One document matched: draft-cam-winget-eap-fast-03.txt
Differences from draft-cam-winget-eap-fast-02.txt
Network Working Group N. Cam-Winget
Internet-Draft D. McGrew
Expires: April 22, 2006 J. Salowey
H. Zhou
Cisco Systems
October 19, 2005
The Flexible Authentication via Secure Tunneling Extensible
Authentication Protocol Method (EAP-FAST)
draft-cam-winget-eap-fast-03.txt
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Copyright Notice
Copyright (C) The Internet Society (2005).
Abstract
This document defines the Extensible Authentication Protocol (EAP)
based Flexible Authentication via Secure Tunneling (EAP-FAST)
protocol. EAP-FAST is an EAP method that enables secure
communication between a peer and a server by using the Transport
Layer Security (TLS) to establish a mutually authenticated tunnel.
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Within the tunnel, Type-Length-Value (TLV) objects are used to convey
authentication related data between the peer and the EAP server.
Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 4
1.1 Specification Requirements . . . . . . . . . . . . . . . . 5
1.2 Terminology . . . . . . . . . . . . . . . . . . . . . . . 5
2. Protocol Overview . . . . . . . . . . . . . . . . . . . . . . 5
2.1 Architectural Model . . . . . . . . . . . . . . . . . . . 6
2.2 Protocol Layering Model . . . . . . . . . . . . . . . . . 7
3. EAP-FAST Protocol . . . . . . . . . . . . . . . . . . . . . . 7
3.1 Version Negotiation . . . . . . . . . . . . . . . . . . . 8
3.2 EAP-FAST Authentication Phase 1: Tunnel Establishment . . 9
3.2.1 TLS Session Resume using Server State . . . . . . . . 10
3.2.2 TLS Session Resume Using a PAC . . . . . . . . . . . . 10
3.2.3 Transition between Abbreviated and Full TLS
Handshake . . . . . . . . . . . . . . . . . . . . . . 11
3.3 EAP-FAST Authentication Phase 2: Tunneled
Authentication . . . . . . . . . . . . . . . . . . . . . . 12
3.3.1 EAP Sequences . . . . . . . . . . . . . . . . . . . . 12
3.3.2 Protected Termination and Acknowledged Result
Indication . . . . . . . . . . . . . . . . . . . . . . 13
3.4 Error Handling . . . . . . . . . . . . . . . . . . . . . . 14
3.4.1 TLS Layer Errors . . . . . . . . . . . . . . . . . . . 14
3.4.2 Phase 2 Errors . . . . . . . . . . . . . . . . . . . . 14
3.5 Fragmentation . . . . . . . . . . . . . . . . . . . . . . 15
4. Message Formats . . . . . . . . . . . . . . . . . . . . . . . 16
4.1 EAP-FAST Message Format . . . . . . . . . . . . . . . . . 16
4.1.1 Authority ID Data . . . . . . . . . . . . . . . . . . 18
4.2 EAP-FAST TLV Format and Support . . . . . . . . . . . . . 19
4.2.1 General TLV Format . . . . . . . . . . . . . . . . . . 19
4.2.2 Result TLV . . . . . . . . . . . . . . . . . . . . . . 20
4.2.3 NAK TLV . . . . . . . . . . . . . . . . . . . . . . . 21
4.2.4 Error TLV . . . . . . . . . . . . . . . . . . . . . . 23
4.2.5 Vendor-Specific TLV . . . . . . . . . . . . . . . . . 24
4.2.6 EAP-Payload TLV . . . . . . . . . . . . . . . . . . . 25
4.2.7 Intermediate-Result TLV . . . . . . . . . . . . . . . 26
4.2.8 Crypto-Binding TLV . . . . . . . . . . . . . . . . . . 27
4.2.9 Request-Action TLV . . . . . . . . . . . . . . . . . . 29
4.3 Table of TLVs . . . . . . . . . . . . . . . . . . . . . . 30
5. Cryptographic Calculations . . . . . . . . . . . . . . . . . . 31
5.1 EAP-FAST Authentication Phase 1: Key Derivations . . . . . 31
5.2 Intermediate Compound Key Derivations . . . . . . . . . . 32
5.3 Computing the Compound MAC . . . . . . . . . . . . . . . . 32
5.4 EAP Master Session Key Generation . . . . . . . . . . . . 33
5.5 T-PRF . . . . . . . . . . . . . . . . . . . . . . . . . . 33
6. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 34
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7. Security Considerations . . . . . . . . . . . . . . . . . . . 34
7.1 Mutual Authentication and Integrity Protection . . . . . . 35
7.2 Method Negotiation . . . . . . . . . . . . . . . . . . . . 35
7.3 Separation of the EAP Server and the Authenticator . . . . 36
7.4 Separation of Phase 1 and Phase 2 Servers . . . . . . . . 36
7.5 Mitigation of Known Vulnerabilities and Protocol
Deficiencies . . . . . . . . . . . . . . . . . . . . . . . 37
7.5.1 User Identity Protection and Verification . . . . . . 38
7.5.2 Dictionary Attack Resistance . . . . . . . . . . . . . 39
7.5.3 Protection against MitM Attacks . . . . . . . . . . . 39
7.5.4 PAC Validation with User Credentials . . . . . . . . . 40
7.6 Protecting against Forged Clear Text EAP Packets . . . . . 41
7.7 Implementation . . . . . . . . . . . . . . . . . . . . . . 42
7.8 Server Certificate Validation . . . . . . . . . . . . . . 42
7.9 Security Claims . . . . . . . . . . . . . . . . . . . . . 42
8. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . 43
9. References . . . . . . . . . . . . . . . . . . . . . . . . . . 43
9.1 Normative References . . . . . . . . . . . . . . . . . . . 43
