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IETF RFC 4285
Authentication Protocol for Mobile IPv6
Last modified on Friday, January 6th, 2006
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Network Working Group A. Patel
Request for Comments: 4285 K. Leung
Category: Informational Cisco Systems
M. Khalil
H. Akhtar
Nortel Networks
K. Chowdhury
Starent Networks
January 2006
Authentication Protocol for Mobile IPv6
Status of this Memo
This memo provides information for the Internet community. It does
not specify an Internet standard of any kind. Distribution of this
memo is unlimited.
Copyright Notice
Copyright © The Internet Society (2006).
IESG Note
This RFC is not a candidate for any level of Internet Standard. RFC
3775 and 3776 define Mobile IPv6 and its security mechanism. This
document presents an alternate security mechanism for Mobile IPv6
used in 3GPP2 networks.
The security properties of this mechanism have not been reviewed in
the IETF. Conducting this review proved difficult because the
standards-track security mechanism for Mobile IPv6 is tightly
integrated into the protocol; extensions to Mobile IPv6 and the core
documents make assumptions about the properties of the security model
without explicitly stating what assumptions are being made. There is
no documented service model. Thus it is difficult to replace the
security mechanism and see if the current protocol and future
extensions meet appropriate security requirements both under the
original and new security mechanisms. If a service model for Mobile
IPv6 security is ever formally defined and reviewed, a mechanism
similar to this one could be produced and fully reviewed.
Section 1.1 of this document provides an applicability statement for
this RFC. The IESG recommends against the usage of this
specification outside of environments that meet the conditions of
that applicability statement. In addition the IESG recommends those
Patel, et al. Informational PAGE 1
RFC 4285 Authentication Protocol for Mobile IPv6 January 2006
considering deploying or implementing this specification conduct a
sufficient security review to meet the conditions of the environments
in which this RFC will be used.
Abstract
IPsec is specified as the means of securing signaling messages
between the Mobile Node and Home Agent for Mobile IPv6 (MIPv6).
MIPv6 signaling messages that are secured include the Binding Updates
and Acknowledgement messages used for managing the bindings between a
Mobile Node and its Home Agent. This document proposes an alternate
method for securing MIPv6 signaling messages between Mobile Nodes and
Home Agents. The alternate method defined here consists of a
MIPv6-specific mobility message authentication option that can be
added to MIPv6 signaling messages.
Table of Contents
1. Introduction ....................................................3
1.1. Applicability Statement ....................................3
2. Overview ........................................................4
3. Terminology .....................................................5
3.1. General Terms ..............................................5
4. Operational Flow ................................................6
5. Mobility Message Authentication Option ..........................7
5.1. MN-HA Mobility Message Authentication Option ...............8
5.1.1. Processing Considerations ...........................9
5.2. MN-AAA Mobility Message Authentication Option ..............9
5.2.1. Processing Considerations ..........................10
5.3. Authentication Failure Detection at the Mobile Node .......11
6. Mobility Message Replay Protection Option ......................11
7. Security Considerations ........................................13
8. IANA Considerations ............................................14
9. Acknowledgements ...............................................15
10. References ....................................................15
10.1. Normative References .....................................15
10.2. Informative References ...................................15
Appendix A. Rationale for mobility message replay protection
option ................................................16
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RFC 4285 Authentication Protocol for Mobile IPv6 January 2006
1. Introduction
The base Mobile IPv6 specification [RFC 3775] specifies the signaling
messages, Binding Update (BU) and Binding Acknowledgement (BA),
between the Mobile Node (MN) and Home Agent (HA) to be secured by the
IPsec Security Associations (IPsec SAs) that are established between
these two entities.
This document proposes a solution for securing the Binding Update and
Binding Acknowledgment messages between the Mobile Node and Home
Agent using a mobility message authentication option that is included
in these messages. Such a mechanism enables IPv6 mobility in a host
without having to establish an IPsec SA with its Home Agent. A
Mobile Node can implement Mobile IPv6 without having to integrate it
with the IPsec module, in which case the Binding Update and Binding
Acknowledgement messages (between MN-HA) are secured with the
mobility message authentication option.
