EAP WG
Internet-Draft H. Tschofenig
D. Kroeselberg
Siemens
Y. Ohba
Toshiba
F. Bersani
France Telecom R&D
Document: draft-tschofenig-eap-ikev2-06.txt
Expires: November 18, 2005 May 2005
EAP IKEv2 Method
(EAP-IKEv2)
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Copyright (C) The Internet Society (2005).
Abstract
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EAP-IKEv2 is an EAP method which reuses the cryptography and the
payloads of IKEv2, creating a flexible EAP method that supports
both symmetric and asymmetric authentication, as well as a
combination of both. This EAP method offers the security benefits
of IKEv2 authentication and key agreement without the goal of
establishing IPsec security associations.
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Table of Contents
1. Introduction..................................................3
2. IKEv2 and EAP-IKEv2 Overview..................................4
3. Terminology...................................................5
4. Protocol overview.............................................5
5. Identities used in EAP-IKEv2..................................8
6. Packet Format.................................................9
7. Retransmission...............................................11
8. Key derivation...............................................11
9. Error Handling...............................................13
10. Fast Reconnect..............................................14
11. Channel Binding.............................................16
11.1 Channel Binding Procedure in Full Authentication........16
11.2 Channel Binding Procedure in Fast Reconnect.............17
11.3 Channel Binding Error Indication........................17
11.4 Notify Payload Types for Channel Binding................18
11.5 Examples................................................19
12. Security Considerations.....................................23
12.1 General Considerations..................................23
12.2 Security Claims.........................................23
13. Open Issues.................................................25
14. Normative References........................................26
15. Informative References......................................26
Acknowledgments.................................................27
Author's Addresses..............................................27
Intellectual Property Statement.................................28
Disclaimer of Validity..........................................28
Copyright Statement.............................................29
Acknowledgment..................................................29
1. Introduction
This document specifies the EAP-IKEv2 authentication method. The
main design goal for EAP-IKEv2 is to provide a flexible and
efficient EAP method which makes the IKEv2 protocol's features
available for scenarios using EAP-based authentication.
The main advantage of EAP-IKEv2 is that it does not define a new
cryptographic protocol, but re-uses the IKEv2 authentication
exchanges, and thereby provides strong, well-analyzed,
cryptographic properties as well as broad flexibility.
EAP-IKEv2 especially provides an efficient shared-secret method
offering a high security level, and allows for password-derived
shared secrets while protecting from password-guessing attacks.
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EAP-IKEv2 provides mutual authentication between EAP peers. This
may be based on either symmetric methods using pre-shared keys,
or on asymmetric methods based on public/private key pairs,
Certificates and CRLs. It is possible to use different types of
authentication for the different directions, e.g. the server uses
certificate-based authentication whereas the client uses a
symmetric-key method.
IKEv2 supports two-phased authentication schemes by establishing
a server-authenticated secure tunnel and subsequently protecting
an EAP authentication allowing for legacy client authentication
methods. EAP-IKEv2, however, does not support this optional
tunneling feature of IKEv2 in this version, which allows to
increase the EAP-IKEv2 method performance and to decrease
implementation complexity.
A non-goal of EAP-IKEv2 (and basically the major difference to
plain IKEv2) is the establishment of IPsec security associations,
as this would not make much sense in the standard AAA three-party
scenario, consisting of an EAP peer, an authenticator (NAS) and
a back-end authentication server terminating EAP. IPsec SA
establishment may be required locally (i.e., between the EAP peer
and some access server). However, SA establishment within an EAP
method would only provide SAs between the EAP peer and the back-end
authentication server. Other approaches as, e.g., the IETF PANA
framework are considered more appropriate in this case.
2. IKEv2 and EAP-IKEv2 Overview
IKEv2 [Kau04] is a protocol which consists of two exchanges:
(1) an authentication and key exchange protocol which establishes
an IKE-SA.
(2) messages and payloads which focus on the negotiation of
parameters in order to establish IPsec security associations
(i.e., Child-SAs). These payloads contain algorithm parameters
and traffic selector fields.
In addition to the above-mentioned parts IKEv2 also includes some
payloads and messages which allow configuration parameters to be
exchanged primarily for remote access scenarios.
The EAP-IKEv2 method defined by this document uses the IKEv2
payloads and messages used for the initial IKEv2 exchange which
establishes an IKE-SA.
IKEv2 provides an improvement over IKEv1 [RFC2409] as described
in Appendix A of [Kau04]. Important for this document are the
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reduced number of initial exchanges, decreased latency of the
initial exchange, and some other fixes (e.g., hash problem). IKEv2
is a cryptographically sound protocol that has received a
considerable amount of expert review and that benefits from a long
practical experience with IKE.
The goal of EAP-IKEv2 is to inherit these properties within an
efficient, secure EAP method.
In addition, IKEv2 provides authentication and key exchange
capabilities which allow an entity to use symmetric as well as
asymmetric authentication within a single protocol. Such
flexibility is considered important for an EAP method and is
provided by EAP-IKEv2.
[Per03] provides a good tutorial for IKEv2 design decisions.
EAP-IKEv2 provides a secure fragmentation mechanism in which
integrity protection is performed for each fragment of an IKEv2
message.
3. Terminology
This document does not introduce new terms other than those defined
in [RFC3748] or in [Kau04].