9.2 Informative References . . . . . . . . . . . . . . . . . . 44
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . 44
A. Examples . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
A.1 Successful Authentication . . . . . . . . . . . . . . . . 45
A.2 Failed Authentication . . . . . . . . . . . . . . . . . . 46
A.3 Full TLS Handshake using Certificate-based Cipher Suite . 48
A.4 Client authentication during Phase 1 with identity
privacy . . . . . . . . . . . . . . . . . . . . . . . . . 49
A.5 Fragmentation and Reassembly . . . . . . . . . . . . . . . 51
A.6 Sequence of EAP Methods . . . . . . . . . . . . . . . . . 53
A.7 Failed Crypto-binding . . . . . . . . . . . . . . . . . . 55
A.8 Stateless Session Resume Using Authorization PAC . . . . . 57
A.9 Sequence of EAP Method with Vendor-Specific TLV
Exchange . . . . . . . . . . . . . . . . . . . . . . . . . 58
B. Test Vectors . . . . . . . . . . . . . . . . . . . . . . . . . 60
B.1 Key Derivation . . . . . . . . . . . . . . . . . . . . . . 60
B.2 Crypto-Binding MIC . . . . . . . . . . . . . . . . . . . . 62
Intellectual Property and Copyright Statements . . . . . . . . 63
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1. Introduction
The need to provide user friendly and easily deployable network
access solutions has heightened the need for strong mutual
authentication protocols that internally use weak user credentials.
This document defines the base protocol which consists of
establishing a Transport Layer Security (TLS) tunnel as defined in
[RFC2246] and then exchanging data in the form of type, length, value
objects (TLV) to perform further authentication. [I-D.cam-winget-
eap-fast-provisioning] defines extensions to provision an additional
credential called a protected access credential (PAC) to optimize the
EAP-FAST exchange. In addition to regular TLS ciphersuites and
handshakes, EAP-FAST supports using a PAC with the TLS extension
defined in [I-D.salowey-tls-ticket] in order to support fast re-
establishment of the secure tunnel without having to maintain per-
session state on the server as described in Section 3.2.2.
EAP-FAST's design motivations included:
o Mutual Authentication: an EAP Server must be able to verify the
identity and authenticity of the peer, and the peer must be able
to verify the authenticity of the EAP server.
o Immunity to passive dictionary attacks: as many authentication
protocols require the password to be explicitly provided (either
in the clear or hashed) by the peer to the EAP server; at minimum,
the communication of the weak credential (e.g. password) must be
immune from eavesdropping.
o Immunity to man-in-the-middle (MitM) attacks: in establishing a
mutually authenticated protected tunnel, the protocol must prevent
adversaries from successfully interjecting information into the
conversation between the peer and the EAP server.
o Flexibility to enable support for most password authentication
interfaces: as many different password interfaces (e.g. MSCHAP,
LDAP, OTP, etc) exist to authenticate a peer, the protocol must
provide this support seamlessly.
o Efficiency: specifically when using wireless media, peers will be
limited in computational and power resources. The protocol must
enable the network access communication to be computationally
lightweight.
With these motivational goals defined, further secondary design
criteria are imposed:
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o Flexibility to extend the communications inside the tunnel: with
the growing complexity in network infrastructures the need to gain
authentication, authorization and accounting is also evolving.
For instance, there may be instances in which multiple (already
existent) authentication protocols are required to achieve mutual
authentication. Similarly, different protected conversations may
be required to achieve the proper authorization once a peer has
successfully authenticated.
o Minimize the authentication server's per user authentication state
requirements: with large deployments, it is typical to have many
servers acting as the authentication servers for many peers. It
is also highly desirable for a peer to use the same shared secret
to secure a tunnel much the same way it uses the username and
password to gain access to the network. The protocol must
facilitate the use of a single strong shared secret by the peer
while enabling the servers to minimize the per user and device
state it must cache and manage.
1.1 Specification Requirements
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in [RFC2119] .
1.2 Terminology
Much of the terminology in this document comes from [RFC3748].
Additional terms are defined below:
Protected Access Credential (PAC)
Credentials distributed to a peer for future optimized network
authentication. The PAC consists of at most three components: a
shared secret, an opaque element and optionally other information.
