One document matched: draft-ietf-ipngwg-site-prefixes-02.txt
Differences from draft-ietf-ipngwg-site-prefixes-01.txt
INTERNET-DRAFT Erik Nordmark, Sun Microsystems
August 7, 1998
Site prefixes in Neighbor Discovery
<draft-ietf-ipngwg-site-prefixes-02.txt>
Status of this Memo
This document is an Internet-Draft. Internet-Drafts are working
documents of the Internet Engineering Task Force (IETF), its areas,
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Distribution of this memo is unlimited.
This Internet Draft expires February 7, 1999.
Abstract
This document specifies extensions to IPv6 Neighbor Discovery to
carry site prefixes. The site prefixes are used to reduce the effect
of site renumbering by ensuring that the communication inside a site
uses site-local addresses.
This protocol requires that all IPv6 implementations, even those that
do not implement this protocol, ignore all site-local addresses that
they retrieve from the DNS.
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Contents
Status of this Memo.......................................... 1
1. INTRODUCTION AND MOTIVATION.............................. 3
2. TERMINOLOGY.............................................. 4
2.1. What is a site?..................................... 4
2.2. Requirements........................................ 4
3. OVERVIEW................................................. 5
3.1. Protocol Overview................................... 5
3.2. Mobile IP implications.............................. 6
3.3. Assumptions......................................... 9
4. UPDATED PREFIX OPTION FORMAT............................. 9
5. CONCEPTUAL VARIABLES..................................... 11
6. SENDING RULES............................................ 12
7. RECEIVING RULES.......................................... 12
8. USING THE SITE PREFIXES.................................. 13
8.1. Host Name Lookups................................... 13
8.2. IPv6 Address Lookups................................ 14
9. MULTIHOMED TO MULTIPLE SITES............................. 15
9.1. Detecting site multihoming.......................... 16
10. SECURITY CONSIDERATIONS................................. 16
REFERENCES................................................... 17
AUTHOR'S ADDRESS............................................. 18
APPENDIX A: CHANGES SINCE PREVIOUS DRAFT..................... 19
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1. INTRODUCTION AND MOTIVATION
In order to maintain the aggregation of the global Internet routing
tables it might be necessary for whole sites to renumber to use
different prefixes for their global IPv6 addresses. Such renumbering
would not directly benefit the renumbered sites but instead be
necessary for the scaling of the Internet as a whole.
In order to increase the probability that such renumbering is viewed
favorably by the sites themselves, which see little or no direct
benefit, it is critical that both the effort of renumbering is kept
at a minimum and also that the risk associated with renumbering is as
small as possible.
The Stateless address autoconfiguration [ADDRCONF] and support for
router renumbering [ROUTER-RENUM] make it easier to renumber a site.
However, these protocols do not by themselves address long-running
TCP connections or cases where IP addresses have been stored in some
configuration file. Thus additional measures are needed to reduce
the risk of renumbering.
For many sites it is much more critical to maintain the internal
communication than the intra-site communication over the Internet.
Based on that observation this proposal tries to limit the effect of
a site renumbering one or more of its global prefixes by ensuring
that intra-site communication can use site-local addresses which
would not be affected by the site renumbering. With this proposal it
is possible to maintain internal long-running TCP connections or
otherwise store IPv6 addresses for longer time than would have been
possible without it.
As specified in [ADDR-TODAY] IP addresses are no longer temporally
unique. This implies, among other things, that applications should
not store IPv6 addresses without a mechanisms for honoring the DNS
time-to-live and refreshing the IPv6 address. This protocol is not
intended to deter from that recommendation but is merely based on the
observation that the applications today might assume that IPv4
addresses are temporally unique and it is likely that some
applications might not be corrected in their behavior as they are
moved to IPv6. It would be unfortunate if such application
"brokenness" would lead sites to view site renumbering as a too risky
or a too costly operation.
This document does not address the general issues of renumbering such
as renumbering a single host or a subnet. It is targeted at site
renumbering. The proposal does not attempt to address how long-
running TCP connections going outside a site will survive the site
renumbering.
