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IETF RFC 1933
Transition Mechanisms for IPv6 Hosts and Routers
Last modified on Friday, April 5th, 1996
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Network Working Group R. Gilligan
Request for Comments: 1933 E. Nordmark
Category: Standards Track Sun Microsystems, Inc.
April 1996
Transition Mechanisms for IPv6 Hosts and Routers
Status of this Memo
This document specifies an Internet standards track protocol for the
Internet community, and requests discussion and suggestions for
improvements. Please refer to the current edition of the "Internet
Official Protocol Standards" (STD 1) for the standardization state
and status of this protocol. Distribution of this memo is unlimited.
Abstract
This document specifies IPv4 compatibility mechanisms that can be
implemented by IPv6 hosts and routers. These mechanisms include
providing complete implementations of both versions of the Internet
Protocol (IPv4 and IPv6), and tunneling IPv6 packets over IPv4
routing infrastructures. They are designed to allow IPv6 nodes to
maintain complete compatibility with IPv4, which should greatly
simplify the deployment of IPv6 in the Internet, and facilitate the
eventual transition of the entire Internet to IPv6.
1. Introduction
The key to a successful IPv6 transition is compatibility with the
large installed base of IPv4 hosts and routers. Maintaining
compatibility with IPv4 while deploying IPv6 will streamline the task
of transitioning the Internet to IPv6. This specification defines a
set of mechanisms that IPv6 hosts and routers may implement in order
to be compatible with IPv4 hosts and routers.
The mechanisms in this document are designed to be employed by IPv6
hosts and routers that need to interoperate with IPv4 hosts and
utilize IPv4 routing infrastructures. We expect that most nodes in
the Internet will need such compatibility for a long time to come,
and perhaps even indefinitely.
However, IPv6 may be used in some environments where interoperability
with IPv4 is not required. IPv6 nodes that are designed to be used
in such environments need not use or even implement these mechanisms.
The mechanisms specified here include:
Gilligan & Nordmark Standards Track PAGE 1
RFC 1933 IPv6 Transition Mechanisms April 1996
- Dual IP layer. Providing complete support for both IPv4 and
IPv6 in hosts and routers.
- IPv6 over IPv4 tunneling. Encapsulating IPv6 packets within
IPv4 headers to carry them over IPv4 routing infrastructures.
Two types of tunneling are employed: configured and automatic.
Additional transition and compatibility mechanisms may be developed
in the future. These will be specified in other documents.
1.2. Terminology
The following terms are used in this document:
Types of Nodes
IPv4-only node:
A host or router that implements only IPv4. An
IPv4-only node does not understand IPv6. The installed
base of IPv4 hosts and routers existing before the
transition begins are IPv4-only nodes.
IPv6/IPv4 node:
A host or router that implements both IPv4 and IPv6.
IPv6-only node:
A host or router that implements IPv6, and does not
implement IPv4. The operation of IPv6-only nodes is not
addressed here.
IPv6 node:
Any host or router that implements IPv6. IPv6/IPv4 and
IPv6-only nodes are both IPv6 nodes.
IPv4 node:
Any host or router that implements IPv4. IPv6/IPv4 and
IPv4-only nodes are both IPv4 nodes.
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RFC 1933 IPv6 Transition Mechanisms April 1996
Types of IPv6 Addresses
IPv4-compatible IPv6 address:
An IPv6 address, assigned to an IPv6/IPv4 node, which
bears the high-order 96-bit prefix 0:0:0:0:0:0, and an
IPv4 address in the low-order 32-bits. IPv4-compatible
addresses are used by the automatic tunneling mechanism.
IPv6-only address:
The remainder of the IPv6 address space. An IPv6
address that bears a prefix other than 0:0:0:0:0:0.
Techniques Used in the Transition
IPv6-over-IPv4 tunneling:
The technique of encapsulating IPv6 packets within IPv4
so that they can be carried across IPv4 routing
infrastructures.
IPv6-in-IPv4 encapsulation:
IPv6-over-IPv4 tunneling.
Configured tunneling:
IPv6-over-IPv4 tunneling where the IPv4 tunnel endpoint
address is determined by configuration information on
the encapsulating node.
Automatic tunneling:
IPv6-over-IPv4 tunneling where the IPv4 tunnel endpoint
address is determined from the IPv4 address embedded in
the IPv4-compatible destination address of the IPv6
packet.
1.3. Structure of this Document
The remainder of this document is organized into three sections:
- Section 2 discusses the IPv4-compatible address format.
- Section 3 discusses the operation of nodes with a dual IP
layer, IPv6/IPv4 nodes.
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RFC 1933 IPv6 Transition Mechanisms April 1996
- Section 4 discusses IPv6-over-IPv4 tunneling.