The keywords MUST, MUST NOT, REQUIRED, SHALL, SHALL NOT, SHOULD,
SHOULD NOT, RECOMMENDED, MAY, and OPTIONAL, when they appear in
this document, are to be interpreted as described in [RFC2119].
4. Protocol overview
This section provides some overview over EAP-IKEv2 message
exchanges. Note that some mandatory IKEv2 payloads are omitted,
or profiled (such as SAi2 and SAr2), as it is not supported to
establish IPsec (ESP, AH) SAs in EAP-IKEv2.
IKEv2 uses the same protocol message exchanges for both symmetric
and asymmetric authentication. The difference lies only in the
computation of the AUTH payload. See Section 2.15 of [Kau04] for
more information about the details of the AUTH payload
computation. It is even possible to combine symmetric (e.g., from
the client to the server) with asymmetric authentication (e.g.,
from the server to the client) in a single protocol exchange.
Figure 1 depicts such a protocol exchange.
Message exchanges are reused from [Kau04], and are adapted. Since
this document does not describe frameworks or particular
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architectures the message exchange takes place between two parties
- between the Initiator (I) and the Responder (R). In the context
of EAP the Initiator takes the role of the EAP server and the
responder matches the EAP peer.
The first message flow shows the EAP-IKEv2 full successful
exchange. The core EAP-IKEv2 exchange (message (3) - (6)) consists
of four messages (two round trips)_only. The first two messages
constitute the standard EAP identity exchange and are optional;
they are not required in case the EAP server is known. In the
exchange, the EAP server (B) takes the role of the IKEv2 initiator
and the EAP peer (A) acts as the IKEv2 responder.
1) A <-- B: EAP-Request/Identity
2) A --> B: EAP-Response/Identity(Id)
3) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(HDR(A,0), SAi1, KEi, Ni)
4) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SAr1, KEr, Nr, [CERTREQ])
5) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {IDi, [CERT,] [CERTREQ,] [IDr,], AUTH})
6) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {IDr, [CERT,] AUTH})
7) A <-- B: EAP-Success
Figure 1: EAP-IKEv2 successful message flow
Figure 2 shows the message flow in case the EAP peer fails to
authenticate the EAP server.
1) A <-- B: EAP-Request/Identity
2) A --> B: EAP-Response/Identity(Id)
3) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(HDR(A,0), SAi1, KEi, Ni)
4) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SAr1, KEr, Nr, [CERTREQ])
5) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {IDi, [CERT,] [CERTREQ,] [IDr,], AUTH})
6) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
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HDR(A,B), SK {N(AUTHENTICATION_FAILED)})
7) A <-- B: EAP-Failure
Figure 2: EAP-IKEv2 with failed server authentication
Figure 3 shows the message flow in case the EAP server fails to
authenticate the EAP peer. The EAP peer MUST send an empty
EAP-IKEv2 informational message in reply to the EAP server's error
indication. The EAP server answers with an EAP-Failure.
1) A <-- B: EAP-Request/Identity
2) A --> B: EAP-Response/Identity(Id)
3) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(HDR(A,0), SAi1, KEi, Ni)
4) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SAr1, KEr, Nr, [CERTREQ])
5) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {IDi, [CERT,] [CERTREQ,] [IDr,], AUTH})
6) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {IDr, [CERT,] AUTH})
7) A <-- B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {N(AUTHENTICATION_FAILED)})
8) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {})
9) A <-- B: EAP-Failure
Figure 3: EAP-IKEv2 with failed client authentication
Since the goal of this EAP method is not to establish an IPsec SA
some payloads used in IKEv2 are omitted. In particularly the
following messages and payloads SHOULD not be sent:
- Traffic Selector (TS) payloads
- SA payloads that carry SA proposals for protocol IDs other than
1(IKE), i.e., SA payloads with protocol ID 2 (ESP) or 3 (AH)
- ESN (extended sequence number) transforms
Some of these messages and payloads are optional in IKEv2.
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In general it does not make sense to directly negotiate IPsec SAs
within EAP-IKEv2, as such SAs are not required between the EAP
endpoints and as SAs cannot be transferred to different AAA
entities by standard AAA protocols.
Consequently, mechanisms and payloads that are not supported by
EAP-IKEv2 are:
- ECN Notifications as specified in section 2.24 of [Kau04].
- IKE-specific port handling
- NAT traversal
Since the EAP server acts as the initiator of the initial IKEv2
exchange, a number of optional payloads used for realizing
specific features in IKEv2 are not supported by EAP-IKEv2, as they
are intended for the client side (e.g. for corporate access
scenarios) in plain IKEv2. These payloads MUST not be sent by an
EAP-IKEv2 entity. EAP-IKEv2 entities receiving such payloads MUST
respond with the appropriate error messages as defined in [Kau04].
These payloads are:
- Configuration (CFG) payloads as specified in 3.15 of [Kau04].
These payloads MUST not be sent by an EAP-IKEv2 implementation.
EAP-IKEv2 entities receiving such payloads MUST ignore
configuration payloads as described for minimal implementations
in 3.15 of [Kau04].
- EAP payloads as specified in section 3.16 of [Kau04]. These
payloads allow to run an inner EAP exchange for secure legacy
authentication through an IKE SA. EAP-IKEv2 implementations
acting as initiator MUST include and AUTH payload in the initial
IKE_AUTH message (message 3 of the initial IKE exchange).