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The author would like to acknowledge the contributions the IPNGWG
working group and in particular Mike O'Dell who pointed out the
importance of the problem, and Robert Elz who suggested this approach
to solving the problem.
2. TERMINOLOGY
This documents uses the terminology defined in [IPv6] and
[DISCOVERY].
2.1. What is a site?
This document does not attempt to define the concept of a "site", but
it does place some assumptions on such a definition:
- A site is an administratively controlled piece of topology that is
well-connected. It can be connected using tunnels including the
special form of tunnels (using routing headers and home address
options) defined in [MOBILE-IPv6].
- A link can belong to zero or one site. This implies that an
interface can belong to at most one site.
- A node can have interfaces belonging to different sites. Such a
node is said to be at the site boundary.
- A mobile node [MOBILE-IPv6] which has been assigned one or more
site-local addresses and moves outside the site which contains its
home address (its "home site") is considered to have one
interfaces which is part of the "home site".
2.2. Requirements
The keywords MUST, MUST NOT, REQUIRED, SHALL, SHALL NOT, SHOULD,
SHOULD NOT, RECOMMENDED, MAY, and OPTIONAL, when they appear in this
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document, are to be interpreted as described in [KEYWORDS].
3. OVERVIEW
The goal of this extension to Neighbor Discovery is to make
communication that is local to a single site use the site-local
addresses instead of the global addresses. If all communication
internal to a site uses site-local addresses then the site's global
addresses can be renumbered without having any affect on the internal
communication. Thus the risk associated with site renumbering is
lowered - applications that store IPv6 addresses and long-running TCP
connections will, as long as the communication is local to the site,
continue to operate across the renumbering of the site.
A few alternative solutions have been explored. An early proposal
was to place the site-local addresses in the name service (e.g., the
DNS) and make sure they are returned first in the list of addresses
returned to an application (to make it likely that the application
will use that address). That proposal has the disadvantage that the
name service must return different addresses depending on who asks
the question; if a node inside the site asks for an address it should
return the site-local address(es) but if a node outside the site asks
it must not return a site-local address. This is referred to as the
two-faced DNS. While some sites use a two-faced DNS today as part of
their firewall solution it would be rather unfortunate if each and
every site had to deploy such a solution. See [GSE-EVAL] for more
discussion.
An earlier version of this proposal took a different approach. The
name service would only contain global addresses and the routers
would advertise the global address prefixes assigned to the site
which the nodes would use to derive site-local addresses
corresponding to the global addresses returned from the name service.
That approach had the disadvantage that all nodes in a site would be
required to respond to their automatically derived site local
address. For instance, it was not possible to have certain mobile
nodes that would only be reachable using a global address.
3.1. Protocol Overview
This version of the document takes a middle ground. The site-local
addresses, as well as the global addresses, are stored in the DNS
without requiring a "two-faced" DNS. All nodes are required to
ignore any site-local addresses retrieved from the DNS unless they
can determine that they are in the same site as the peer. This
determination is done by verifying that the retrieved AAAA RRset for
the peer includes one or more global addresses that match the site
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prefixes advertised by the routers.
This protocol assumes that the routing infrastructure will be used to
distribute information about which prefixes belong to the local site.
This document only specifies how the site prefixes are distributed
from the routers to the hosts on each link. However, other protocols
such as [ROUTER-RENUM] might be extended to carry the site prefixes
to all routers in a site. The use of the routing infrastructure to
carry the site prefixes avoids the "two-faced" issue above - the
routers know which part of the network is inside the site thus they
can naturally prevent this information from being distributed outside
the site.
The protocol is based on each host maintaining a list of all the
currently active site prefixes. The site prefixes are periodically
advertised in Neighbor Discovery Router Advertisement messages and
each prefix has an associated lifetime.
Once a host has a list of the prefixes that apply to its site it uses
this information to determine if the global addresses returned by the
name service is part of its site. If this is the case then the host
can use any site-local address contained in that AAAA RRset.
Otherwise any the site-local addresses contained in that RRset must
be ignored. A node should prefer the site-local addresses over the
global addresses e.g. by having the applications try the site-local
addresses before any of the global addresses.