2. Addressing
The automatic tunneling mechanism uses a special type of IPv6
address, termed an "IPv4-compatible" address. An IPv4-compatible
address is identified by an all-zeros 96-bit prefix, and holds an
IPv4 address in the low-order 32-bits. IPv4-compatible addresses are
structured as follows:
| 96-bits | 32-bits |
+--------------------------------------+--------------+
| 0:0:0:0:0:0 | IPv4 Address |
+--------------------------------------+--------------+
IPv4-Compatible IPv6 Address Format
IPv4-compatible addresses are assigned to IPv6/IPv4 nodes that
support automatic tunneling. Nodes that are configured with IPv4-
compatible addresses may use the complete address as their IPv6
address, and use the embedded IPv4 address as their IPv4 address.
The remainder of the IPv6 address space (that is, all addresses with
96-bit prefixes other than 0:0:0:0:0:0) are termed "IPv6-only
Addresses."
3. Dual IP Layer
The most straightforward way for IPv6 nodes to remain compatible with
IPv4-only nodes is by providing a complete IPv4 implementation. IPv6
nodes that provide a complete IPv4 implementation in addition to
their IPv6 implementation are called "IPv6/IPv4 nodes." IPv6/IPv4
nodes have the ability to send and receive both IPv4 and IPv6
packets. They can directly interoperate with IPv4 nodes using IPv4
packets, and also directly interoperate with IPv6 nodes using IPv6
packets.
The dual IP layer technique may or may not be used in conjunction
with the IPv6-over-IPv4 tunneling techniques, which are described in
section 4. An IPv6/IPv4 node that supports tunneling may support
only configured tunneling, or both configured and automatic
tunneling. Thus three configurations are possible:
- IPv6/IPv4 node that does not perform tunneling.
- IPv6/IPv4 node that performs configured tunneling only.
- IPv6/IPv4 node that performs configured tunneling and
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RFC 1933 IPv6 Transition Mechanisms April 1996
automatic tunneling.
3.1. Address Configuration
Because they support both protocols, IPv6/IPv4 nodes may be
configured with both IPv4 and IPv6 addresses. Although the two
addresses may be related to each other, this is not required.
IPv6/IPv4 nodes may be configured with IPv6 and IPv4 addresses that
are unrelated to each other.
Nodes that perform automatic tunneling are configured with IPv4-
compatible IPv6 addresses. These may be viewed as single addresses
that can serve both as IPv6 and IPv4 addresses. The entire 128-bit
IPv4-compatible IPv6 address is used as the node's IPv6 address,
while the IPv4 address embedded in low-order 32-bits serves as the
node's IPv4 address.
IPv6/IPv4 nodes may use the stateless IPv6 address configuration
mechanism [5] or DHCP for IPv6 [3] to acquire their IPv6 address.
These mechanisms may provide either IPv4-compatible or IPv6-only IPv6
addresses.
IPv6/IPv4 nodes may use IPv4 mechanisms to acquire their IPv4
addresses.
IPv6/IPv4 nodes that perform automatic tunneling may also acquire
their IPv4-compatible IPv6 addresses from another source: IPv4
address configuration protocols. A node may use any IPv4 address
configuration mechanism to acquire its IPv4 address, then "map" that
address into an IPv4-compatible IPv6 address by pre-pending it with
the 96-bit prefix 0:0:0:0:0:0. This mode of configuration allows
IPv6/IPv4 nodes to "leverage" the installed base of IPv4 address
configuration servers. It can be particularly useful in environments
where IPv6 routers and address configuration servers have not yet
been deployed.
The specific algorithm for acquiring an IPv4-compatible address using
IPv4-based address configuration protocols is as follows:
1) The IPv6/IPv4 node uses standard IPv4 mechanisms or protocols
to acquire its own IPv4 address. These include:
- The Dynamic Host Configuration Protocol (DHCP) [2]
- The Bootstrap Protocol (BOOTP) [1]
- The Reverse Address Resolution Protocol (RARP) [9]
- Manual configuration
- Any other mechanism which accurately yields the node's
own IPv4 address
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RFC 1933 IPv6 Transition Mechanisms April 1996
2) The node uses this address as its IPv4 address.
3) The node prepends the 96-bit prefix 0:0:0:0:0:0 to the 32-bit
IPv4 address that it acquired in step (1). The result is an
IPv4-compatible IPv6 address with the node's own IPv4-address
embedded in the low-order 32-bits. The node uses this address
as its own IPv6 address.
3.1.1. IPv4 Loopback Address
Many IPv4 implementations treat the address 127.0.0.1 as a "loopback
address" -- an address to reach services located on the local
machine. Per the host requirements specification [10], section
3.2.1.3, IPv4 packets addressed from or to the loopback address are
not to be sent onto the network; they must remain entirely within the
node. IPv6/IPv4 implementations may treat the IPv4-compatible IPv6
address ::127.0.0.1 as an IPv6 loopback address. Packets with this
address should also remain entirely within the node, and not be
transmitted onto the network.