The authentication mechanism proposed here is similar to the
authentication mechanism used in Mobile IPv4 [RFC 3344].
1.1. Applicability Statement
The mobility message authentication option specified in Section 5 is
applicable in certain types of networks that have the following
characteristics:
- Networks in which the authentication of the MN for network access
is done by an authentication server in the home network via the home
agent. The security association is established by the network
operator (provisioning methods) between the MN and a backend
authentication server (e.g., Authentication, Authorization, and
Accounting (AAA) home server). MIPv6 as per RFCs 3775 and 3776
relies on the IPsec SA between the MN and an HA. In cases where the
assignment of the HA is dynamic and the only static or long-term SA
is between the MN and a backend authentication server, the mobility
message authentication option is desirable.
- In certain deployment environments, the mobile node needs dynamic
assignment of a home agent and home address. The assignment of such
can be on a per-session basis or on a per-MN power-up basis. In such
scenarios, the MN relies on an identity such as a Network Access
Identifier (NAI) [RFC 4283], and a security association with a AAA
server to obtain such bootstrapping information. The security
association is created via an out-of-band mechanism or by non Mobile
IPv6 signaling. The out-of-band mechanism can be specific to the
deployment environment of a network operator. In Code Division
Multiple Access (CDMA) network deployments, this information can be
Patel, et al. Informational PAGE 3
RFC 4285 Authentication Protocol for Mobile IPv6 January 2006
obtained at the time of network access authentication via [3GPP2]
specific extensions to PPP or DHCPv6 on the access link and by AAA
extensions in the core. It should be noted that the out-of-band
mechanism is not within the scope of the mobility message
authentication option (Section 5) and hence is not described therein.
- Network deployments in which not all Mobile Nodes and Home Agents
have IKEv2 implementations and support for the integration of IKEv2
with backend AAA infrastructures. IKEv2 as a technology has yet to
reach maturity status and widespread implementations needed for
commercial deployments on a large scale. At the time of this
writing, [RFC 4306] is yet to be published as an RFC. Hence from a
practical perspective that operators face, IKEv2 is not yet capable
of addressing the immediate need for MIPv6 deployment.
- Networks that expressly rely on the backend AAA infrastructure as
the primary means for identifying and authentication/authorizing a
mobile user for MIPv6 service.
- Networks in which the establishment of the security association
between the Mobile Node and the authentication server (AAA Home) is
established using an out-of-band mechanism and not by any key
exchange protocol. Such networks will also rely on out-of-band
mechanisms to renew the security association (between MN and AAA
Home) when needed.
- Networks that are bandwidth constrained (such as cellular wireless
networks) and for which there exists a strong desire to minimize the
number of signaling messages sent over such interfaces. MIPv6
signaling that relies on Internet Key Exchange (IKE) as the primary
means for setting up an SA between the MN and HA requires more
signaling messages compared with the use of an mobility message
authentication option carried in the BU/BA messages.
One such example of networks that have such characteristics are CDMA
networks as defined in [3GPP2].
2. Overview
This document presents a lightweight mechanism to authenticate the
Mobile Node at the Home Agent or at the Authentication,
Authorization, and Accounting (AAA) server in Home network (AAAH)
based on a shared-key-based mobility security association between the
Mobile Node and the respective authenticating entity. This shared-
key-based mobility security association (shared-key-based mobility
SA) may be statically provisioned or dynamically created. The term
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RFC 4285 Authentication Protocol for Mobile IPv6 January 2006
"mobility security association" referred to in this document is
understood to be a "shared-key-based Mobile IPv6 authentication"
security association.
This document introduces new mobility options to aid in
authentication of the Mobile Node to the Home Agent or AAAH server.
The confidentiality protection of Return Routability messages and
authentication/integrity protection of Mobile Prefix Discovery (MPD)
is not provided when these options are used for authentication of the
Mobile Node to the Home Agent. Thus, unless the network can
guarantee such protection (for instance, like in 3GPP2 networks),
Route Optimization and Mobile Prefix Discovery should not be used
when using the mobility message authentication option.
3. Terminology
The keywords "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in RFC 2119.