EAP-IKEv2 implementations receiving initial IKE_AUTH messages as
responders that indicate the initiator's desire to start extended
authentication MUST be answered with an AUTHENTICATION_FAILED
notification as the response.
IKEv2 provides optional functionality for additional DoS
protection by adding a roundtrip to the initial exchanges, see
section 2.xx of [Kau04]. As this is intended to protect the IKEv2
responder but in EAP-IKEv2 the EAP server takes the role of the
initiator, it is not recommended to use this feature of IKEv2 for
server protection.
5. Identities used in EAP-IKEv2
A number of different places allow to convey identity information
in IKEv2, when combined with EAP. This section describes their
function within the different exchanges of EAP-IKEv2. Note that
EAP-IKEv2 does not introduce more identities than other
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non-tunneling EAP methods. Figure 4 shows which identities are
used during the individual phases of the protocol.
+-------+ +-------------+ +---------+
|Client | |Front-End | |AAA |
| | |Authenticator| |Server |
+-------+ +-------------+ +---------+
EAP/Identity-Request
<---------------------
(a) EAP/Identity-Response
---------------------------------->
Tunnel-Establishment
(b) (Identities of IKEv2 are used)
Server (Network) Authentication
<----------------------------------
...
---------------------------------->
Figure 4: Identities used in EAP-IKEv2
a) The first part of the (outer) EAP message exchange provides
information about the identities of the EAP endpoints. This
message exchange mainly is an identity request/response. This
exchange is optional if the EAP server is known already or can be
learned by other means.
b) Identities exchanged within EAP-IKEv2 for both the initiator
and the responder. The initiator identity is often associated with
a user identity such as a fully-qualified RFC 822 email address.
The identity of the responder might be a FQDN. The identity is of
importance for authorization.
For carrying identities in EAP-IKEv2, implementations MUST follow
the rules given in [Kau04], section 3.5, i.e., MUST be configurable
to send at least one of ID_IPV4_ADDR, ID_FQDN, ID_RFC822_ADDR, or
ID_KEY_ID, and MUST be configurable to accept all of these types.
Implementations SHOULD be capable of generating and accepting all
of these types.
6. Packet Format
The IKEv2 payloads, which are defined in [Kau04], are embedded into
the Data field of the standard EAP Request/Response packets. The
Code, Identifier, Length and Type field is described in [RFC3748].
The Type-Data field carries a one byte Flags field following the
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IKEv2 payloads. Each IKEv2 payload starts with a header field HDR
(see [Kau04]).
The packet format is shown in Figure 5.
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Code | Identifier | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Type | Flags | Message Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Message Length | Data ... ~
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Integrity Checksum Data |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 5: Packet Format
No additional packet formats other than those defined in [Kau04]
are required for this EAP method.
The Flags field is used for fragmentation support. The S and F bits
are reserved for future use.
Currently five bits of the eight bit flags field are defined. The
remaining bits are set to zero.
0 1 2 3 4 5 6 7
+-+-+-+-+-+-+-+-+
|S F L M I 0 0 0|
+-+-+-+-+-+-+-+-+
S = (reserved)
F = (reserved)
L = Length included
M = More fragments
I = Integrity Checksum Data included
EAP-IKEv2 messages which have neither the S nor the F flag set
contain regular IKEv2 message payloads inside the Data field.
With regard to fragmentation we follow the suggestions and
descriptions given in Section 2.8 of [PS+03]: The L indicates that
a length field is present and the M flag indicates fragments. The
L flag MUST be set for the first fragment and the M flag MUST be
set on all fragments expect for the last one. Each fragment sent
must subsequently be acknowledged.
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The Message Length field is four octets long and present only if
the L bit is set. This field provides the total message length that
is being fragmented (i.e., the length of the Data field.).
The Integrity Checksum Data is the cryptographic checksum of the
entire EAP message starting with the Code field through the Data
field. This field presents only if the I bit is set. The field
immediately follows the Data field without adding any padding
octet before or after itself. The checksum MUST be computed for
each fragment (including the case where the entire IKEv2 message
is carried in a single fragment) by using the same key (i.e., SK_ai
or SK_ar) that is used for computing the checksum for the IKEv2
Encrypted payload in the encapsulated IKEv2 message. The
Integrity Checksum Data field is omitted for other packets. To
minimize DoS attacks on fragmented packets, messages that are
not protected SHOULD NOT be fragmented. Note that IKE_SA_INIT
messages are the only ones that are not encrypted or integrity
protected, however, such messages are not likely to be fragmented
since they do not carry certificates.
The EAP Type for this EAP method is <TBD>.
7. Retransmission
Since EAP authenticators support a timer-based retransmission
mechanism for EAP Requests and EAP peers retransmit the last valid
EAP Response when receiving a duplicate EAP Request message, IKEv2
messages MUST NOT be retransmitted based on timers, when used as
EAP authentication method.
8. Key derivation
The EAP-IKEv2 method described in this document generates session
keys. On the one hand, these session keys are used within the
IKE-SA, for protection of EAP-IKEv2 payloads, e.g., AUTH exchanges
or notifications. On the other hand, additional keys are derived
to be exported as part of the EAP keying framework [AS+05] (i.e.,
MSK, EMSK and IV). It is good cryptographic security practice to
use different keys for different "applications". Hence we suggest
reusing of the key derivation function suggested in Section 2.17
of [Kau04] to create keying material KEYMAT.
The key derivation function defined is KEYMAT = prf+(SK_d, Ni |
Nr), where Ni and Nr are the Nonces from the IKE_SA_INIT exchange.