The reverse lookup (from an IPv6 address to a host name) is handled
by mapping a site-local address to the corresponding global
addresses. Thus, if the address being looked up is a site-local
address the host constructs the corresponding global addresses using
the list of site prefixes and performs a reverse lookup on those
addresses until a match is found.
It is expected that both the forward and reverse lookup rules can be
hidden from applications by implementing them as part of the library
that handles host name lookups.
3.2. Mobile IP implications
A mobile node which moves outside its "home site" must maintain the
"home site-local addresses" for continued communication with nodes in
its "home site". This implies that such a mobile node will have one
pseudo interface (for the traffic destined to and from its home site)
which is assigned the home site-local addresses and other interfaces
which might be part of the visited site.
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A mobile node might choose to autoconfigure site-local addresses in
the visited site. However, such addresses add complexity to the
mobile node with little or no benefit. Thus it is recommended that
mobile nodes only autoconfigure global addresses when moving to links
outside its home site.
A mobile node needs to be able to detect when it has moved to a
different site. Thus in addition to the regular movement detection
in [MOBILE-IPv6] it should inspect the site prefixes in the Router
Advertisement messages to determine when it is outside its home site.
The remainder of this section specifies the operation of Mobile IP
when it is outside its home site.
The mobile node needs to retain any site-local addresses it was
assigned in its home site, but those site-local addresses should only
be used when communicating with nodes in its home site.
The binding updates the binding updates will have to use a global
address as the care-of-address.
There are no changes needed to Home Agents. The home agent needs to
select a proper source address when sending to a global address as is
expected of all IPv6 implementations - it should not use a site-local
source address when sending to a global destination address.
The only change needed to the Correspondent Nodes using Routing
Headers to communicate with the mobile node is to include a Home
Address Option to carry its site-local source address so that the IP
source address field can contain a global address when sending to the
global destination.
The additional use of the Home Address Option from the correspondents
ensures that all traffic to and from the mobile node will have global
source addresses. Thus the site-local addresses will be "hidden" in
1) encapsulated headers, 2) routing headers, or 3) home address
option.
Packets encapsulated to the mobile node will look like this:
Outer IP header destination address:
Registered care-of-address. A global address.
Outer IP header source address:
Global address assigned to home agent
Inner IP header destination address:
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One of the mobile node's home addresses. Likely to be a
site-local address.
Inner IP header source address:
Sender of original packet. Likely to be a site-local
address.
Packets sent to the mobile node using routing headers:
IP header destination address:
Registered care-of-address. A global address.
IP header source address:
A global address needed to match the scope of the
destination address. (This requirement is added by the
specification.)
Routing header:
The mobile node's home address which has been used for
this communication e.g. which identifies the TCP
connection. Likely to be a site-local address.
Home address option (This requirement is added by the
specification.):
The correspondent node's address which has been used for
this communication e.g. which identifies the TCP
connection. Likely to be a site-local address.
Packets sent from the mobile node to a site-local correspondent
address:
IP header destination address:
The correspondent node's global address. If this is not
known then the packet must be instead be encapsulated
and sent to the (global address of) the home agent which
can deliver the packet to the site-local destination
address.
IP header source address:
Mobile node's care-of-address. A global address.
Routing header:
The correspondent node's address which has been used for
this communication e.g. which identifies the TCP
connection. Likely to be a site-local address.
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Home address option:
The mobile node's address which has been used for this
communication e.g. which identifies the TCP connection.
Likely to be a site-local address.
Packets sent from the mobile node to a global correspondent:
IP header destination address:
The correspondent node's global address.
IP header source address:
Mobile node's care-of-address. A global address.
Home address option:
The mobile node's address which has been used for this
communication e.g. which identifies the TCP connection.
Likely to be a site-local address.
3.3. Assumptions
The protocol assumes that the site uses a consistent subnet numbering
scheme across all its global addresses and its site-local addresses.
Thus, for every subnet in the site, the 16-bit subnet ID field
[ADDR-ARCH] for the site-local address must have the same value as
the Site-Local Aggregator(s) field in the global addresses.