3.1. General Terms
First (size, input)
Some formulas in this specification use a functional form "First
(size, input)" to indicate truncation of the "input" data so that
only the first "size" bits remain to be used.
Shared-key-based Mobility Security Association
Security relation between the Mobile Node and its Home Agent, used
to authenticate the Mobile Node for mobility service. The
shared-key-based mobility security association between Mobile Node
and Home Agent consists of a mobility Security Parameter Index
(SPI), a shared key, an authentication algorithm, and the replay
protection mechanism in use.
Mobility SPI
A number in the range [0-4294967296] used to index into the
shared-key-based mobility security associations.
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4. Operational Flow
The figure below describes the sequence of messages sent and received
between the MN and HA in the registration process. Binding Update
(BU) and Binding Acknowledgement (BA) messages are used in the
registration process.
MN HA/AAAH
| BU to HA |
(a) |----------------------------------------------------->|
| (including MN-ID option, |
| mobility message replay protection option[optional],|
| mobility message authentication option) |
| |
| HA/AAAH authenticates MN
| |
| |
| BA to MN |
(b) |<-----------------------------------------------------|
| (including MN-ID option, |
| mobility message replay protection option[optional],|
| mobility message authentication option) |
| |
Figure 1: Home Registration with Authentication Protocol
The Mobile Node MUST use the Mobile Node Identifier option,
specifically the MN-NAI mobility option as defined in [RFC 4283] to
identify itself while authenticating with the Home Agent. The Mobile
Node uses the Mobile Node Identifier option as defined in [RFC 4283]
to identify itself as may be required for use with some existing AAA
infrastructure designs.
The Mobile Node MAY use the Message Identifier option as defined in
Section 6 for additional replay protection.
The mobility message authentication option described in Section 5 may
be used by the Mobile Node to transfer authentication data when the
Mobile Node and the Home Agent are utilizing a mobility SPI (a number
in the range [0-4294967296] used to index into the shared-key-based
mobility security associations) to index between multiple mobility
security associations.
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5. Mobility Message Authentication Option
This section defines a mobility message authentication option that
may be used to secure Binding Update and Binding Acknowledgement
messages. This option can be used along with IPsec or preferably as
an alternate mechanism to authenticate Binding Update and Binding
Acknowledgement messages in the absence of IPsec.
This document also defines subtype numbers, which identify the mode
of authentication and the peer entity to authenticate the message.
Two subtype numbers are specified in this document. Other subtypes
may be defined for use in the future.
Only one instance of a mobility message authentication option of a
particular subtype can be present in the message. One message may
contain multiple instances of the mobility message authentication
option with different subtype values. If both MN-HA and MN-AAA
authentication options are present, the MN-HA authentication option
must be present before the MN-AAA authentication option (else, the HA
MUST discard the message).
When a Binding Update or Binding Acknowledgement is received without
a mobility message authentication option and the entity receiving it
is configured to use the mobility message authentication option or
has the shared-key-based mobility security association for the
mobility message authentication option, the entity should silently
discard the received message.
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Option Type | Option Length | Subtype |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Mobility SPI |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Authentication Data ....
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 2: Mobility Message Authentication Option
Option Type:
AUTH-OPTION-TYPE value 9 has been defined by IANA. An 8-bit
identifier of the type mobility option.
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Option Length:
8-bit unsigned integer, representing the length in octets of
the Subtype, mobility Security Parameter Index (SPI) and
Authentication Data fields.
Subtype:
A number assigned to identify the entity and/or mechanism to be
used to authenticate the message.
Mobility SPI:
Mobility Security Parameter Index
Authentication Data:
This field has the information to authenticate the relevant
mobility entity. This protects the message beginning at the
Mobility Header up to and including the mobility SPI field.
Alignment requirements :
The alignment requirement for this option is 4n + 1.
5.1. MN-HA Mobility Message Authentication Option
The format of the MN-HA mobility message authentication option is as
defined in Figure 2. This option uses the subtype value of 1. The
MN-HA mobility message authentication option is used to authenticate
the Binding Update and Binding Acknowledgement messages based on the
shared-key-based security association between the Mobile Node and the
Home Agent.