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Since the required amount of keying material is greater than the
size of the output of the prf algorithm the prf is used iteratively.
Section 2.13 of [Kau04] describes this mechanism in detail.
According to [AS+05] the keying material of MSK, EMSK and IV have
to be at minimum 64, 64 and 64 octets long.
The produced keying material for MSK, EMSK and IV MUST be at least
the minimum size (i.e., 64 octets). The keying material KEYMAT
is split into the MSK, EMSK and IV part.
Figure 6 describes the keying hierarchy of EAP-IKEv2 graphically.
This figure is adopted from Figure 2 of [AS+05].
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-++ ---+
| | ^
| EAP-IKEv2 Method | |
| +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-++ +------------------+ | |
| | EAP-IKEv2 Diffie-Hellmann | | EAP-IKEv2 prot. | | |
| | derived and authenticated key | | session specific | | |
| | SK_d | | state (Nonce i,j)| | |
| +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-++ +-------------+----+ | |
| | | | Local |
| | | | to EAP |
| | | | Method |
| | | | |
| | | | |
| | | | |
| | | | |
| +---------------+-------------+ | | |
| | | | | | |
| +-+-+-+-+-++ +-+-+-+-+-++ +-+-+-+-+-++ | |
| | MSK | |EMSK | | IV | | |
| |Derivation| |Derivation| |Derivation| | |
| +-+-+-+-+-++ +-+-+-+-+-++ +-+-+-+-+-++ | |
| | | | | V
+-+-+-+-+-+-+-+-+-+-+-+-+-+--+-+-++-+-+-+-+-------+-+-+----+ ---+
| | | ^
|MSK |EMSK |IV |
| | | |
| | | Exported |
| | | by EAP |
V V V Method |
+-+-+-+-+-+-+-+-+-+-+-+-+ +-+-+-+-+-+-+-+ |
| AAA Key Derivation | | Known | |
| Naming & Binding | |(Not Secret) | |
+-+-+-+-+-+-+-+-+-+-+-+-+ +-+-+-+-+-+-+-+ V
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Legend:
MSK = Master Session Key (512 Bit)
EMSK = Extended Master Session Key (512 Bit)
SK_d = Session key derived by EAP-IKEv2
IV = Initialization Vector
Figure 6: EAP-IKEv2 Keying Hierarchy
9. Error Handling
As described in the IKEv2 specification, there are many kinds of
errors that can occur during IKE processing (i.e., processing the
Data field of EAP-IKEv2 Request and Response messages) and
detailed processing rules. EAP-IKEv2 follows the error handling
rules specified in the IKEv2 specification for errors on the Data
field of EAP-IKEv2 messages, with the following additional rules:
For an IKEv2 error that triggers an initiation of an IKEv2 exchange
(i.e., an INFORMATIONAL exchange), an EAP-IKEv2 message that
contains the IKEv2 request that is generated for the IKEv2 exchange
MUST be sent to the peering entity. In this case, the EAP message
that caused the IKEv2 error MUST be treated as a valid EAP message.
For an IKEv2 error for which the IKEv2 message that caused the error
is discarded without triggering an initiation of an IKEv2
exchange, the EAP message that carries the erroneous IKEv2 message
MUST be treated as an invalid EAP message and discarded as if it
were not received at EAP layer.
For an error occurred outside the Data field of EAP-IKEv2 messages,
including defragmentation failures, integrity check failures,
errors in Flag and Message Length fields, the EAP message that
caused the error MUST be treated as an invalid EAP message and
discarded as if it were not received at EAP layer.
When the EAP-IKEv2 method runs on a backend EAP server, an
outstanding EAP Request is not retransmitted based on timer and
thus there is a possibility of EAP conversation stall when the EAP
server receives an invalid EAP Response. To avoid this, the EAP
server MAY retransmit the outstanding EAP Request in response to
an invalid EAP Response. Alternatively, the EAP server MAY send
a new EAP Request in response to an invalid EAP Response with
assigning a new Identifier and putting the last transmitted IKEv2
message in the Data field.
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10. Fast Reconnect
EAP-IKEv2 supports fast reconnect, i.e., a successful reconnect
exchange creates a new IKE-SA by using an IKE CHILD_SA exchange.
The purpose of a re-authentication exchange is to allow for
efficient re-keying based on the existing IKE-SA in situations
where (depending on the given security policy) no full
authentication is required in case of an existing EAP-IKEv2
security context.
The fast reconnect exchange uses the IKE-SA rekeying as specified
in section 2.18 of [Kau04]. However, the exchanges for EAP-IKEv2
do not use rekeying payloads other than IKE SAs:
- The TS (traffic selector) payloads SHOULD not be sent by
EAP-IKEv2 implementations.
- The [N] payload (REKEY_SA notification) SHOULD not be sent by
EAP-IKEv2 implementations.
During fast re-authentication, the new IKE_SA is computed as
specified in [Kau04], section 2.18. The new keying material
derived from this IKE_SA is computed as in an initial EAP-IKEv2
authentication exchange.
Fast re-authentication allows for an optional new Diffie-Hellman
exchange.