3.2. DNS
The Domain Naming System (DNS) is used in both IPv4 and IPv6 to map
hostnames into addresses. A new resource record type named "AAAA"
has been defined for IPv6 addresses [6]. Since IPv6/IPv4 nodes must
be able to interoperate directly with both IPv4 and IPv6 nodes, they
must provide resolver libraries capable of dealing with IPv4 "A"
records as well as IPv6 "AAAA" records.
3.2.1. Handling Records for IPv4-Compatible Addresses
When an IPv4-compatible IPv6 addresses is assigned to an IPv6/IPv4
host that supports automatic tunneling, both A and AAAA records are
listed in the DNS. The AAAA record holds the full IPv4-compatible
IPv6 address, while the A record holds the low-order 32-bits of that
address. The AAAA record is needed so that queries by IPv6 hosts can
be satisfied. The A record is needed so that queries by IPv4-only
hosts, whose resolver libraries only support the A record type, will
locate the host.
DNS resolver libraries on IPv6/IPv4 nodes must be capable of handling
both AAAA and A records. However, when a query locates an AAAA
record holding an IPv4-compatible IPv6 address, and an A record
holding the corresponding IPv4 address, the resolver library need not
necessarily return both addresses. It has three options:
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RFC 1933 IPv6 Transition Mechanisms April 1996
- Return only the IPv6 address to the application.
- Return only the IPv4 address to the application.
- Return both addresses to the application.
The selection of which address type to return in this case, or, if
both addresses are returned, in which order they are listed, can
affect what type of IP traffic is generated. If the IPv6 address is
returned, the node will communicate with that destination using IPv6
packets (in most cases encapsulated in IPv4); If the IPv4 address is
returned, the communication will use IPv4 packets.
The way that DNS resolver implementations handle redundant records
for IPv4-compatible addresses may depend on whether that
implementation supports automatic tunneling, or whether it is
enabled. For example, an implementation that does not support
automatic tunneling would not return IPv4-compatible IPv6 addresses
to applications because those destinations are generally only
reachable via tunneling. On the other hand, those implementations in
which automatic tunneling is supported and enabled may elect to
return only the IPv4-compatible IPv6 address and not the IPv4
address.
4. IPv6-over-IPv4 Tunneling
In most deployment scenarios, the IPv6 routing infrastructure will be
built up over time. While the IPv6 infrastructure is being deployed,
the existing IPv4 routing infrastructure can remain functional, and
can be used to carry IPv6 traffic. Tunneling provides a way to
utilize an existing IPv4 routing infrastructure to carry IPv6
traffic.
IPv6/IPv4 hosts and routers can tunnel IPv6 datagrams over regions of
IPv4 routing topology by encapsulating them within IPv4 packets.
Tunneling can be used in a variety of ways:
- Router-to-Router. IPv6/IPv4 routers interconnected by an IPv4
infrastructure can tunnel IPv6 packets between themselves. In
this case, the tunnel spans one segment of the end-to-end path
that the IPv6 packet takes.
- Host-to-Router. IPv6/IPv4 hosts can tunnel IPv6 packets to an
intermediary IPv6/IPv4 router that is reachable via an IPv4
infrastructure. This type of tunnel spans the first segment
of the packet's end-to-end path.
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RFC 1933 IPv6 Transition Mechanisms April 1996
- Host-to-Host. IPv6/IPv4 hosts that are interconnected by an
IPv4 infrastructure can tunnel IPv6 packets between
themselves. In this case, the tunnel spans the entire
end-to-end path that the packet takes.
- Router-to-Host. IPv6/IPv4 routers can tunnel IPv6 packets to
their final destination IPv6/IPv4 host. This tunnel spans
only the last segment of the end-to-end path.
Tunneling techniques are usually classified according to the
mechanism by which the encapsulating node determines the address of
the node at the end of the tunnel. In the first two tunneling
methods listed above -- router-to-router and host-to-router -- the
IPv6 packet is being tunneled to a router. The endpoint of this type
of tunnel is an intermediary router which must decapsulate the IPv6
packet and forward it on to its final destination. When tunneling to
a router, the endpoint of the tunnel is different from the
destination of the packet being tunneled. So the addresses in the
IPv6 packet being tunneled do not provide the IPv4 address of the
tunnel endpoint. Instead, the tunnel endpoint address must be
determined from configuration information on the node performing the
tunneling. We use the term "configured tunneling" to describe the
type of tunneling where the endpoint is explicitly configured.
In the last two tunneling methods -- host-to-host and router-to-host
-- the IPv6 packet is tunneled all the way to its final destination.