The shared-key-based mobility security association between Mobile
Node and Home Agent used within this specification consists of a
mobility SPI, a key, an authentication algorithm, and the replay
protection mechanism in use. The mobility SPI is a number in the
range [0-4294967296], where the range [0-255] is reserved. The key
consists of an arbitrary value and is 16 octets in length. The
authentication algorithm is HMAC_SHA1. The replay protection
mechanism may use the Sequence number as specified in [RFC 3775] or
the Timestamp option as defined in Section 6. If the Timestamp
option is used for replay protection, the mobility security
association includes a "close enough" field to account for clock
drift. A default value of 7 seconds SHOULD be used. This value
SHOULD be greater than 3 seconds.
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The MN-HA mobility message authentication option MUST be the last
option in a message with a mobility header if it is the only mobility
message authentication option in the message.
The authentication data is calculated on the message starting from
the mobility header up to and including the mobility SPI value of
this option.
Authentication Data = First (96, HMAC_SHA1(MN-HA Shared key, Mobility
Data))
Mobility Data = care-of address | home address | Mobility Header (MH)
Data
MH Data is the content of the Mobility Header up to and including the
mobility SPI field of this option. The Checksum field in the
Mobility Header MUST be set to 0 to calculate the Mobility Data.
The first 96 bits from the Message Authentication Code (MAC) result
are used as the Authentication Data field.
5.1.1. Processing Considerations
The assumption is that the Mobile Node has a shared-key-based
security association with the Home Agent. The Mobile Node MUST
include this option in a BU if it has a shared-key-based mobility
security association with the Home Agent. The Home Agent MUST
include this option in the BA if it received this option in the
corresponding BU and Home Agent has a shared-key-based mobility
security association with the Mobile Node.
The Mobile Node or Home Agent receiving this option MUST verify the
authentication data in the option. If authentication fails, the Home
Agent MUST send BA with Status Code MIPV6-AUTH-FAIL. If the Home
Agent does not have shared-key-based mobility SA, Home Agent MUST
discard the BU. The Home Agent MAY log such events.
5.2. MN-AAA Mobility Message Authentication Option
The format of the MN-AAA mobility message authentication option is as
defined in Figure 2. This option uses the subtype value of 2. The
MN-AAA authentication mobility option is used to authenticate the
Binding Update message based on the shared mobility security
association between the Mobile Node and AAA server in Home network
(AAAH). It is not used in Binding Acknowledgement messages. The
corresponding Binding Acknowledgement messages must be authenticated
using the MN-HA mobility message authentication option (Section 5.1).
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The MN-AAA mobility message authentication option must be the last
option in a message with a mobility header. The corresponding
response MUST include the MN-HA mobility message authentication
option, and MUST NOT include the MN-AAA mobility message
authentication option.
The Mobile Node MAY use the Mobile Node Identifier option [RFC 4283]
to enable the Home Agent to make use of available AAA infrastructure.
The authentication data is calculated on the message starting from
the mobility header up to and including the mobility SPI value of
this option.
The authentication data shall be calculated as follows:
Authentication data = hash_fn(MN-AAA Shared key, MAC_Mobility Data)
hash_fn() is decided by the value of mobility SPI field in the MN-AAA
mobility message authentication option.
SPI = HMAC_SHA1_SPI:
If mobility SPI has the well-known value HMAC_SHA1_SPI, then
hash_fn() is HMAC_SHA1. When HMAC_SHA1_SPI is used, the BU is
authenticated by AAA using HMAC_SHA1 authentication. In that case,
MAC_Mobility Data is calculated as follows:
MAC_Mobility Data = SHA1(care-of address | home address | MH Data)
MH Data is the content of the Mobility Header up to and including the
mobility SPI field of this option.
5.2.1. Processing Considerations
The use of the MN-AAA mobility message authentication option assumes
that AAA entities at the home site communicate with the HA via an
authenticated channel. Specifically, a BU with the MN-AAA mobility
message authentication option is authenticated via a home AAA server.
The specific details of the interaction between the HA and the AAA
server is beyond the scope of this document.