4. UPDATED PREFIX OPTION FORMAT
The protocol adds two new fields using previously reserved parts of
the Prefix Information Option defined in [DISCOVERY].
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0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Type | Length | Prefix Length |L|A|R|S|Resvd1 |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Valid Lifetime |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Preferred Lifetime |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Site PLength | Reserved2 |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
+ +
| |
+ Prefix +
| |
+ +
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
New fields:
S 1-bit site prefix flag. When set indicates that
this prefix, in addition to what might be specified
by the L and A flags, should be used to create
site-local addresses when an address matches the
first Site PLength part of the prefix.
Site PLength 8-bit unsigned integer. This Site Prefix Length is
only valid when the S flag is set. The number of
leading bits in the Prefix that are valid. The
value ranges from 0 to 128.
The defined format above allows a single Prefix Information option to
carry a subnet prefix used for on-link and/or stateless address
autoconfiguration [ADDRCONF] together with a site prefix since the
site prefix(es) are normally sub-prefixes of the subnet prefixes.
For example, if the subnet prefix is
2000:1:2:653a::0/64
and the site prefix is:
2000:1:2::0/48
this can be encoded in a single Prefix Information option with Prefix
Length being 64, Site PLength being 48 and the Prefix being
2000:1:2:653a::0.
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5. CONCEPTUAL VARIABLES
This document makes use of internal conceptual variables to describe
protocol behavior and external variables that an implementation must
allow system administrators to change. The specific variable names,
how their values change, and how their settings influence protocol
behavior are provided to demonstrate protocol behavior. An
implementation is not required to have them in the exact form
described here, so long as its external behavior is consistent with
that described in this document.
Hosts will need to maintain the following pieces of information.
Unlike the information specific in [DISCOVERY] this information is
not per interface but, for the bulk of this document, viewed as being
for the host as a whole.
Site Prefix List
A list of the site prefixes that have been received
in Router Advertisement messages that have not yet
timed out. Each entry has an associated
invalidation timer value (extracted from the
advertisement) used to expire site prefixes when
they become invalid. A special "infinity" timer
value specifies that a prefix remains valid
forever, unless a new (finite) value is received in
a subsequent advertisement.
Note that the Site Prefix List is separate from the
list of on-link prefixes called Prefix List in
[DISCOVERY].
For normal operation the Site Prefix List is per node. However, in
order to discover that the node is multihomed to multiple sites the
site prefixes have to be tracked for each interface.
The conceptual Router variable called AdvPrefixList in [DISCOVERY] is
extended to also contain site prefixes. Conceptually this can be
done by having each prefix both contain a AdvSubnetPrefixLength and a
AdvSitePrefixLength field. If one of the length fields is zero the
prefix is not used as a on-link and/or addrconf prefix or a site
prefix, respectively. The same lifetime values will apply to both
the subnet and site prefix aspects of a prefix in the AdvPrefixList.
The above are conceptual variables; Implementations are free to
implement the router variables as a separate list for the site
prefixes and the existing Neighbor Discovery AdvPrefixList for subnet
prefixes. However, it is desirable that such implementations still
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use a single Prefix Information option to encode both a site and a
subnet prefix when the site prefix is just a sub-prefix of the subnet
prefix.
6. SENDING RULES
When a router is sending Prefix options as part of sending Router
Advertisement messages in addition to the rules in [DISCOVERY] is
performs the following operations:
o If the AdvSitePrefixLength field in the AdvPrefixList entry is
non-zero set the S flag in the Prefix option to one and set the
Site PLength to the AdvSitePrefixLength.
o Only if the AdvSubnetPrefixLength field is non-zero should the L-
bit and the A-bit be set from the AdvOnLinkFlag and the
AdvAutonomousFlag fields, respectively.
o The Prefix field and the lifetime fields are set is specified in
[DISCOVERY].