The tunnel endpoint is the node to which the IPv6 packet is
addressed. Since the endpoint of the tunnel is the destination of
the IPv6 packet, the tunnel endpoint can be determined from the
destination IPv6 address of that packet: If that address is an IPv4-
compatible address, then the low-order 32-bits hold the IPv4 address
of the destination node, and that can be used as the tunnel endpoint
address. This technique avoids the need to explicitly configure the
tunnel endpoint address. Deriving the tunnel endpoint address from
the embedded IPv4 address of the packet's IPv6 address is termed
"automatic tunneling".
The two tunneling techniques -- automatic and configured -- differ
primarily in how they determine the tunnel endpoint address. Most of
the underlying mechanisms are the same:
- The entry node of the tunnel (the encapsulating node) creates an
encapsulating IPv4 header and transmits the encapsulated packet.
- The exit node of the tunnel (the decapsulating node) receives
the encapsulated packet, removes the IPv4 header, updates the
IPv6 header, and processes the received IPv6 packet.
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RFC 1933 IPv6 Transition Mechanisms April 1996
- The encapsulating node may need to maintain soft state
information for each tunnel recording such parameters as the MTU
of the tunnel in order to process IPv6 packets forwarded into
the tunnel. Since the number of tunnels that any one host or
router may be using may grow to be quite large, this state
information can be cached and discarded when not in use.
The next section discusses the common mechanisms that apply to both
types of tunneling. Subsequent sections discuss how the tunnel
endpoint address is determined for automatic and configured
tunneling.
4.1. Common Tunneling Mechanisms
The encapsulation of an IPv6 datagram in IPv4 is shown below:
+-------------+
| IPv4 |
| Header |
+-------------+ +-------------+
| IPv6 | | IPv6 |
| Header | | Header |
+-------------+ +-------------+
| Transport | | Transport |
| Layer | ===> | Layer |
| Header | | Header |
+-------------+ +-------------+
| | | |
~ Data ~ ~ Data ~
| | | |
+-------------+ +-------------+
Encapsulating IPv6 in IPv4
In addition to adding an IPv4 header, the encapsulating node also has
to handle some more complex issues:
- Determine when to fragment and when to report an ICMP "packet
too big" error back to the source.
- How to reflect IPv4 ICMP errors from routers along the tunnel
path back to the source as IPv6 ICMP errors.
Those issues are discussed in the following sections.
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RFC 1933 IPv6 Transition Mechanisms April 1996
4.1.1. Tunnel MTU and Fragmentation
The encapsulating node could view encapsulation as IPv6 using IPv4 as
a link layer with a very large MTU (65535-20 bytes to be exact; 20
bytes "extra" are needed for the encapsulating IPv4 header). The
encapsulating node would need only to report IPv6 ICMP "packet too
big" errors back to the source for packets that exceed this MTU.
However, such a scheme would be inefficient for two reasons:
1) It would result in more fragmentation than needed. IPv4 layer
fragmentation should be avoided due to the performance problems
caused by the loss unit being smaller than the retransmission
unit [11].
2) Any IPv4 fragmentation occurring inside the tunnel would have to
be reassembled at the tunnel endpoint. For tunnels that
terminate at a router, this would require additional memory to
reassemble the IPv4 fragments into a complete IPv6 packet before
that packet could be forwarded onward.
The fragmentation inside the tunnel can be reduced to a minimum by
having the encapsulating node track the IPv4 Path MTU across the
tunnel, using the IPv4 Path MTU Discovery Protocol [8] and recording
the resulting path MTU. The IPv6 layer in the encapsulating node can
then view a tunnel as a link layer with an MTU equal to the IPv4 path
MTU, minus the size of the encapsulating IPv4 header.
Note that this does not completely eliminate IPv4 fragmentation in
the case when the IPv4 path MTU would result in an IPv6 MTU less than
576 bytes. (Any link layer used by IPv6 has to have an MTU of at
least 576 bytes [4].) In this case the IPv6 layer has to "see" a link
layer with an MTU of 576 bytes and the encapsulating node has to use
IPv4 fragmentation in order to forward the 576 byte IPv6 packets.
The encapsulating node can employ the following algorithm to
determine when to forward an IPv6 packet that is larger than the
tunnel's path MTU using IPv4 fragmentation, and when to return an
IPv6 ICMP "packet too big" message:
if (IPv4 path MTU - 20) is less than or equal to 576
if packet is larger than 576 bytes
Send IPv6 ICMP "packet too big" with MTU = 576.
Drop packet.
else
Encapsulate but do not set the Don't Fragment
flag in the IPv4 header. The resulting IPv4
packet might be fragmented by the IPv4 layer on
the encapsulating node or by some router along
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RFC 1933 IPv6 Transition Mechanisms April 1996
the IPv4 path.
endif
else
if packet is larger than (IPv4 path MTU - 20)
Send IPv6 ICMP "packet too big" with
MTU = (IPv4 path MTU - 20).