When the Home Agent receives a Binding Update with the MN-AAA
mobility message authentication option, the Binding Update is
authenticated by an entity external to the Home Agent, typically a
AAA server.
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5.3. Authentication Failure Detection at the Mobile Node
In case of authentication failure, the Home Agent MUST send a Binding
Acknowledgement with status code MIPV6-AUTH-FAIL to the Mobile Node,
if a shared-key-based mobility security association to be used
between Mobile Node and Home Agent for authentication exists. If
there is no shared-key-based mobility security association, HA drops
the Binding Update. HA may log the message for administrative
action.
Upon receiving a Binding Acknowledgement with status code MIPV6-
AUTH-FAIL, the Mobile Node SHOULD stop sending new Binding Updates to
the Home Agent.
6. Mobility Message Replay Protection Option
The Mobility message replay protection option MAY be used in Binding
Update/Binding Acknowledgement messages when authenticated using the
mobility message authentication option as described in Section 5.
The mobility message replay protection option is used to let the Home
Agent verify that a Binding Update has been freshly generated by the
Mobile Node and not replayed by an attacker from some previous
Binding Update. This is especially useful for cases where the Home
Agent does not maintain stateful information about the Mobile Node
after the binding entry has been removed. The Home Agent does the
replay protection check after the Binding Update has been
authenticated. The mobility message replay protection option when
included is used by the Mobile Node for matching BA with BU.
If this mode of replay protection is used, it needs to be part of the
shared-key-based mobility security association.
If the policy at Home Agent mandates replay protection using this
option (as opposed to the sequence number in the Mobility Header in
Binding Update) and the Binding Update from the Mobile Node does not
include this option, the Home Agent discards the BU and sets the
Status Code in BA to MIPV6-MESG-ID-REQD.
When the Home Agent receives the mobility message replay protection
option in Binding Update, it MUST include the mobility message replay
protection option in Binding Acknowledgement. Appendix A provides
details regarding why the mobility message replay protection option
MAY be used when using the authentication option.
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RFC 4285 Authentication Protocol for Mobile IPv6 January 2006
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Option Type | Option Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Timestamp ... |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Timestamp |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 3: Mobility Message Replay Protection Option
Option Type:
MESG-ID-OPTION-TYPE value 10 has been defined by IANA. An
8-bit identifier of the type mobility option.
Option Length:
8-bit unsigned integer, representing the length in octets of
the Timestamp field.
Timestamp:
This field carries the 64 bit timestamp.
Alignment requirements :
The alignment requirement for this option is 8n + 2.
The basic principle of timestamp replay protection is that the node
generating a message inserts the current time of day, and the node
receiving the message checks that this timestamp is sufficiently
close to its own time of day. Unless specified differently in the
shared-key-based mobility security association between the nodes, a
default value of 7 seconds MAY be used to limit the time difference.
This value SHOULD be greater than 3 seconds. The two nodes must have
adequately synchronized time-of-day clocks.
The Mobile Node MUST set the Timestamp field to a 64-bit value
formatted as specified by the Network Time Protocol (NTP) [RFC 1305].
The low-order 32 bits of the NTP format represent fractional seconds,
and those bits that are not available from a time source SHOULD be
generated from a good source of randomness. Note, however, that when
using timestamps, the 64-bit timestamp used in a Binding Update from
the Mobile Node MUST be greater than that used in any previous
successful Binding Update.
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After successful authentication of Binding Update (either locally at
the Home Agent or when a success indication is received from the AAA
server), the Home Agent MUST check the Timestamp field for validity.
In order to be valid, the timestamp contained in the Timestamp field
MUST be close enough to the Home Agent's time-of-day clock and the
timestamp MUST be greater than all previously accepted timestamps for
the requesting Mobile Node.
If the timestamp is valid, the Home Agent copies the entire Timestamp
field into the Timestamp field in the BA it returns to the Mobile
Node. If the timestamp is not valid, the Home Agent copies only the
low-order 32 bits into the BA, and supplies the high-order 32 bits
from its own time of day.
If the Timestamp field is not valid but the authentication of the BU
succeeds, the Home Agent MUST send a Binding Acknowledgement with
status code MIPV6-ID-MISMATCH. The Home Agent does not create a
binding cache entry if the timestamp check fails.