The shared secret part contains the pre-shared key between the
peer and the authentication server. The opaque part is provided
to the peer and is presented to the authentication server when the
peer wishes to obtain access to network resources. Finally, a PAC
may optionally include other information that may be useful to the
peer. The opaque part of the PAC is the same type of data as the
ticket in [I-D.salowey-tls-ticket].
2. Protocol Overview
EAP-FAST is an authentication protocol similar to EAP-TLS [RFC2716]
that enables mutual authentication and cryptographic context
establishment by using the TLS handshake protocol. EAP-FAST allows
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for the established TLS tunnel to be used for further authentication
exchanges. EAP-FAST makes use of TLVs to carry out the inner
authentication exchanges. The tunnel is then used to protect weaker
inner authentication methods, which may be based on passwords, and to
communicate the results of the authentication.
EAP-FAST makes use of the TLS enhancements in [I-D.salowey-tls-
ticket] to enable an optimized TLS tunnel session resume while
minimizing server state. In EAP-FAST the key and ticket used to
establish the tunnel may be provisioned through mechanisms that do
not involve the TLS handshake. It is RECOMMENDED that
implementations support the capability to distribute the ticket and
secret key within the EAP-FAST tunnel as specified in [I-D.cam-
winget-eap-fast-provisioning]. The pre-shared secret used in EAP-
FAST is referred to as the protected access credential key (or PAC-
Key); the PAC-Key is used to mutually authenticate the peer and the
server when securing a tunnel. The ticket is referred to as the
protected access credential opaque data (or PAC-Opaque).
The EAP-FAST conversation is used to establish or resume an existing
session to typically establish network connectivity between a peer
and the network. Upon successful execution of EAP-FAST both EAP Peer
and EAP Server derive strong session keys which can then communicated
to the network access server (NAS).
2.1 Architectural Model
The network architectural model for EAP-FAST usage is shown below:
+----------+ +----------+ +----------+ +----------+
| | | | | | | Inner |
| Peer |<---->| Authen- |<---->| EAP-FAST |<---->| Method |
| | | ticator | | server | | server |
| | | | | | | |
+----------+ +----------+ +----------+ +----------+
The entities depicted above are logical entities and may or may not
correspond to separate network components. For example, the EAP-
FAST server and Inner Method server might be a single entity; the
authenticator and EAP-FAST server might be a single entity; or, the
functions of the authenticator, EAP-FAST server and Inner Method
server might be combined into a single physical device. For example,
typical 802.11 deployments place the Authenticator in an access point
(AP) while a Radius Server may provide the EAP-FAST and Inner Method
server components. The above diagram illustrates the division of
labor among entities in a general manner and shows how a distributed
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system might be constructed; however, actual systems might be
realized more simply. The security considerations Section 7.4
provides an additional discussion of the implications of separating
EAP-FAST server from the inner method server.
2.2 Protocol Layering Model
EAP-FAST packets are encapsulated within EAP, and EAP in turn,
requires a carrier protocol for transport. EAP-FAST packets
encapsulate TLS, which is then used to encapsulate user
authentication information. Thus, EAP-FAST messaging can be
described using a layered model, where each layer encapsulates the
layer beneath it. The following diagram clarifies the relationship
between protocols:
+---------------------------------------------------------------+
| Inner EAP Method | Other TLV information |
|---------------------------------------------------------------|
| TLV Encapsulation (TLVs) |
|---------------------------------------------------------------|
| TLS |
|---------------------------------------------------------------|
| EAP-FAST |
|---------------------------------------------------------------|
| EAP |
|---------------------------------------------------------------|
| Carrier Protocol (EAPOL, RADIUS, Diameter, etc.) |
+---------------------------------------------------------------+
The TLV layer is a payload with standard Type-Length-Value (TLV)
Objects defined in Section 4.2. The TLV objects are used to carry
arbitrary parameters between an EAP peer and an EAP server. All
conversations in the EAP-FAST protected tunnel must be encapsulated
in a TLV layer.
Methods for encapsulating EAP within carrier protocols are already
defined. For example, IEEE 802.1x EAPOL may be used to transport EAP
between the peer and the authenticator; RADIUS or Diameter are used
to transport EAP between the authenticator and the EAP-FAST server.
3. EAP-FAST Protocol
EAP-FAST authentication occurs in two phases. For the first phase
EAP-FAST employs the TLS handshake to invoke an authenticated key
agreement exchange to establish a protected tunnel. Once the tunnel
is established phase 2 begins in which the peer and server can engage
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in further conversations to establish the required authentication and
authorization policies. The operation of the protocol including
phase 1 and phase 2 are the topic of this section. The format of
EAP-FAST messages is given in Section 4 and the cryptographic
calculations are given in Section 5.
3.1 Version Negotiation
EAP-FAST packets contain a three bit version field, following the TLS
Flags field, which enables EAP-FAST implementations to be backward
compatible with previous versions of the protocol. This
specification documents the EAP-FAST version 1 protocol;
implementations of this specification MUST use a version field set to
1.