Drop packet.
else
Encapsulate and set the Don't Fragment flag
in the IPv4 header.
endif
endif
Encapsulating nodes that have a large number of tunnels might not be
able to store the IPv4 Path MTU for all tunnels. Such nodes can, at
the expense of additional fragmentation in the network, avoid using
the IPv4 Path MTU algorithm across the tunnel and instead use the MTU
of the link layer (under IPv4) in the above algorithm instead of the
IPv4 path MTU.
In this case the Don't Fragment bit must not be set in the
encapsulating IPv4 header.
4.1.2. Hop Limit
IPv6-over-IPv4 tunnels are modeled as "single-hop". That is, the
IPv6 hop limit is decremented by 1 when an IPv6 packet traverses the
tunnel. The single-hop model serves to hide the existence of a
tunnel. The tunnel is opaque to users of the network, and is not
detectable by network diagnostic tools such as traceroute.
The single-hop model is implemented by having the encapsulating and
decapsulating nodes process the IPv6 hop limit field as they would if
they were forwarding a packet on to any other datalink. That is,
they decrement the hop limit by 1 when forwarding an IPv6 packet.
(The originating node and final destination do not decrement the hop
limit.)
The TTL of the encapsulating IPv4 header is selected in an
implementation dependent manner. The current suggested value is
published in the "Assigned Numbers RFC. Implementations may provide
a mechanism to allow the administrator to configure the IPv4 TTL.
4.1.3. Handling IPv4 ICMP errors
In response to encapsulated packets it has sent into the tunnel, the
encapsulating node may receive IPv4 ICMP error messages from IPv4
routers inside the tunnel. These packets are addressed to the
Gilligan & Nordmark Standards Track PAGE 11
RFC 1933 IPv6 Transition Mechanisms April 1996
encapsulating node because it is the IPv4 source of the encapsulated
packet.
The ICMP "packet too big" error messages are handled according to
IPv4 Path MTU Discovery [8] and the resulting path MTU is recorded in
the IPv4 layer. The recorded path MTU is used by IPv6 to determine
if an IPv6 ICMP "packet too big" error has to be generated as
described in section 4.1.1.
The handling of other types of ICMP error messages depends on how
much information is included in the "packet in error" field, which
holds the encapsulated packet that caused the error.
Many older IPv4 routers return only 8 bytes of data beyond the IPv4
header of the packet in error, which is not enough to include the
address fields of the IPv6 header. More modern IPv4 routers may
return enough data beyond the IPv4 header to include the entire IPv6
header and possibly even the data beyond that.
If the offending packet includes enough data, the encapsulating node
may extract the encapsulated IPv6 packet and use it to generating an
IPv6 ICMP message directed back to the originating IPv6 node, as
shown below:
+--------------+
| IPv4 Header |
| dst = encaps |
| node |
+--------------+
| ICMP |
| Header |
- - +--------------+
| IPv4 Header |
| src = encaps |
IPv4 | node |
+--------------+ - -
Packet | IPv6 |
| Header | Original IPv6
in +--------------+ Packet -
| Transport | Can be used to
Error | Header | generate an
+--------------+ IPv6 ICMP
| | error message
~ Data ~ back to the source.
| |
- - +--------------+ - -
IPv4 ICMP Error Message Returned to Encapsulating Node
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RFC 1933 IPv6 Transition Mechanisms April 1996
4.1.4. IPv4 Header Construction
When encapsulating an IPv6 packet in an IPv4 datagram, the IPv4
header fields are set as follows:
Version:
4
IP Header Length in 32-bit words:
5 (There are no IPv4 options in the encapsulating
header.)
Type of Service:
0
Total Length:
Payload length from IPv6 header plus length of IPv6 and
IPv4 headers (i.e. a constant 60 bytes).
Identification:
Generated uniquely as for any IPv4 packet transmitted by
the system.
Flags:
Set the Don't Fragment (DF) flag as specified in
section 4.1.1. Set the More Fragments (MF) bit as
necessary if fragmenting.
Fragment offset:
Set as necessary if fragmenting.
Time to Live:
Set in implementation-specific manner.
Protocol:
41 (Assigned payload type number for IPv6)
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RFC 1933 IPv6 Transition Mechanisms April 1996
Header Checksum:
Calculate the checksum of the IPv4 header.
Source Address:
IPv4 address of outgoing interface of the
encapsulating node.
Destination Address:
IPv4 address of tunnel endpoint.
Any IPv6 options are preserved in the packet (after the IPv6 header).
4.1.5. Decapsulating IPv6-in-IPv4 Packets
When an IPv6/IPv4 host or a router receives an IPv4 datagram that is
addressed to one of its own IPv4 address, and the value of the
protocol field is 41, it removes the IPv4 header and submits the IPv6
datagram to its IPv6 layer code.