The following exchange provides fast reconnect for EAP-IKEv2,
where A is the EAP peer (IKE responder) and B is the EAP server
(IKE initiator):
1) A <-- B: EAP-Request/Identity
2) A --> B: EAP-Response/Identity(Id)
3) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(
HDR, SK {SA, Ni, [KEi]})
4) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR, SK {SA, Nr, [KEr]})
5) A <-- B: EAP-Success
Figure 7: Fast Reconnect Message Flow
The first two messages constitute the standard EAP identity
exchange and are optional; they are not required in case the EAP
server is known.
Figure 8 shows the fast reconnect message flow in case the EAP peer
fails to re-authenticate the EAP server.
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1) A <-- B: EAP-Request/Identity
2) A --> B: EAP-Response/Identity(Id)
3) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2
(HDR, SK {SA, Ni, [KEi]})
4) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR, SK {N(AUTHENTICATION_FAILED)})
5) A <-- B: EAP-Failure
Figure 8: EAP-IKEv2 fast reconnect
(server authentication failed)
Figure 9 shows the fast reconnect message flow in case the EAP
server fails to re-authenticate the EAP peer. The EAP peer MUST
send an empty EAP-IKEv2 informational message in reply to the EAP
server's error indication. The EAP server answers with an
EAP-Failure.
1) A <-- B: EAP-Request/Identity
2) A --> B: EAP-Response/Identity(Id)
3) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(
HDR, SK {SA, Ni, [KEi]})
4) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR, SK {SA, Nr, [KEr]})
5) A <-- B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {N(AUTHENTICATION_FAILED)})
6) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {})
7) A <-- B: EAP-Failure
Figure 9: EAP-IKEv2 fast reconnect
(client authentication failed)
IKE_SAs do not have lifetimes. Such lifetimes are therefore set
by local policies of the peers. Typically the peer setting the
shorter lifetime will therefore trigger the reconnect procedure.
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Note: IKEv2 supports fast rekeying to be initiated by both peers.
In EAP-IKEv2, the EAP server initiates the rekeying as this results
in the most efficient message flow. If the client initiates fast
rekeying, it needs to indicate this to the network by appropriate
out-of-band (e.g. link-layer) means.
11. Channel Binding
EAP-IKEv2 provides a channel binding functionality [RFC3784] in
order for the EAP peer and EAP server to make sure that the both
entities are given the same network access attributes such as
Calling-Station-Id, Called-Station-Id, and NAS-Port-Type by the
NAS. This is achieved by using Notify payloads to exchange
attribute data between the EAP peer and EAP server.
A Notify payload that carries a null channel binding attribute is
referred to as a channel binding request. A Notify payload which
contains a non-null channel binding attribute and is sent in
response to a channel binding request is referred to as a channel
binding response. A pair of channel binding request and channel
binding response constitutes a channel binding exchange. A
distinct Notify payload type is used for a particular type of
channel binding attribute, which is referred to as a channel
binding attribute type. It is allowed to carry multiple channel
binding requests and/or responses with different channel binding
attribute types in a single IKEv2 message. A set of channel binding
exchanges performed in a single round of EAP-IKEv2 full
authentication or fast reconnect is referred to as a channel
binding procedure.
A Notify payload that is used for reporting an error occurred
during a channel binding exchange is referred to as a channel
binding error indication.
EAP-IKEv2 offers a protected result indication mechanism (see
section 12.2). To receive protected result indication, the EAP
server MUST initiate a channel binding exchange as specified in
Figure 10, message 5. As a result of this channel binding exchange,
the client will receive a protected result indication, because the
server will initiate an informational exchange as part of the
channel binding procedure (messages 7 and 8) through the new IKE-SA
that results from a successful reconnect procedure.
11.1 Channel Binding Procedure in Full Authentication
In the case of EAP-IKEv2 full authentication procedure, the
channel binding procedure is performed in the following way.
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The EAP peer MAY include one or more channel binding request in
an IKE_SA_INIT response. The EAP server MAY include one or more
channel binding request in an IKE_AUTH request. When the EAP server
receives an IKE_SA_INIT response with one or more channel binding
request, it MUST include the corresponding channel binding
response(s) an IKE_AUTH request (in addition to its channel
binding request(s) if any). When the EAP peer receives an IKE_AUTH
request with one or more channel binding request, it MUST include
the corresponding channel binding response(s) in an IKE_AUTH
response.
When the EAP server successfully validates all the channel binding
response(s) sent by the EAP server, it initiates an INFORMATIONAL
exchange, where an empty payload is used in both INFORMATIONAL
request and INFORMATIONAL response. This exchange serves as a
protected success indication. After completion of this
INFORMATIONAL exchange, the EAP server sends Success message.
11.2 Channel Binding Procedure in Fast Reconnect
In the case of EAP-IKEv2 fast reconnect, the channel binding
procedure is performed in the following way.
In the pair of CREATE_CHILD_SA exchange, the EAP peer and/or the
EAP server MAY include one or more channel binding request, one
for each channel binding attribute that needs validation. When
the EAP peer receives a CREATE_CHILD_SA request with containing
one or more channel binding request, it MUST contain channel
binding response(s) in the CREATE_CHILD_SA response, as well as
its channel binding request(s) if any. This piggybacking is
possible because the CREATE_CHILD_SA exchange is protected with
the old IKE_SA. When the EAP server receives a CREATE_CHILD_SA
response, if it has one or more channel binding response to send
to the EAP peer, it initiates an INFORMATIONAL exchange
immediately after completion of the CREATE_CHILD_SA exchange,
where one or more channel binding response is carried in the
INFORMATIONAL request. If the EAP peer successfully validates the
channel binding response(s), it MUST respond with an empty
INFORMATIONAL response. This exchange serves as a protected
success indication. After completion of this INFORMATIONAL
exchange, the EAP server sends Success message.