If the Mobile Node receives a Binding Acknowledgement with the code
MIPV6-ID-MISMATCH, the Mobile Node MUST authenticate the BA by
processing the MN-HA authentication mobility option.
If authentication succeeds, the Mobile Node MUST adjust its timestamp
and send subsequent Binding Update using the updated value.
Upon receiving a BA that does not contain the MIPV6-ID-MISMATCH
status code, the Mobile Node MUST compare the Timestamp value in the
BA to the Timestamp value it sent in the corresponding BU. If the
values match, the Mobile Node proceeds to process the MN-HA
authentication data in the BA. If the values do not match, the
Mobile Node silently discards the BA.
7. Security Considerations
This document proposes new mobility message authentication options to
authenticate the control message between Mobile Node, Home Agent,
and/or home AAA (as an alternative to IPsec). The new options
provide for authentication of Binding Update and Binding
Acknowledgement messages. The MN-AAA mobility message authentication
option provide for authentication with AAA infrastructure.
This specification also introduces an optional replay protection
mechanism in Section 6, to prevent replay attacks. The sequence
number field in the Binding Update is not used if this mechanism is
used. This memo defines the timestamp option to be used for mobility
message replay protection.
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8. IANA Considerations
IANA services are required for this specification. The values for
new mobility options and status codes must be assigned from the
Mobile IPv6 [RFC 3775] numbering space.
The values for Mobility Option types AUTH-OPTION-TYPE and MESG-ID-
OPTION-TYPE, as defined in Section 5 and Section 6, have been
assigned. The values are 9 for the AUTH-OPTION-TYPE and 10 for the
MESG-ID-OPTION-TYPE Mobility Option.
The values for status codes MIPV6-ID-MISMATCH, MIPv6-AUTH-FAIL, and
MIPV6-MESG-ID-REQD, as defined in Section 6 and Section 5.3, have
been assigned. The values are 144 for MIPV6-ID-MISMATCH 145 for
MIPV6-MESG-ID-REQD and 146 for MIPV6-AUTH-FAIL.
A new section for enumerating algorithms identified by specific
mobility SPIs within the range 0-255 has to be added to
http://www.iana.org/assignments/mobility-parameters
The currently defined values are as follows:
The value 0 should not be assigned.
The value 3 is reserved for HMAC_SHA1_SPI as defined in Section 5.2.
The value 5 is reserved for use by 3GPP2.
New values for this namespace can be allocated using IETF Consensus.
[RFC 2434].
In addition, IANA has created a new namespace for the Subtype field
of the MN-HA and MN-AAA mobility message authentication options under
http://www.iana.org/assignments/mobility-parameters
The currently allocated values are as follows:
1 MN-HA mobility message authentication option Section 5.1
2 MN-AAA mobility message authentication option Section 5.2
New values for this namespace can be allocated using IETF Consensus.
[RFC 2434].
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9. Acknowledgements
The authors would like to thank Basavaraj Patil, Charlie Perkins,
Vijay Devarapalli, Jari Arkko, and Gopal Dommety, and Avi Lior for
their thorough review and suggestions on the document. The authors
would like to acknowledge the fact that a similar authentication
method was considered in base protocol [RFC 3775] at one time.
10. References
10.1. Normative References
[RFC 4283] Patel, A., Leung, K., Khalil, M., Akhtar, H., and K.
Chowdhury, "Mobile Node Identifier Option for Mobile
IPv6", RFC 4283, November 2005.
[RFC 1305] Mills, D., "Network Time Protocol (Version 3)
Specification, Implementation", RFC 1305, March 1992.
[RFC 2434] Narten, T. and H. Alvestrand, "Guidelines for Writing an
IANA Considerations Section in RFCs", BCP 26, RFC 2434,
October 1998.
[RFC 3344] Perkins, C., "IP Mobility Support for IPv4", RFC 3344,
August 2002.
[RFC 3775] Johnson, D., Perkins, C., and J. Arkko, "Mobility Support
in IPv6", RFC 3775, June 2004.