The decapsulation is shown below:
+-------------+
| IPv4 |
| Header |
+-------------+ +-------------+
| IPv6 | | IPv6 |
| Header | | Header |
+-------------+ +-------------+
| Transport | | Transport |
| Layer | ===> | Layer |
| Header | | Header |
+-------------+ +-------------+
| | | |
~ Data ~ ~ Data ~
| | | |
+-------------+ +-------------+
Decapsulating IPv6 from IPv4
When decapsulating the IPv6-in-IPv4 packet, the IPv6 header is not
modified. If the packet is subsequently forwarded, its hop limit is
decremented by one.
The encapsulating IPv4 header is discarded.
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The decapsulating node performs IPv4 reassembly before decapsulating
the IPv6 packet. All IPv6 options are preserved even if the
encapsulating IPv4 packet is fragmented.
After the IPv6 packet is decapsulated, it is processed the same as
any received IPv6 packet.
4.2. Configured Tunneling
In configured tunneling, the tunnel endpoint address is determined
from configuration information in the encapsulating node. For each
tunnel, the encapsulating node must store the tunnel endpoint
address. When an IPv6 packet is transmitted over a tunnel, the
tunnel endpoint address configured for that tunnel is used as the
destination address for the encapsulating IPv4 header.
The determination of which packets to tunnel is usually made by
routing information on the encapsulating node. This is usually done
via a routing table, which directs packets based on their destination
address using the prefix mask and match technique.
4.2.1. Default Configured Tunnel
Nodes that are connected to IPv4 routing infrastructures may use a
configured tunnel to reach an IPv6 "backbone". If the IPv4 address
of an IPv6/IPv4 router bordering the backbone is known, a tunnel can
be configured to that router. This tunnel can be configured into the
routing table as a "default route". That is, all IPv6 destination
addresses will match the route and could potentially traverse the
tunnel. Since the "mask length" of such default route is zero, it
will be used only if there are no other routes with a longer mask
that match the destination.
The tunnel endpoint address of such a default tunnel could be the
IPv4 address of one IPv6/IPv4 router at the border of the IPv6
backbone. Alternatively, the tunnel endpoint could be an IPv4
"anycast address". With this approach, multiple IPv6/IPv4 routers at
the border advertise IPv4 reachability to the same IPv4 address. All
of these routers accept packets to this address as their own, and
will decapsulate IPv6 packets tunneled to this address. When an
IPv6/IPv4 node sends an encapsulated packet to this address, it will
be delivered to only one of the border routers, but the sending node
will not know which one. The IPv4 routing system will generally
carry the traffic to the closest router.
Using a default tunnel to an IPv4 "anycast address" provides a high
degree of robustness since multiple border router can be provided,
and, using the normal fallback mechanisms of IPv4 routing, traffic
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RFC 1933 IPv6 Transition Mechanisms April 1996
will automatically switch to another router when one goes down.
4.3. Automatic Tunneling
In automatic tunneling, the tunnel endpoint address is determined
from the packet being tunneled. The destination IPv6 address in the
packet must be an IPv4-compatible address. If it is, the IPv4
address component of that address -- the low-order 32-bits -- are
extracted and used as the tunnel endpoint address. IPv6 packets that
are not addressed to an IPv4-compatible address can not be tunneled
using automatic tunneling.
IPv6/IPv4 nodes need to determine which IPv6 packets can be sent via
automatic tunneling. One technique is to use the IPv6 routing table
to direct automatic tunneling. An implementation can have a special
static routing table entry for the prefix 0:0:0:0:0:0/96. (That is,
a route to the all-zeros prefix with a 96-bit mask.) Packets that
match this prefix are sent to a pseudo-interface driver which
performs automatic tunneling. Since all IPv4-compatible IPv6
addresses will match this prefix, all packets to those destinations
will be auto-tunneled.
4.4. Default Sending Algorithm
This section presents a combined IPv4 and IPv6 sending algorithm that
IPv6/IPv4 nodes can use. The algorithm can be used to determine when
to send IPv4 packets, when to send IPv6 packets, and when to perform
automatic and configured tunneling. It illustrates how the
techniques of dual IP layer, configured tunneling, and automatic
tunneling can be used together. Note that is just an example to show
how the techniques can be combined; IPv6/IPv6 implementations may
provide different algorithms. This algorithm has the following
properties:
- Sends IPv4 packets to all IPv4 destinations.
- Sends IPv6 packets to all IPv6 destinations on the same link.
- Using automatic tunneling, sends IPv6 packets encapsulated in
IPv4 to IPv6 destinations with IPv4-compatible addresses that
are located off-link.
- Sends IPv6 packets to IPv6 destinations located off-link when
IPv6 routers are present.
