
MLD Multicast Listener Query/Report/Done (Type 130, 131, 132)
Single hop message. Silently drop.
Neighbor Discover messages (Type 133 through 137)
Single hop message. Silently drop.
Unknown informational messages
Silently drop.
ICMPv6 error messages:
Destination Unreachable (Type 1)
Set the Type field to 3. Translate the code field as follows:
Code 0 (no route to destination):
Set Code to 1 (host unreachable).
Code 1 (communication with destination administratively prohibited):
Set Code to 10 (communication with destination host administratively prohibited).
Code 2 (beyond scope of source address):
Set Code to 1 (host unreachable). Note that this error is very unlikely since the IPv4-translatable source address is considered to have global scope.
Code 3 (address unreachable):
Set Code to 1 (host unreachable).
Code 4 (port unreachable):
Set Code to 3 (port unreachable).
Packet Too Big (Type 2)
Translate to an ICMPv4 Destination Unreachable with code 4. The MTU field needs to be adjusted for the difference between the IPv4 and IPv6 header sizes taking into account whether or not the packet in error includes a Fragment header.
Time Exceeded (Type 3)
Set the Type to 11. The Code field is unchanged.
Parameter Problem (Type 4)
If the Code is 1 translate this to an ICMPv4 protocol unreachable (Type 3, Code 2). Otherwise set the Type to 12 and the Code to zero. The Pointer needs to be updated to point to the corresponding field in the translated include IP header.
Unknown error messages
Silently drop.


 TOC 

5.3.  Translating ICMPv6 Error Messages into ICMPv4

There are some differences between the IPv4 and the IPv6 ICMP error message formats as detailed above. In addition, the ICMP error messages contain the IP header for the packet in error which needs to be translated just like a normal IP header. The translation of this "packet in error" is likely to change the length of the datagram thus the Total Length field in the outer IPv4 header might need to be updated.




+-------------+                 +-------------+
|    IPv6     |                 |    IPv4     |
|   Header    |                 |   Header    |
+-------------+                 +-------------+
|   ICMPv6    |                 |   ICMPv4    |
|   Header    |                 |   Header    |
+-------------+                 +-------------+
|    IPv6     |      ===>       |    IPv4     |
|   Header    |                 |   Header    |
+-------------+                 +-------------+
|   Partial   |                 |   Partial   |
|  Transport  |                 |  Transport  |
|   Layer     |                 |   Layer     |
|   Header    |                 |   Header    |
+-------------+                 +-------------+

 Figure 6: IPv6-to-IPv4 ICMP Error Translation 

The translation of the inner IP header can be done by recursively invoking the function that translated the outer IP headers.



 TOC 

5.4.  Knowing when to Translate

If the translator is implemented in a router providing both translation and normal forwarding, and the address is reachable by a more specific route without translation, the router should forward it without translating it. Otherwise, when the translator receives an IPv6 packet with an IPv4-mapped destination address the packet will be translated to IPv4.



 TOC 

6.  Implications for IPv6-Only Nodes

An IPv6-only node which works through an IPv4/IPv6 translator needs some modifications beyond a normal IPv6-only node.

As specified in Section 1.4 (Impact Outside the Network Layer) the application protocols need to handle operation on a dual stack node. In addition the protocol stack needs to be able to:



 TOC 

7.  IANA Considerations

This memo adds no new IANA considerations.

Note to RFC Editor: This section will have served its purpose if it correctly tells IANA that no new assignments or registries are required, or if those assignments or registries are created during the RFC publication process. From the author's perspective, it may therefore be removed upon publication as an RFC at the RFC Editor's discretion.



 TOC 

8.  Security Considerations

The use of stateless IP/ICMP translators does not introduce any new security issues beyond the security issues that are already present in the IPv4 and IPv6 protocols and in the routing protocols which are used to make the packets reach the translator.

As the Authentication Header [RFC4302] (Kent, S., “IP Authentication Header,” December 2005.) is specified to include the IPv4 Identification field and the translating function not being able to always preserve the Identification field, it is not possible for an IPv6 endpoint to compute AH on received packets that have been translated from IPv4 packets. Thus AH does not work through a translator.

Packets with ESP can be translated since ESP does not depend on header fields prior to the ESP header. Note that ESP transport mode is easier to handle than ESP tunnel mode; in order to use ESP tunnel mode the IPv6 node needs to be able to generate an inner IPv4 header when transmitting packets and remove such an IPv4 header when receiving packets.



 TOC 

9.  Acknowledgements

This is under development by a large group of people. Those who have posted to the list during the discussion include Andrew Sullivan, Andrew Yourtchenko, Brian Carpenter, Dan Wing, Ed Jankiewicz, Fred Baker, Hiroshi Miyata, Iljitsch van Beijnum, John Schnizlein, Kevin Yin, Magnus Westerlund, Marcelo Bagnulo Braun, Margaret Wasserman, Masahito Endo, Phil Roberts, Philip Matthews, Remi Denis-Courmont, Remi Despres, and Xing Li.