10.2. Informative References
[3GPP2] "cdma2000 Wireless IP Network Standard", 3GPP2 X.S0011-D,
September 2005.
[RFC 4306] Kaufman, C., Ed., "Internet Key Exchange (IKEv2)
Protocol", RFC 4306, December 2005.
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RFC 4285 Authentication Protocol for Mobile IPv6 January 2006
Appendix A. Rationale for Mobility Message Replay Protection Option
Mobile IPv6 [RFC 3775] defines a Sequence Number in the mobility
header to prevent replay attacks. There are two aspects that stand
out in regards to using the Sequence Number to prevent replay
attacks.
First, the specification states that the Home Agent should accept a
BU with a Sequence Number greater than the Sequence Number from the
previous Binding Update. This implicitly assumes that the Home Agent
has some information regarding the Sequence Number from the previous
BU (even when the binding cache entry is not present). Second, the
specification states that if the Home Agent has no binding cache
entry for the indicated home address, it MUST accept any Sequence
Number value in a received Binding Update from this Mobile Node.
With the mechanism defined in this document, it is possible for the
Mobile Node to register with a different Home Agent during each
mobility session. Thus, it is unreasonable to expect each Home Agent
in the network to maintain state about the Mobile Node. Also, if the
Home Agent does not cache information regarding sequence number, as
per the second point above, a replayed BU can cause a Home Agent to
create a binding cache entry for the Mobile Node. Thus, when
authentication option is used, Sequence Number does not provide
protection against replay attack.
One solution to this problem (when the Home Agent does not save state
information for every Mobile Node) would be for the Home Agent to
reject the first BU and assign a (randomly generated) starting
sequence number for the session and force the Mobile Node to send a
fresh BU with the suggested sequence number. While this would work
in most cases, it would require an additional round trip, and this
extra signaling and latency is not acceptable in certain deployments
[3GPP2]. Also, this rejection and using sequence number as a nonce
in rejection is a new behavior that is not specified in [RFC 3775].
Thus, this specification uses the mobility message replay protection
option to prevent replay attacks. Specifically, timestamps are used
to prevent replay attacks as described in Section 6.
It is important to note that as per Mobile IPv6 [RFC 3775] this
problem with sequence number exists. Since the base specification
mandates the use of IPsec (and naturally that goes with IKE in most
cases), the real replay protection is provided by IPsec/IKE. In case
of BU/BA between Mobile Node and Client Node (CN), the liveness proof
is provided by the use of nonces that the CN generates.
Patel, et al. Informational PAGE 16
RFC 4285 Authentication Protocol for Mobile IPv6 January 2006
Authors' Addresses
Alpesh Patel
Cisco Systems
170 W. Tasman Drive
San Jose, CA 95134
US
Phone: +1 408-853-9580
EMail: alpesh@cisco.com
Kent Leung
Cisco Systems
170 W. Tasman Drive
San Jose, CA 95134
US
Phone: +1 408-526-5030
EMail: kleung@cisco.com
Mohamed Khalil
Nortel Networks
2221 Lakeside Blvd.
Richardson, TX 75082
US
Phone: +1 972-685-0574
EMail: mkhalil@nortel.com
Haseeb Akhtar
Nortel Networks
2221 Lakeside Blvd.
Richardson, TX 75082
US
Phone: +1 972-684-4732
EMail: haseebak@nortel.com
Patel, et al. Informational PAGE 17
RFC 4285 Authentication Protocol for Mobile IPv6 January 2006
Kuntal Chowdhury
Starent Networks
30 International Place
Tewksbury, MA 01876
US
Phone: +1 214 550 1416
EMail: kchowdhury@starentnetworks.com
Patel, et al. Informational PAGE 18
RFC 4285 Authentication Protocol for Mobile IPv6 January 2006
Full Copyright Statement
Copyright © The Internet Society (2006).
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Patel, et al. Informational PAGE 19
Authentication Protocol for Mobile IPv6
RFC TOTAL SIZE: 40874 bytes
PUBLICATION DATE: Friday, January 6th, 2006
LEGAL RIGHTS: The IETF Trust (see BCP 78)
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