Version negotiation proceeds as follows:
In the first EAP-Request sent with EAP type=EAP-FAST, the EAP
server must set the version field to the highest supported version
number.
If the EAP peer supports this version of the protocol, it MUST
respond with an EAP-Response of EAP type=EAP-FAST, and the version
number proposed by the EAP-FAST server.
If the EAP-FAST peer does not support this version, it responds
with an EAP-Response of EAP type=EAP-FAST and the highest
supported version number.
If the EAP-FAST server does not support the version number
proposed by the EAP-FAST peer, it terminates the conversation.
Otherwise the EAP-FAST conversation continues.
The version negotiation procedure guarantees that the EAP-FAST peer
and server will agree to the latest version supported by both
parties. If version negotiation fails, then use of EAP-FAST will not
be possible, and another mutually acceptable EAP method will need to
be negotiated if authentication is to proceed.
The EAP-FAST version is not protected by TLS; and hence can be
modified in transit. In order to detect modification of EAP-FAST
version and specifically downgrade of an EAP-FAST version negotiated,
the peers MUST exchange information on the EAP-FAST version number
received during version negotiation using the Crypto-Binding TLV
described in Section 3.3.2. The receiver of the Crypto-Binding TLV
MUST verify that the version in the Crypto-Binding TLV matches the
version sent in the EAP-FAST version negotiation.
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3.2 EAP-FAST Authentication Phase 1: Tunnel Establishment
EAP-FAST is based on TLS handshake [RFC2246] to establish an
authenticated and protected tunnel. The TLS version offered by the
peer and server MUST be TLS v1.0 or later. This version of the EAP-
FAST implementation MUST support the following TLS ciphersuites:
TLS_RSA_WITH_RC4_128_SHA
TLS_RSA_WITH_AES_128_CBC_SHA [RFC3268]
TLS_DHE_RSA_WITH_AES_128_CBC_SHA [RFC3268]
Other ciphersuites MAY be supported. It is RECOMMENDED that
anonymous ciphersuites such as TLS_DH_anon_WITH_AES_128_CBC_SHA only
be used in the context of the provisioning described in [I-D.cam-
winget-eap-fast-provisioning]. During the EAP-FAST Phase 1
conversation the EAP-FAST endpoints MAY negotiate TLS compression.
The EAP server initiates the EAP-FAST conversation with an EAP
request containing an EAP-FAST/Start packet. This packet includes a
set Start (S) bit, the EAP-FAST version as specified in Section 3.1,
and an authority identity. The TLS payload in the initial packet is
empty. The authority identity (A-ID) is used to provide the peer a
hint of the server's identity which may be useful in helping the peer
select the appropriate credential to use. Assuming that the peer
supports EAP-FAST the conversation continues with the peer sending an
EAP-Response packet with EAP type of EAP-FAST with the start (s) bit
clear and the version as specified in Section 3.1. This message
encapsulates one or more TLS records containing the TLS handshake
messages. If the EAP-FAST version negotiation is successful then the
EAP-FAST conversation continues until the EAP server and EAP peer are
ready to enter phase 2. When the full TLS handshake is performed,
then the first payload of EAP-FAST Phase 2 MAY be sent along with
finished handshake message to reduce the number of round trips.
After the TLS session is established, another EAP exchange may occur
within the tunnel to authenticate the EAP peer. EAP-FAST
implementations MUST support client authentication during tunnel
establishment using the specified TLS ciphersuites specified in
Section 3.2. EAP-FAST implementations MUST also support the
immediate re-negotiation of a TLS session to initiate a new handshake
message exchange under the protection of the current ciphersuite.
This allows support for protection of the peer's identity. Note that
the EAP peer does not need to authenticate as part of the TLS
exchange, but can alternatively be authenticate through additional
EAP exchanges carried out in phase 2.
The EAP-FAST tunnel protects peer identity information from
disclosure outside the tunnel. Implementations that wish to provide
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identity privacy for the peer identity must carefully consider what
information is disclosed outside the tunnel.
The following sections describe resuming a TLS session based on
server side or client side state.
3.2.1 TLS Session Resume using Server State
EAP-FAST session resumption is achieved in the same manner TLS
achieves session resume. To support session resumption, the server
and peer must minimally cache the Session ID, master secret and
ciphersuite. The peer attempts to resume a session by including a
valid Session ID from a previous handshake in its ClientHello
message. If the server finds a match for the Session ID and is
willing to establish a new connection using the specified session
state, the server will respond with the same session ID and proceed
with the EAP-FAST Authentication Phase 1 tunnel establishment based
on a TLS abbreviated handshake. After a successful conclusion of the
EAP-FAST Authentication Phase 1 conversation, the conversation then
continues on to phase 2.