 TOC 

10.  References



 TOC 

10.1. Normative References

[FRAMEWORK] Baker, F., “Framework for IPv4/IPv6 Translation - baker-behave-v4v6-framework,” October 2008.
[I-D.bagnulo-behave-nat64] Bagnulo, M., Matthews, P., and I. Beijnum, “NAT64: Network Address and Protocol Translation from IPv6 Clients to IPv4 Servers,” draft-bagnulo-behave-nat64-03 (work in progress), March 2009 (TXT).
[RFC0791] Postel, J., “Internet Protocol,” STD 5, RFC 791, September 1981 (TXT).
[RFC0792] Postel, J., “Internet Control Message Protocol,” STD 5, RFC 792, September 1981 (TXT).
[RFC2119] Bradner, S., “Key words for use in RFCs to Indicate Requirement Levels,” BCP 14, RFC 2119, March 1997 (TXT, HTML, XML).
[RFC2460] Deering, S. and R. Hinden, “Internet Protocol, Version 6 (IPv6) Specification,” RFC 2460, December 1998 (TXT, HTML, XML).
[RFC2765] Nordmark, E., “Stateless IP/ICMP Translation Algorithm (SIIT),” RFC 2765, February 2000 (TXT).
[RFC4291] Hinden, R. and S. Deering, “IP Version 6 Addressing Architecture,” RFC 4291, February 2006 (TXT).
[RFC4443] Conta, A., Deering, S., and M. Gupta, “Internet Control Message Protocol (ICMPv6) for the Internet Protocol Version 6 (IPv6) Specification,” RFC 4443, March 2006 (TXT).
[RFC5382] Guha, S., Biswas, K., Ford, B., Sivakumar, S., and P. Srisuresh, “NAT Behavioral Requirements for TCP,” BCP 142, RFC 5382, October 2008 (TXT).


 TOC 

10.2. Informative References

[I-D.petithuguenin-behave-stun-pmtud] Petit-Huguenin, M., “Path MTU Discovery Using Session Traversal Utilities for NAT (STUN),” draft-petithuguenin-behave-stun-pmtud-03 (work in progress), March 2009 (TXT).
[Miller] Miller, G., “Email to the ngtrans mailing list,” March 1999.
[RFC1112] Deering, S., “Host extensions for IP multicasting,” STD 5, RFC 1112, August 1989 (TXT).
[RFC1191] Mogul, J. and S. Deering, “Path MTU discovery,” RFC 1191, November 1990 (TXT).
[RFC1981] McCann, J., Deering, S., and J. Mogul, “Path MTU Discovery for IP version 6,” RFC 1981, August 1996 (TXT).
[RFC2428] Allman, M., Ostermann, S., and C. Metz, “FTP Extensions for IPv6 and NATs,” RFC 2428, September 1998 (TXT, HTML, XML).
[RFC2474] Nichols, K., Blake, S., Baker, F., and D. Black, “Definition of the Differentiated Services Field (DS Field) in the IPv4 and IPv6 Headers,” RFC 2474, December 1998 (TXT, HTML, XML).
[RFC2710] Deering, S., Fenner, W., and B. Haberman, “Multicast Listener Discovery (MLD) for IPv6,” RFC 2710, October 1999 (TXT).
[RFC3493] Gilligan, R., Thomson, S., Bound, J., McCann, J., and W. Stevens, “Basic Socket Interface Extensions for IPv6,” RFC 3493, February 2003 (TXT).
[RFC3590] Haberman, B., “Source Address Selection for the Multicast Listener Discovery (MLD) Protocol,” RFC 3590, September 2003 (TXT).
[RFC3810] Vida, R. and L. Costa, “Multicast Listener Discovery Version 2 (MLDv2) for IPv6,” RFC 3810, June 2004 (TXT).
[RFC4213] Nordmark, E. and R. Gilligan, “Basic Transition Mechanisms for IPv6 Hosts and Routers,” RFC 4213, October 2005 (TXT).
[RFC4301] Kent, S. and K. Seo, “Security Architecture for the Internet Protocol,” RFC 4301, December 2005 (TXT).
[RFC4302] Kent, S., “IP Authentication Header,” RFC 4302, December 2005 (TXT).
[RFC4303] Kent, S., “IP Encapsulating Security Payload (ESP),” RFC 4303, December 2005 (TXT).
[RFC4821] Mathis, M. and J. Heffner, “Packetization Layer Path MTU Discovery,” RFC 4821, March 2007 (TXT).
[RFC4861] Narten, T., Nordmark, E., Simpson, W., and H. Soliman, “Neighbor Discovery for IP version 6 (IPv6),” RFC 4861, September 2007 (TXT).


 TOC 

Authors' Addresses

  Xing Li (editor)
  CERNET Center/Tsinghua University
  Room 225, Main Building, Tsinghua University
  Beijing, 100084
  China
Phone:  +86 62785983
Email:  xing@cernet.edu.cn
  
  Congxiao Bao (editor)
  CERNET Center/Tsinghua University
  Room 225, Main Building, Tsinghua University
  Beijing, 100084
  China
Phone:  +86 62785983
Email:  congxiao@cernet.edu.cn
  
  Fred Baker (editor)
  Cisco Systems
  Santa Barbara, California 93117
  USA
Phone:  +1-408-526-4257
Email:  fred@cisco.com


 TOC 

Full Copyright Statement

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