11.3 Channel Binding Error Indication
A channel binding error is detected by the EAP peer or EAP server
when (i) a channel binding response is not contained in the
expected IKEv2 message or (ii) a channel binding response is
contained in the expected IKEv2 message but the channel binding
attribute does not have the expected value. Whenever a channel
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binding error is detected, the detecting entity MUST send a channel
binding error indication to its peering entity. In case of (ii),
the channel binding error indication MUST contain the channel
binding attribute that caused the error.
When the EAP server detects a channel binding error, a channel
binding error indication MUST be carried in an INFORMATIONAL
request, and the EAP peer MUST respond with an empty INFORMATIONAL
response.
When the EAP peer detects a channel binding error, a channel
binding error indication MUST be carried in an IKEv2 error
reporting message for which the R-flag of the IKEv2 header MUST
be set. The EAP server MUST respond with EAP-Failure message when
it receives such a channel binding error indication.
11.4 Notify Payload Types for Channel Binding
The following Notify Payload types are defined for the purpose of
channel binding exchange.
CALLING_STATION_ID TBD
The payload data in a channel binding response of this type
contains octet string representation of
Calling-Station-Id value known to the EAP server by using
an external mechanism.
CALLED_STATION_ID TBD
The payload data in a channel binding response of this type
contains octet string representation of Called-Station-Id
value known to the EAP peer by using an external mechanism.
NAS_PORT_TYPE TBD
The payload data in a channel binding response of this type
contains 4-octet unsigned integer value of NAS-Port-Type
known to the EAP peer by using an external mechanism.
The following Notify Payload types are defined for the purpose of
reporting when there is an error in a channel binding exchange.
INVALID_CALLING_STATION_ID TBD
The payload data (if non-null) contains octet string
representation of Calling-Station-Id value that caused the
error.
INVALID_CALLED_STATION_ID TBD
The payload data (if non-null) contains octet string
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representation of Called-Station-Id value that caused the
error.
INVALID_NAS_PORT_TYPE TBD
The payload data (if non-null) contains 4-octet unsigned
integer value of NAS-Port-Type that caused the error.
Table 1 shows the entity that is allowed to send a channel binding
request for each channel binding attribute type.
channel binding The entity that is allowed to send
attribute type channel binding request
----------------------+---------------------------------------
CALLING_STATION_ID EAP server
CALLED_STATION_ID EAP peer
NAS_PORT_TYPE EAP server
Table 1: Channel Binding Attribute Types and Requesting
Entities
11.5 Examples
In the figures of this section, a Notify payload tagged with '*'
indicates a Notify payload with null data (i.e., a channel binding
request). a Notify payload no tagged with '*' indicates a Notify
payload with non-null data (i.e., a channel binding response).
Figure 10 shows an example of EAP-IKEv2 authentication sequence
with a successful channel binding procedure. The first two
messages constitute the standard EAP identity exchange and are
optional.
1) A <-- B: EAP-Request/Identity
2) A --> B: EAP-Response/Identity(Id)
3) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(HDR(A,0), SAi1, KEi, Ni)
4) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SAr1, KEr, Nr, [CERTREQ,]
N(CALLED_STATION_ID*))
5) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {IDi, [CERT,] [CERTREQ,] [IDr,], AUTH,
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N(CALLED_STATION_ID),
N(CALLING_STATION_ID*),
N(NAS_PORT_TYPE*)})
6) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {IDr, [CERT,] AUTH,
N(CALLING_STATION_ID),
N(NAS_PORT_TYPE)})
7) A <-- B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {})
8) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {})
9) A <-- B: EAP-Success
Figure 10: EAP-IKEv2 with successful channel binding
Figure 11 shows an example of EAP-IKEv2 authentication sequence
when the EAP server detects an error in a channel binding
procedure. The first two messages constitute the standard EAP
identity exchange and are optional. In this case, message 7) and
8) MUST constitute an INFORMATIONAL exchange.
1) A <-- B: EAP-Request/Identity
2) A --> B: EAP-Response/Identity(Id)
3) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(HDR(A,0), SAi1, KEi, Ni)
4) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SAr1, KEr, Nr, [CERTREQ,]
N(CALLED_STATION_ID*))
5) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {IDi, [CERT,] [CERTREQ,] [IDr,], AUTH,
N(CALLED_STATION_ID),
N(CALLING_STATION_ID*),
N(NAS_PORT_TYPE*)})
6) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {IDr, [CERT,] AUTH,
N(CALLING_STATION_ID),
N(NAS_PORT_TYPE)})
7) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {N(INVALID_CALLING_STATION_ID)})
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8) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {})
9) A <-- B: EAP-Failure
Figure 11: EAP-IKEv2 with channel binding error
(detected by EAP server)
Figure 12 shows an example of EAP-IKEv2 authentication sequence
when the EAP peer detects an error in a channel binding procedure.
The first two messages constitute the standard EAP identity
exchange and are optional.