3.2.2 TLS Session Resume Using a PAC
EAP-FAST supports the resumption of sessions based on client side
state using techniques described in [I-D.salowey-tls-ticket]. This
version of EAP-FAST does not support the provisioning of a ticket
through the use of the SessionTicket handshake message. Instead it
supports the provisioning of a ticket called a Protected Access
Credential (PAC) as described in [I-D.cam-winget-eap-fast-
provisioning]. Since the PAC mentioned here is used for establishing
the TLS Tunnel, it is more specifically referred to as the Tunnel
PAC. The Tunnel PAC is a security credential provided by the EAP
server to a peer and comprised of:
1. PAC-Key: this is a 32-octet key used by the peer to establish the
EAP-FAST Phase 1 tunnel. This key is used to derive the TLS
premaster secret as described in Section 5.1. The PAC-Key is
randomly generated by the EAP Server to produce a strong entropy
32-octet key. The PAC-Key is a secret and MUST be treated
accordingly. For example a PAC-Key MUST be delivered in a secure
channel and stored securely.
2. PAC-Opaque: this is a variable length field that is sent to the
EAP Server during the EAP-FAST Phase 1 tunnel establishment. The
PAC-Opaque can only be interpreted by the EAP Server to recover
the required information for the server to validate the peer's
identity and authentication. For example, the PAC-Opaque may
include the PAC-Key and the PAC's peer identity. The PAC-Opaque
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format and contents are specific to the PAC issuing server. The
PAC-Opaque is a public credential and MAY be presented in the
clear, so an attacker MUST NOT be able to gain useful information
from the PAC-Opaque itself.
3. PAC-Info: this is a variable length field used to provide at
minimum, the authority identity of PAC issuer. Other useful but
not mandatory information, such as the PAC-Key lifetime, may also
be conveyed by the EAP Server to the peer during PAC provisioning
or refreshment.
The use of the PAC is based on the SessionTicket extension defined in
[I-D.salowey-tls-ticket]. The EAP Server initiates the TLS
conversation as in the previous section. Upon receiving the A-ID
from the server the Peer checks to see if it has an existing valid
PAC-Key and PAC-Opaque for the server. If it does then it obtains
the PAC-Opaque and puts it in the SessionTicket extension in the
ClientHello. It is RECOMMENDED in EAP-FAST that the peer include an
empty session ID in a ClientHello containing a PAC-Opaque. EAP-FAST
does not currently support the SessionTicket Handshake message so an
empty SessionTicket extension MUST NOT be included in the
ClientHello. If the PAC-Opaque included in SessionTicket extension
is valid and EAP server permits the abbreviated TLS handshake, it
will select the ciphersuite allowed to be used from information
within the PAC and finish with the abbreviated TLS handshake. If the
server receives a Session ID and a PAC-Opaque in the SessionTicket
extension in a ClientHello it should place the same Session ID in the
ServerHello if it is resuming a session based on the PAC-Opaque. The
conversation then proceeds as described in [I-D.salowey-tls-ticket]
until the handshake completes or a fatal error occurs. After the
abbreviated handshake completes the peer and server are ready to
enter phase 2. Note that when a PAC is used the TLS master secret is
calculated from the PAC-Key, client random and server random as
described in Section 5.1.
3.2.3 Transition between Abbreviated and Full TLS Handshake
If session resumption based on server side or client side state fails
the server can gracefully fall back to a full TLS handshake. If the
ServerHello received by the peer contains a empty Session ID or a
Session ID that is different than in the ClientHello the server may
be falling back to a full handshake. The peer can distinguish
Server's intent of negotiating full or abbreviated TLS handshake by
checking the next TLS handshake messages in the server response to
ClientHello. If ChangeCipherSpec follows the ServerHello in response
to the ClientHello, then the Server has accepted the session
resumption and intends to negotiate the abbreviated handshake.
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Otherwise, the Server intends to negotiate the full TLS handshake. A
peer can request for a new PAC to be provisioned after the full TLS
handshake and mutual authentication of the peer and the server. In
order to facilitate the fall back to a full handshake the peer SHOULD
include ciphersuites that allow for a full handshake and possibly PAC
provisioning so the server can select one of this in case session
resumption fails. An example of the transition is shown in
Appendix A.
3.3 EAP-FAST Authentication Phase 2: Tunneled Authentication
The second portion of the EAP-FAST Authentication occurs immediately
after successful completion of phase 1. Phase 2 occurs even if both
peer and authenticator are authenticated in the phase 1 TLS
negotiation. Phase 2 MUST NOT occur if the Phase 1 TLS handshake
fails. Phase 2 consists of a series of requests and responses formed
of TLV objects defined in Section 4.2. Phase 2 MUST always end with
a protected termination exchange described in Section 3.3.2. The TLV
exchange may include the execution of zero or more EAP methods within
the protected tunnel as described in Section 3.3.1. A server MAY
proceed directly to the protected termination exchange if it does not
wish to request further authentication from the peer. However, the
peer and server must not assume that either will skip inner EAP
methods or other TLV exchanges. The peer may have roamed to a
network which requires conformance with a different authentication
policy or the peer may request the server take additional action
through the use of the Request-Action TLV.