7. RECEIVING RULES
The host receiving a valid Router Advertisement follows the rules as
specified in [DISCOVERY] with the following additions when parsing
each received Prefix Information option. For each prefix that has
the S-flag set:
o If the Site PLength is zero ignore the prefix.
o If the prefix is the link-local or the site-local prefix ignore
the prefix.
o If the prefix is a multicast address ignore the prefix.
o If the prefix is not already present in the Site Prefix List and
the Valid Lifetime is zero, ignore the prefix.
o If the prefix is not already present in the Site Prefix List and
the Valid Lifetime is non-zero, create a new entry for the prefix
in the Site Prefix List and initialize its invalidation timer to
the Valid Lifetime value in the Prefix Information option.
o If the prefix is already present in the host's Site Prefix List as
the result of a previously-received advertisement, reset its
invalidation timer to the Valid Lifetime value in the Prefix
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Information option. If the new Lifetime value is zero,
immediately remove the prefix from the Site Prefix List.
The bits in the Prefix after the first Site PLength bits MUST be
ignored when the prefix is entered in the Site Prefix List and/or
when it is compared against other site prefixes. These bits might be
non-zero when the Prefix option carries a subnet prefix in addition
to a site prefix.
Timing out a site prefix from the Site Prefix List SHOULD NOT affect
any existing communication. New communication will use the updated
Site Prefix List after performing a host name lookup.
8. USING THE SITE PREFIXES
The following rules apply when a node looks up host names and
addresses in a name service such as DNS.
8.1. Host Name Lookups
The node will inspect the AAAA RRset returned from DNS to check if
one or more of the global addresses belong to the same site as
itself. This is done by comparing all the global addresses against
all the prefixes in the Site Prefix List. If there are no matches
then the site-local addresses in the RRset must not be used. If
there are one or more matches then the node should prefer using the
site-local address(es) over the global addresses. This can be done
by sorting the addresses before they are returned to the application.
It is important that the site-local addresses are first in the sorted
list so that the applications try the site-local addresses before any
global address. Also, the matched global addresses are removed from
the list in order to prevent the applications from using global
addresses for communication that is local to the site.
A possible algorithm for doing these comparisons is as follows:
1) Assume the name service returns the global addresses G1, G2,
G3, ... Gn and the site-local addresses SL1, SL2, ... SLk.
Assume the prefixes in the Site Prefix List are SP1, SP2, ...
SPm. The Site PLength of each of the prefixes is Length(SPj).
2) For each Gi compare it against all the SPj. If the first
Length(SPj) bits of Gi are equal to the first Length(SPj) bits
of SPj then we have a match.
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3) If there is one or more matches and k > 0 then only give the
application the site-local addresses SL1, SL2, ... SLk.
4) Otherwise give only give the application the global addresses
G1, ... Gn.
For example, if the name service returns these addresses for a
multihomed node:
2837:a:b:987:X:Y:W:Z1
2000:1:2:987:X:Y:W:Z1
fec0::987:X:Y:W:Z1
2837:a:b:34:X:Y:W:Z2
2000:1:2:34:X:Y:W:Z2
fec0::34:X:Y:W:Z2
2abc:77:66:23:X:Y:W:Z3
and the prefixes in the Site Prefix List are:
2837:a:b::0/48
2000:1:2::0/48
The resulting list that the application should use should be:
fec0::987:X:Y:W:Z1
fec0::34:X:Y:W:Z2
If there is no match (e.g., the Site Prefix List is empty) the
resulting list that the application should use should be:
2837:a:b:987:X:Y:W:Z1
2000:1:2:987:X:Y:W:Z1
2837:a:b:34:X:Y:W:Z2
2000:1:2:34:X:Y:W:Z2
2abc:77:66:23:X:Y:W:Z3
8.2. IPv6 Address Lookups
It is not sufficient to handle the forward lookup. For instance, the
node that receives packets and/or connections from a site-local
address might have the desire to perform a reverse lookup to get a
host name. Thus these rules allow such a reverse lookup to succeed
as long as the Site Prefix List contains all the prefixes that apply
to the site.
A possible algorithm for doing this is as follows:
1) Assume the site-local address is SL and the prefixes in the
Site Prefix List are SP1, SP2, ... SPm. The Site PLength of
each of the prefixes is Length(SPj).