1) A <-- B: EAP-Request/Identity
2) A --> B: EAP-Response/Identity(Id)
3) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(HDR(A,0), SAi1, KEi, Ni)
4) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SAr1, KEr, Nr, [CERTREQ,]
N(CALLED_STATION_ID*))
5) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {IDi, [CERT,] [CERTREQ,] [IDr,], AUTH,
N(CALLED_STATION_ID),
N(CALLING_STATION_ID*),
N(NAS_PORT_TYPE*)})
6) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {N(INVALID_CALLED_STATION_ID)})
7) A <-- B: EAP-Failure
Figure 12: EAP-IKEv2 with channel binding error
(detected by EAP peer)
Figure 13 shows an example of EAP-IKEv2 fast reconnection sequence
with a successful channel binding procedure. The first two
messages constitute the standard EAP identity exchange and are
optional.
1) A <-- B: EAP-Request/Identity
2) A --> B: EAP-Response/Identity(Id)
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3) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(HDR, SK {SA, Ni, [KEi,]
N(CALLING_STATION_ID*),
N(NAS_PORT_TYPE*)})
4) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(HDR, SK {SA, Nr, [KEr,]
N(CALLED_STATION_ID*),
N(CALLING_STATION_ID),
N(NAS_PORT_TYPE)})
5) A <-- B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {N(CALLED_STATION_ID)})
6) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(HDR(A,B), SK {})
7) A <-- B: EAP-Success
Figure 13: Fast reconnect with channel binding error
(fast reconnect)
Figure 14 shows an example of EAP-IKEv2 fast reconnect sequence
when the EAP server detects an error in a channel binding
procedure. The first two messages constitute the standard EAP
identity exchange and are optional. In this case, message 7) and
8) MUST constitute an INFORMATIONAL exchange.
1) A <-- B: EAP-Request/Identity
2) A --> B: EAP-Response/Identity(Id)
3) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(HDR, SK {SA, Ni, [KEi,]
N(CALLING_STATION_ID*),
N(NAS_PORT_TYPE*)})
4) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(HDR, SK {SA, Nr, [KEr,]
N(CALLED_STATION_ID*),
N(CALLING_STATION_ID),
N(NAS_PORT_TYPE)})
5) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {N(INVALID_CALLING_STATION_ID)})
6) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {})
7) A <-- B: EAP-Failure
Figure 14: Fast reconnect with channel binding error
(detected by EAP server)
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Figure 15 shows an example of EAP-IKEv2 fast reconnect sequence
when the EAP peer detects an error in a channel binding procedure.
The first two messages constitute the standard EAP identity
exchange and are optional.
1) A <-- B: EAP-Request/Identity
2) A --> B: EAP-Response/Identity(Id)
3) A <-- B: EAP-Request/EAP-Type=EAP-IKEv2(HDR, SK {SA, Ni, [KEi,]
N(CALLING_STATION_ID*),
N(NAS_PORT_TYPE*)})
4) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(HDR, SK {SA, Nr, [KEr,]
N(CALLED_STATION_ID*),
N(CALLING_STATION_ID),
N(NAS_PORT_TYPE)})
5) A <-- B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {N(CALLED_STATION_ID)})
6) A --> B: EAP-Response/EAP-Type=EAP-IKEv2(
HDR(A,B), SK {N(INVALID_CALLED_STATION_ID)})
7) A <-- B: EAP-Failure
Figure 15: Fast reconnect with channel binding error
(detected by EAP peer)
12. Security Considerations
12.1 General Considerations
The security of the proposed EAP method is intentionally based on
IKEv2 [Kau04]. Therefore, the security claims of EAP-IKEv2 are
derived from the security offered by the supported features of
IKEv2.
12.2 Security Claims
Authentication mechanism:
Mutual authentication is supported based on either pre-shared
symmetric keys or public/private key pairs. Besides certificates,
plain public keys can be used. It is possible to use different types
of authentication for the different directions within one
authentication exchange. An example is the server using
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certificate-based authentication and the client using pre-shared
secrets.
Password-based authentication should only be used in IKEv2 with
extended authentication (EAP tunneling), which is not supported
by this version of EAP-IKEv2. Without extended authentication, the
use of passwords (i.e., password-derived shared secrets) is
discouraged for IKEv2.
In contrast, EAP-IKEv2 changes the roles regarding password usage:
The EAP server acts as initiator, the remote peer as responder.
This results in an exchange which protects user authentication
(based on a shared secret derived from a user password) to the
network through an already network (initiator-) authenticated,
secured IKEv2 SA (see e.g. message 6 of Figure 1). This prevents
an attacker from launching password-guessing attacks on the
peer-generated AUTH value.
Therefore, dictionary attacks are not applicable in the context
of EAP-IKEv2 in the case the EAP peer uses a password-derived
shared secret.
Man-in-the-middle attacks discovered in the context of tunneled
authentication protocols (see [AN03] and [PL+03]) are not
applicable to EAP-IKEv2 as the extended authentication feature of
IKEv2 is not supported. Hence, the cryptographic binding claim is
not applicable.
Ciphersuite negotiation is supported as specified in IKEv2 for
IKE-SAs. The negotiation for IPsec (Child) SAs is not supported,
as such SAs are not generated by EAP-IKEv2.
Protected result indication as described in section 7.16 of
[RFC3748] is optionally provided by EAP-IKEv2. In message 5 of
figure 1 (full successful authentication) the EAP server
authenticates to the client. Message 6 authenticates the client
to the server, and the client by authenticating the server and by
sending message 6 expresses that it is willing to accept access.