3.3.1 EAP Sequences
EAP [RFC3748] prohibits use of multiple authentication methods within
a single EAP conversation in order to limit vulnerabilities to man-
in-the-middle attacks. EAP-FAST addresses man-in-the-middle attacks
through support for cryptographic protection of the inner EAP
exchange and cryptographic binding of the inner authentication method
to the protected tunnel. EAP methods are executed serially in a
sequence. This version of EAP-FAST does not support initiating
multiple EAP methods simultaneously in parallel. The methods need
not be distinct. For example, EAP-TLS could be run twice as an inner
method, initially with machine credentials followed by user
credentials.
EAP method messages are carried within EAP-Payload TLVs defined in
Section 4.2.6. Upon method completion of a method a server MUST send
an Intermediate-Result TLV indicating the result. The peer MUST
respond to the Intermediate-Result TLV indicating its result. If the
result indicates success the Intermediate-Result TLV MUST be
accompanied by a Crypto-Binding TLV. The Crypto-Binding TLV is
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further discussed in Section 4.2.8 and Section 5.3. The
Intermediate-Result TLVs can be included with other TLVs such as EAP-
Payload TLVs starting a new EAP conversation or with the Result TLV
used in the protected termination exchange.
If both peer and server indicate success then the method is
considered to have completed. If either indicates failure then the
method is considered to have failed. The result of failure of a EAP
method does not always imply a failure of the overall authentication.
If one authentication method fails the server may attempt to
authenticate the peer with a different method.
3.3.2 Protected Termination and Acknowledged Result Indication
A successful EAP-FAST phase 2 conversation MUST always end in a
successful Result TLV exchange. An EAP-FAST server may initiate the
Result TLV exchange without initiating any EAP conversation in EAP-
FAST Phase 2. After the final Result TLV exchange the TLS tunnel is
terminated and a clear text EAP-Success or EAP-Failure is sent by the
server. The format of the Result TLV is described in Section 4.2.2.
A server initiates a successful protected termination exchange by
sending a Result TLV indicating success. The server may send the
Result TLV along with an Intermediate-Result TLV and a Crypto-Binding
TLV. If the peer requires nothing more from the server it will
respond with a Result TLV indicating success accompanied by an
Intermediate-Result TLV and Crypto-Binding TLV if necessary. The
server then tears down the tunnel and sends a clear text EAP-Success.
If the peer receives a Result TLV indicating success from the server,
but its authentication policies are not satisfied (for example it
requires a particular authentication mechanism be run or it wants to
request a PAC) it may request further action from the server using
the Request-Action TLV. The Request-Action TLV is sent along with
the Result TLV indicating what EAP Success/Failure result peer would
expect if the requested action is not granted. The value of the
Request-Action TLV indicates what the peer would like to do next.
The format and values for the Request-Action TLV are defined in
Section 4.2.9.
Upon receiving the Request-Action TLV the server may process the
request or ignore it, based on its policy. If the server ignores the
request, it proceeds with termination of the tunnel and send the
clear text EAP Success or Failure message based on the value of the
peer's result TLV. If server honors and processes the request, it
continues with the requested action. The conversation completes with
a Result TLV exchange. The Result TLV may be included with the TLV
that completes the requested action.
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Error handling for phase 2 is discussed in Section 3.4.2.
3.4 Error Handling
EAP-FAST uses the following error handling rules summarized below:
1. Errors in TLS layer are communicated via TLS alert messages in
all phases of EAP-FAST.
2. The Intermediate-Result TLVs indicate success or failure
indications of the individual EAP methods in EAP-FAST Phase 2.
Errors within the EAP conversation in Phase 2 are expected to be
handled by individual EAP methods.
3. Violations of the TLV rules are handled using Result TLVs
together with Error TLVs.
4. Tunnel compromised errors (errors caused by Crypto-Binding failed
or missing) are handled using Result TLVs and Error TLVs.
3.4.1 TLS Layer Errors
If the EAP-FAST server detects an error at any point in the TLS
Handshake or the TLS layer, the server SHOULD send an EAP-FAST
request encapsulating a TLS record containing the appropriate TLS
alert message rather than immediately terminating the conversation so
as to allow the peer to inform the user of the cause of the failure
and possibly allow for a restart of the conversation. The peer MUST
send an EAP-FAST response to an alert message. The EAP-Response
packet sent by the peer may encapsulate a TLS ClientHello handshake
message, in which case the EAP-FAST server MAY allow the EAP-FAST
conversation to be restarted, or it MAY contain an EAP-FAST response
with a zero length message, in which case the server MUST terminate
the conversation with an EAP-Failure packet. It is up to the EAP-
FAST server whether to allow restarts, and if so, how many times the
conversation can be restarted. An EAP-FAST Server implementing
restart capability SHOULD impose a limit on the number of restarts,
so as to protect against denial of service attacks.