- Using the default IPv6 tunnel, sends IPv6 packets encapsulated
in IPv4 to IPv6 destinations with IPv6-only addresses when no
IPv6 routers are present.
Gilligan & Nordmark Standards Track PAGE 16
RFC 1933 IPv6 Transition Mechanisms April 1996
The algorithm is as follows:
1) If the address of the end node is an IPv4 address then:
1.1) If the destination is located on an attached link, then
send an IPv4 packet addressed to the end node.
1.2) If the destination is located off-link, then;
1.2.1) If there is an IPv4 router on link, then send an
IPv4 format packet. The IPv4 destination
address is the IPv4 address of the end node.
The datalink address is the datalink address of
the IPv4 router.
1.2.2) Else, the destination is treated as
"unreachable" because it is located off link and
there are no on-link routers.
2) If the address of the end node is an IPv4-compatible IPv6
address (i.e. bears the prefix 0:0:0:0:0:0), then:
2.1) If the destination is located on an attached link, then
send an IPv6 format packet (not encapsulated). The IPv6
destination address is the IPv6 address of the end node.
The datalink address is the datalink address of the end
node.
2.2) If the destination is located off-link, then:
2.2.1) If there is an IPv4 router on an attached link,
then send an IPv6 packet encapsulated in IPv4.
The IPv6 destination address is the address of
the end node. The IPv4 destination address is
the low-order 32-bits of the end node's address.
The datalink address is the datalink address of
the IPv4 router.
2.2.2) Else, if there is an IPv6 router on an attached
link, then send an IPv6 format packet. The IPv6
destination address is the IPv6 address of the
end node. The datalink address is the datalink
address of the IPv6 router.
2.2.3) Else, the destination is treated as
"unreachable" because it is located off-link and
there are no on-link routers.
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RFC 1933 IPv6 Transition Mechanisms April 1996
3) If the address of the end node is an IPv6-only address, then:
3.1) If the destination is located on an attached link, then
send an IPv6 format packet. The IPv6 destination
address is the IPv6 address of the end node. The
datalink address is the datalink address of the end
node.
3.2) If the destination is located off-link, then:
3.2.1) If there is an IPv6 router on an attached link,
then send an IPv6 format packet. The IPv6
destination address is the IPv6 address of the
end node. The datalink address is the datalink
address of the IPv6 router.
3.2.2) Else, if the destination is reachable via a
configured tunnel, and there is an IPv4 router
on an attached link, then send an IPv6
packet encapsulated in IPv4. The IPv6
destination address is the address of the end
node. The IPv4 destination address is the
configured IPv4 address of the tunnel endpoint.
The datalink address is the datalink address of
the IPv4 router.
3.2.3) Else, the destination is treated as
"unreachable" because it is located off-link and
there are no on-link IPv6 routers.
A summary of these sending rules are given in the table below:
Gilligan & Nordmark Standards Track PAGE 18
RFC 1933 IPv6 Transition Mechanisms April 1996
End | End | IPv4 | IPv6 | Packet | | |
Node | Node | Router | Router | Format | IPv6 | IPv4 | DLink
Address | On | On | On | To | Dest | Dest | Dest
Type | Link? | Link? | Link? | Send | Addr | Addr | Addr
------------+---------+---------+---------+--------+------+------+------
IPv4 | Yes | N/A | N/A | IPv4 | N/A | E4 | EL
------------+---------+---------+---------+--------+------+------+------
IPv4 | No | Yes | N/A | IPv4 | N/A | E4 | RL
------------+---------+---------+---------+--------+------+------+------
IPv4 | No | No | N/A | UNRCH | N/A | N/A | N/A
------------+---------+---------+---------+--------+------+------+------
IPv4-compat | Yes | N/A | N/A | IPv6 | E6 | N/A | EL
------------+---------+---------+---------+--------+------+------+------
IPv4-compat | No | Yes | N/A | IPv6/4 | E6 | E4 | RL
------------+---------+---------+---------+--------+------+------+------
IPv4-compat | No | No | Yes | IPv6 | E6 | N/A | RL
------------+---------+---------+---------+--------+------+------+------
IPv4-compat | No | No | No | UNRCH | N/A | N/A | N/A
------------+---------+---------+---------+--------+------+------+------
IPv6-only | Yes | N/A | N/A | IPv6 | E6 | N/A | EL
------------+---------+---------+---------+--------+------+------+------
IPv6-only | No | N/A | Yes | IPv6 | E6 | N/A | RL
------------+---------+---------+---------+--------+------+------+------
IPv6-only | No | Yes | No | IPv6/4 | E6 | T4 | RL
------------+---------+---------+---------+--------+------+------+------
IPv6-only | No | No | No | UNRCH | N/A | N/A | N/A
------------+---------+---------+---------+--------+------+------+------
Key to Abbreviations
--------------------
N/A: Not applicable or does not matter.