The client, however, does not get a protected result indication
from the server in this case. An attacker could potentially forge
an EAP success/failure message which could result in DoS to the
client. In some situations, synchronization may be achieved by
lower layer indications.
Protected result indication is optionally provided as specified
in section 11.
If this mechanism is not used, the recommended behavior for the
client is to assume the correct establishment of a new IKE-SA after
sending message 6, independent of the receipt of an EAP
success/failure. In case of unsuccessful authentication, the
server would answer with an IKEv2 notification (which, in case of
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the fast reconnect exchange, would be protected by the old IKE-SA).
In case of a lost message 6, the server would retransmit message
5, indicating the message loss to the client.
The client implementation can minimize potential DoS risks due to
missing protected result indications by assuming the correct
establishment of a new IKE-SA after not receiving one of the above
messages within a certain time window after sending message 6. In
the fast reconnect case, the client needs to hold both the old and
the new IKE-SA in parallel during this time window.
Session independence is optionally provided if the fast reconnect
exchange includes the KE payloads (new Diffie-Hellman) as
described in section 10, Figure 7.
Security claims:
Ciphersuite negotiation: Yes
Mutual authentication: Yes
Integrity protection: Yes
Replay protection: Yes
Confidentiality: Yes
Key derivation: Yes
Key strength: Variable
Dictionary attack prot.: Yes
Fast reconnect: Yes
Crypt. binding: N/A
Protected result ind.: yes
Session independence: yes
Fragmentation: Yes
Channel binding: Yes
13. Open Issues
The following issues are still under consideration:
- Notifications
IKEv2 provides the concept of notifications to exchange messages
at any time (e.g., dead peer detection). It remains for further
study which of these messages are required for this EAP method.
- supported identities
Can the NAI be carried by the RFC822 ID type of IKEv2? Are there
other formats to be supported? Additional profiling may be
required in section 5.
- tunneled method
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To reduce the method's complexity, EAP tunneling through EAP-IKEv2
that is in principal possible with IKEv2 is not supported. If
tunneling support is, however, required (e.g. for sequencing), it
is possible to develop an EAP-IKEv2-tunneled method from the
present one. The major change would be to reverse the roles of IKEv2
initiator and responder, as the initiator is EAP-authenticated in
the tunneled case.
It is not considered a good approach by the authors to have both
the tunneled and the non-tunneled method in a single
specification, as this would result in a rather complex method
description. The tunneled-method EAP-IKEv2 specification, if
required, will therefore come with a separate document.
14. Normative References
[RFC3748] Aboba, Blunk, Carlson and Levkowetz: "Extensible
Authentication Protocol (EAP)", RFC 3748, June 2004.
[Kau04] C. Kaufman: "Internet Key Exchange (IKEv2) Protocol",
internet draft, Internet Engineering Task Force, September 2004.
Work in progress.
[RFC2119] S. Bradner: "Key words for use in RFCs to Indicate
Requirement Levels", RFC 2119, Internet Engineering Task Force,
March 1997.
15. Informative References
[AN03] N. Asokan, V. Niemi, and K. Nyberg: "Man-in-the-middle in
tunnelled authentication", In the Proceedings of the 11th
International Workshop on Security Protocols, Cambridge, UK,
April 2003. To be published in the Springer-Verlag LNCS series.
[PL+03] J. Puthenkulam, V. Lortz, A. Palekar, D. Simon, and B.
Aboba, "The compound authentication binding problem," internet
draft, Internet Engineering Task Force, October 2003. Expired.
[RFC2409] D. Harkins, D. Carrel: "The Internet Key Exchange
(IKE)", RFC 2409, November 1998.
[Per03] R. Perlman: "Understanding IKEv2: Tutorial, and rationale
for decisions", internet draft, Internet Engineering Task Force,
2003. Expired.
[AS+05] B. Aboba, D. Simon, J. Arkko, P. Eronen and H. Levkowetz:
"Extensible Authentication Protocol (EAP) Key Management
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Framework", internet draft, Internet Engineering Task Force,
April, 2005. Work in progress.
[PS+03] A. Palekar, D. Simon, G. Zorn, H. Zhou and S. Josefsson:
"Protected EAP Protocol (PEAP)", internet draft, Internet
Engineering Task Force, July 2004. Work in progress.
Acknowledgments
We would like to thank Bernard Aboba, Jari Arkko, Guenther Horn,
Paoulo Pagliusi and John Vollbrecht for their comments to this
draft.
Additionally we would like to thank members of the PANA design team
(namely D. Forsberg and A. Yegin) for their comments and input to
the initial version of the draft.
Finally we would like to thank the members of the EAP keying design
team for their discussion in the area of the EAP Key Management
Framework.
Author's Addresses
Hannes Tschofenig
Siemens AG
Otto-Hahn-Ring 6
81739 Munich
Germany
EMail: Hannes.Tschofenig@siemens.com
Dirk Kroeselberg
Siemens AG
Haidenauplatz 1
81667 Munich
Germany
EMail: Dirk.Kroeselberg@siemens.com
Yoshihiro Ohba
Toshiba America Research, Inc.
1 Telcordia Drive
Piscataway, NJ 08854
USA
Phone: +1 732 699 5305
EMail: yohba@tari.toshiba.com
Florent Bersani
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Internet-Draft EAP-IKEv2 May 2005
France Telecom R&D
38, rue du General Leclerc
Issy-Les-Moulineaux 92794 Cedex 9
FR
EMail: florent.bersani@francetelecom.com
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