If the EAP-FAST peer detects an error at any point in the TLS layer,
the EAP-FAST peer should send an EAP-FAST response encapsulating a
TLS record containing the appropriate TLS alert message. The server
may restart the conversation by sending an EAP-FAST request packet
encapsulating the TLS HelloRequest handshake message. The peer may
allow the EAP-FAST conversation to be restarted or it may terminate
the conversation by sending an EAP-FAST response with an zero length
message.
3.4.2 Phase 2 Errors
Any time the peer or the server finds a fatal error outside of the
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TLS layer during phase 2 TLV processing it MUST send a Result TLV of
failure and an Error TLV with the appropriate error code. For errors
involving the processing the sequence of exchanges, such as a
violation of TLV rules (e.g., multiple EAP-Payload TLVs) the error
code is Unexpected_TLVs_Exchanged. For errors involving a tunnel
compromise the error-code is Tunnel_Compromise_Error. Upon sending a
Result TLV with a fatal Error TLV the sender terminates the TLS
tunnel.
If a server receives a Result TLV of failure with a fatal Error TLV
it SHOULD send a clear text EAP-Failure. If a peer receives a Result
TLV of failure it MUST respond with a Result TLV indicating failure.
If the server has sent a Result TLV of failure it ignores the peer
response and it SHOULD send a clear text EAP-Failure.
3.5 Fragmentation
A single TLS record may be up to 16384 octets in length, but a TLS
message may span multiple TLS records, and a TLS certificate message
may in principle be as long as 16MB. This is larger than the maximum
size for a message on most media types, therefore it is desirable to
support fragmentation. Note that in order to protect against
reassembly lockup and denial of service attacks, it may be desirable
for an implementation to set a maximum size for one such group of TLS
messages. Since a typical certificate chain is rarely longer than a
few thousand octets, and no other field is likely to be anywhere near
as long, a reasonable choice of maximum acceptable message length
might be 64 KB. This is still a fairly large message packet size so
an EAP-FAST implementation MUST provide its own support for
fragmentation and reassembly.
Since EAP is an lock-step protocol, fragmentation support can be
added in a simple manner. In EAP, fragments that are lost or damaged
in transit will be retransmitted, and since sequencing information is
provided by the Identifier field in EAP, there is no need for a
fragment offset field as is provided in IPv4.
EAP-FAST fragmentation support is provided through addition of flag
bits within the EAP-Response and EAP-Request packets, as well as a
TLS Message Length field of four octets. Flags include the Length
included (L), More fragments (M), and EAP-FAST Start (S) bits. The L
flag is set to indicate the presence of the four octet TLS Message
Length field, and MUST be set for the first fragment of a fragmented
TLS message or set of messages. The M flag is set on all but the
last fragment. The S flag is set only within the EAP-FAST start
message sent from the EAP server to the peer. The TLS Message Length
field is four octets, and provides the total length of the TLS
message or set of messages that is being fragmented; this simplifies
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buffer allocation.
When an EAP-FAST peer receives an EAP-Request packet with the M bit
set, it MUST respond with an EAP-Response with EAP-Type of EAP-FAST
and no data. This serves as a fragment ACK. The EAP server must
wait until it receives the EAP-Response before sending another
fragment. In order to prevent errors in processing of fragments, the
EAP server MUST increment the Identifier field for each fragment
contained within an EAP-Request, and the peer must include this
Identifier value in the fragment ACK contained within the EAP-
Response. Retransmitted fragments will contain the same Identifier
value.
Similarly, when the EAP-FAST server receives an EAP-Response with the
M bit set, it must respond with an EAP-Request with EAP-Type of EAP-
FAST and no data. This serves as a fragment ACK. The EAP peer MUST
wait until it receives the EAP-Request before sending another
fragment. In order to prevent errors in the processing of fragments,
the EAP server MUST increment the Identifier value for each fragment
ACK contained within an EAP-Request, and the peer MUST include this
Identifier value in the subsequent fragment contained within an EAP-
Response.
4. Message Formats
The following sections describe the message formats used in EAP-FAST.
The fields are transmitted from left to right in network byte order.
4.1 EAP-FAST Message Format
A summary of the EAP-FAST Request/Response packet format is shown
below.
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 | Ver | Message Length +
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Message Length | Data... +
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
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Code
1 Request
2 Response
Identifier
The Identifier field is one octet and aids in matching
responses with requests. The Identifier field MUST be changed
on each Request packet. The Identifier field in the Response
packet MUST match the Identifier field from the corresponding
request.
Length
The Length field is two octets and indicates the length of the
EAP packet including the Code, Identifier, Length, Type, Flags,
Ver, Message Length and Data fields. Octets outside the range
of the Length field should be treated as Data Link Layer
padding and should be ignored on reception.
Type
43 for EAP-FAST
Flags
0 1 2 3 4
+-+-+-+-+-+
|L M S R R|
+-+-+-+-+-+
L Length included
M More fragments
S EAP-FAST start
R Reserved (must be zero)
L bit (length included) is set to indicate the presence of
the four octet Message Length field, and MUST be set for the
first fragment of a fragmented TLS message or set of
messages. The M bit (more fragments) is set on all but the
last fragment. The S bit (EAP-FAST Start) is set in an EAP-
FAST Start message.