E6: IPv6 address of end node.
E4: IPv4 address of end node (low-order 32-bits of
IPv4-compatible address).
EL: Datalink address of end node.
T4: IPv4 address of the tunnel endpoint.
R6: IPv6 address of router.
R4: IPv4 address of router.
RL: Datalink address of router.
IPv4: IPv4 packet format.
IPv6: IPv6 packet format.
IPv6/4: IPv6 encapsulated in IPv4 packet format.
UNRCH: Destination is unreachable. Don't send a packet.
Gilligan & Nordmark Standards Track PAGE 19
RFC 1933 IPv6 Transition Mechanisms April 1996
4.4.1 On/Off Link Determination
Part of the process of determining what packet format to use includes
determining whether a destination is located on an attached link or
not. IPv4 and IPv6 employ different mechanisms. IPv4 uses an
algorithm in which the destination address and the interface address
are both logically ANDed with the netmask of the interface and then
compared. If the resulting two values match, then the destination is
located on-link. This algorithm is discussed in more detail in
Section 3.3.1.1 of the host requirements specification [10]. IPv6
uses the neighbor discovery algorithm described in "Neighbor
Discovery for IP Version 6" [7].
IPv6/IPv4 nodes need to use both methods:
- If a destination is an IPv4 address, then the on/off link
determination is made by comparison with the netmask, as
described in RFC 1122 section 3.3.1.1.
- If a destination is represented by an IPv4-compatible IPv6
address (prefix 0:0:0:0:0:0), the decision is made using the
IPv4 netmask comparison algorithm using the low-order 32-bits
(IPv4 address part) of the destination address.
- If the destination is represented by an IPv6-only address
(prefix other than 0:0:0:0:0:0), the on/off link determination
is made using the IPv6 neighbor discovery mechanism.
5. Acknowledgements
We would like to thank the members of the IPng working group and the
IPng transition working group for their many contributions and
extensive review of this document. Special thanks to Jim Bound, Ross
Callon, and Bob Hinden for many helpful suggestions and to John Moy
for suggesting the IPv4 "anycast address" default tunnel technique.
6. Security Considerations
Security issues are not discussed in this memo.
Gilligan & Nordmark Standards Track PAGE 20
RFC 1933 IPv6 Transition Mechanisms April 1996
7. Authors' Addresses
Robert E. Gilligan
Sun Microsystems, Inc.
2550 Garcia Ave.
Mailstop UMTV 05-44
Mountain View, California 94043
Phone: 415-336-1012
Fax: 415-336-6015
EMail: Bob.Gilligan@Eng.Sun.COM
Erik Nordmark
Sun Microsystems, Inc.
2550 Garcia Ave.
Mailstop UMTV 05-44
Mountain View, California 94043
Phone: 415-336-2788
Fax: 415-336-6015
EMail: Erik.Nordmark@Eng.Sun.COM
7. References
[1] Croft, W., and J. Gilmore, "Bootstrap Protocol", RFC 951,
September 1985.
[2] Droms, R., "Dynamic Host Configuration Protocol", RFC 1541.
October 1993.
[3] Bound, J., "Dynamic Host Configuration Protocol for IPv6 for IPv6
(DHCPv6)", Work in Progress, November 1995.
[4] Deering, S., and R. Hinden, "Internet Protocol, Version 6 (IPv6)
Specification", RFC 1883, December 1995.
[5] Thomson, S., and T. Nartan, "IPv6 Stateless Address
Autoconfiguration, Work in Progress, December 1995.
[6] Thomson, S., and C. Huitema. "DNS Extensions to support IP
version 6", RFC 1886, December 1995.
[7] Nartan, T., Nordmark, E., and W. Simpson, "Neighbor Discovery for
IP Version 6 (IPv6)", Work in Progress, November 1995.
[8] Mogul, J., and S. Deering, "Path MTU Discovery", RFC 1191,
November 1990.
Gilligan & Nordmark Standards Track PAGE 21
RFC 1933 IPv6 Transition Mechanisms April 1996
[9] Finlayson, R., Mann, T., Mogul, J., and M. Theimer, "Reverse
Address Resolution Protocol", RFC 903, June 1984.
[10] Braden, R., "Requirements for Internet Hosts - Communication
Layers", STD 3, RFC 1122, October 1989.
[11] Kent, C., and J. Mogul, "Fragmentation Considered Harmful". In
Proc. SIGCOMM '87 Workshop on Frontiers in Computer
Communications Technology. August 1987.
Gilligan & Nordmark Standards Track PAGE 22
Transition Mechanisms for IPv6 Hosts and Routers
RFC TOTAL SIZE: 47005 bytes
PUBLICATION DATE: Friday, April 5th, 1996
LEGAL RIGHTS: The IETF Trust (see BCP 78)
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