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2) First perform a regular reverse lookup of the IPv6 address. If
the lookup succeeds, or the lookup fails and the IPv6 address
is not a site-local address, report the failure to the
application.
3) When the reverse lookup of a site-local address fails use the
Site Prefix List to construct global addresses corresponding to
the site-local address. This is done by taking each entry in
the Site Prefix List and using it to construct a global
address. For each of the SPj concatenate the first Length(SPj)
bits from SPj and the last (128 - Length(SPj)) bits from SL to
form a new address. Look up each of the resulting addresses
until a match is found.
For example, if the site-local address is:
fec0::987:X:Y:W:Z1
and the prefixes in the Site Prefix List are:
2837:a:b::0/48
2000:1:2::0/48
The addresses that should be tried in the reverse lookup are:
fec0::987:X:Y:W:Z1
2837:a:b:987:X:Y:W:Z1
2000:1:2:987:X:Y:W:Z1
9. MULTIHOMED TO MULTIPLE SITES
If a node is multihomed to multiple sites the above scheme can not be
used unless all applications always associate an interface with each
IP address. It is recommended (but not required) that
implementations which operate at site boundaries have such support.
An alternative is to turn off all use of site-local addresses (and
not include them in the name service) on a node that sits at a site
boundary. This will force all traffic to and from that node to use
global addresses (except on those few cases where link-local
addresses are used).
Another alternative would be to configure the site boundaries using
two nodes and an intervening link where the link is not part of any
site. Thus a node at the boundary would have one or more interfaces
that are not part of any site - those interfaces would be connected
to nodes which are part of other sites. Other interfaces on the node
would be part of one site. This would allow the "boundary" node to
use site-local addresses when communicating to one site.
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The algorithm outlined below is able to detect when a node is site
multihomed which can be used to ignore all site-local addresses in
the host name lookup algorithm.
9.1. Detecting site multihoming
A possible algorithm for doing this is as follows:
1) Inspect the Site Prefix List for all interfaces.
2) If an interface has no Site Prefix List entry ignore that
interface.
3) If two or more interfaces have one or more common Site Prefix
List entries group those interfaces together.
4) If the result is more than one group of interfaces the node is
considered to be multihomed to more than one site.
10. SECURITY CONSIDERATIONS
Router Advertisements are not required to be authenticated and even
if they are authenticated it is unclear whether or not there would be
a mechanisms to verify the authority of a particular node to send
Router Advertisements.
Neighbor Discovery uses the rule of HopCount 255 (set to 255 on
transmit and verified to be 255 on reception) to drop any Neighbor
Discovery packets that are sent non-neighboring nodes. This limits
any attack using ND to the neighbors.
Without authentication and authorization this new mechanisms
introduces a new type of denial of service attack. A node on the
link can send a router advertisement listing site prefixes that are
in fact not part of the site. For instance, it could advertise some
other sites prefix as a site prefix. Such an attack would result in
all nodes on the link to fail initiate any new communication with any
node in that site since they would accept the site-local AAAA
records.
Also there is the possibility to return incorrect information for the
reverse lookup of IPv6 addresses. A node on the link can send a
router advertisement listing site prefixes that are in fact not part
of the site. For instance, it could advertise an incorrect site
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INTERNET-DRAFT Site Prefixes in Neighbor Discovery August 1998
prefix (e.g. a:b::0/48) which would make the reverse lookup of the
site local address fec0::X lookup a:b::X.
This could be viewed as allowing some form of indirect spoofing of
the addresses returned by the DNS independent whether or not the DNS
itself is secure. Thus introducing a secure DNS [DNSsec] would not
remove this form of "address spoofing". However, it seems like this
threat is no worse than the other threats in [DISCOVERY] where any
node on the link can intercept all packets sent on the link.
The packets used to discover site prefixes, just like all other
Neighbor Discovery protocol packet exchanges, can be authenticated
using the IP Authentication Header [IPv6-AUTH]. A node SHOULD
include an Authentication Header when sending Neighbor Discovery
packets if a security association for use with the IP Authentication
Header exists for the destination address. The security associations
may have been created through manual configuration or through the
operation of some key management protocol.
Received Authentication Headers in these packets, just like all
Neighbor Discovery packets, MUST be verified for correctness and
packets with incorrect authentication MUST be ignored.
Confidentiality issues are addressed by the IP Security Architecture
and the IP Encapsulating Security Payload documents [IPv6-SA, IPv6-
ESP].
REFERENCES
[KEYWORDS] S. Bradner, "Key words for use in RFCs to Indicate
Requirement Levels", RFC 2119, March 1997.
[IPv6] S. Deering, R. Hinden, Editors, "Internet Protocol, Version
6 (IPv6) Specification", RFC 1883, January 1996.
[ADDR-ARCH] S. Deering, R. Hinden, Editors, "IP Version 6
Addressing Architecture", RFC 1884, January 1996.
[DISCOVERY] T. Narten, E. Nordmark, and W. Simpson, "Neighbor
Discovery for IP Version 6 (IPv6)", RFC 1970, August 1996.
[ADDR-TODAY] B. Carpenter, J. Crowcroft, Y. Rekhter, "IPv4 Address
draft-ietf-ipngwg-site-prefixes-02.txt [Page 17]
INTERNET-DRAFT Site Prefixes in Neighbor Discovery August 1998
Behavior Today", RFC 2101, February 1997.
[GSE-EVAL] M. Crawford, A. Mankin, T. Narten, J. Stewart, L. Zhang,
"IPng Analysis of the GSE Proposal", Internet Draft,
draft-ietf-ipngwg-esd-analysis-02.txt.
[ROUTER-RENUM] M. Crawford, and R. Hinden, "Router Renumbering for
IPv6", Internet Draft, draft-ietf-ipngwg-router-renum-
03.txt.
[ADDRCONF] S. Thomson, T. Narten, "IPv6 Address Autoconfiguration",
RFC 1971, August 1996.
[IPv6-SA] R. Atkinson. "Security Architecture for the Internet
Protocol". RFC 1825, August 1995.
[IPv6-AUTH] R. Atkinson. "IP Authentication Header", RFC 1826,
August 1995.
[IPv6-ESP] R. Atkinson. "IP Encapsulating Security Payload (ESP)",
RFC 1827, August 1995.
[DNSsec] D. Eastlake, C. Kaufman, "Domain Name System Security
Extensions", RFC 2065, January 1997.
[MOBILE-IPv6] D.B. Johnson, C. Perkins, "Mobility Support in IPv6",
Internet Draft, draft-ietf-mobileip-ipv6-06.txt, August
1998.
AUTHOR'S ADDRESS
Erik Nordmark
Sun Microsystems, Inc.
901 San Antonio Road
Palo Alto, CA 94303
USA
phone: +1 650 786 5166
fax: +1 650 786 5896
email: nordmark@sun.com
draft-ietf-ipngwg-site-prefixes-02.txt [Page 18]
INTERNET-DRAFT Site Prefixes in Neighbor Discovery August 1998
APPENDIX A: CHANGES SINCE PREVIOUS DRAFT
The following changes have been made since version 01 of the draft.
o Stated the assumptions on what a "site" is and how it is configured.
o Changed the document to store site-local addresses in the DNS and use
filtering do ignore site-local addresses unless the sender and receiver
can be determined to belong to the same site.
o Added text describing interaction with mobile IP.
o Added rules for ignoring site-local entries from the DNS
o Make "turn off at site boundary" implementation dependent.
o Changed 'S' bit in prefix option not to conflict with [MOBILE-IPv6].
The following changes have been made since version 00 of the draft.
o Removed mention of routing protocols.
o Made the formed site-local addresses replace the global addresses
in the list returned to the application. This change prevents the
"accidental" use of a global address when the application
tries all of the returned
addresses and for whatever reason it could not reach the node when
it tried the site-local address(es).
o Added describing how to the mechanism is automatically disabled on
nodes which are Multihomed to multiple sites.
o Updated list of open issues.
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