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Ver
This field contains the version of the protocol. This document
describes version 1 (001 in binary) of EAP-FAST.
Message Length
The Message Length field is four octets, and is present only if
the L bit is set. This field provides the total length of the
message that may be fragmented over the data fields of multiple
packets.
Data
In the case of a EAP-FAST Start request (i.e. when the S bit is
set) the Data field consists of the A-ID described in
Section 4.1.1. In other cases when the Data field is present
it consists of an encapsulated TLS packet in TLS record format.
An EAP-FAST packet with Flags and Version fields but with zero
length data field to used to indicate EAP-FAST acknowledgement
for either a fragmented message, a TLS Alert message or a TLS
Finished message.
4.1.1 Authority ID Data
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 (0x04) | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| ID
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Type
0x04 for Authority ID
Length
The Length filed is two octets, which contains the length of
the ID field in octets.
ID
Hint of the identity of the server. It should be unique across
the deployment.
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4.2 EAP-FAST TLV Format and Support
The TLVs defined here are standard Type-Length-Value (TLV) objects.
The TLV objects could be used to carry arbitrary parameters between
EAP peer and EAP server within the protected TLS tunnel.
The EAP peer may not necessarily implement all the TLVs supported by
the EAP server. To allow for interoperability, TLVs are designed to
allow an EAP server to discover if a TLV is supported by the EAP
peer, using the NAK TLV. The mandatory bit in a TLV indicates
whether support of the TLV is required. If the peer or server does
not support a TLV marked mandatory, then it MUST send a NAK TLV in
the response, and all the other TLVs in the message MUST be ignored.
If an EAP peer or server finds an unsupported TLV which is marked as
optional, it can ignore the unsupported TLV. It MUST NOT send an NAK
TLV for a TLV that is not marked mandatory.
Note that a peer or server may support a TLV with the mandatory bit
set, but may not understand the contents. The appropriate response
to a supported TLV with content that is not understood is defined by
the individual TLV specification.
EAP implementations compliant with this specification MUST support
TLV exchanges, as well as processing of mandatory/optional settings
on the TLV. Implementations conforming to this specification MUST
support the following TLVs:
Result TLV
NAK TLV
Error TLV
EAP-Payload TLV
Intermediate-Result TLV
Crypto-Binding TLV
Request-Action TLV
4.2.1 General TLV Format
TLVs are defined as described below. The fields are transmitted from
left to right.
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|M|R| TLV Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Value...
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
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M
0 Optional TLV
1 Mandatory TLV
R
Reserved, set to zero (0)
TLV Type
A 14-bit field, denoting the TLV type. Allocated Types
include:
0 Reserved
1 Reserved
2 Reserved
3 Result TLV
4 NAK TLV
5 Error TLV
7 Vendor-Specific TLV
9 EAP-Payload TLV
10 Intermediate-Result TLV
11 PAC TLV [I-D.cam-winget-eap-fast-provisioning]
12 Crypto-Binding TLV
18 Server-Trusted-Root TLV [I-D.cam-winget-eap-fast-
provisioning]
19 Request-Action TLV
20 PKCS#7 TLV [I-D.cam-winget-eap-fast-provisioning]
Length
The length of the Value field in octets.
Value
The value of the TLV.
4.2.2 Result TLV
The Result TLV provides support for acknowledged success and failure
messages for protected termination within EAP-FAST. If the Status
field does not contain one of the known values, then the peer or EAP
server MUST treat this as a fatal error of Unexpected_TLVs_Exchanged.
The behavior of the Result TLV is further discussed in Section 3.3.2
and Section 3.4.2. An Result TLV indicating failure MUST NOT be
accompanied by the following TLVs: NAK, EAP-Payload TLV, or Crypto-
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Binding TLV. Result TLV is defined as follows:
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|M|R| TLV Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Status |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
M
Mandatory, set to one (1)
R
Reserved, set to zero (0)
TLV Type
3 for Result TLV
Length
2
Status
The Status field is two octets. Values include:
1 Success
2 Failure
4.2.3 NAK TLV
The NAK TLV allows a peer to detect TLVs that are not supported by
the other peer. An EAP-FAST packet can contain 0 or more NAK TLVs.
A NAK TLV should not be accompanied by other TLVs. A NAK TLV MUST
NOT be sent in response to a message containing a Result TLV, instead
a Result TLV of failure should be sent indicating failure and an
Error TLV of Unexpected_TLVs_Exchanged. The NAK TLV is defined as
follows:
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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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|M|R| TLV Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Vendor-Id |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| NAK-Type | TLVs....
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
M
Mandatory, set to one (1)
R
Reserved, set to zero (0)
TLV Type
4 for NAK TLV
Length
>=6
Vendor-Id
The Vendor-Id field is four octets, and contains the Vendor-Id
of the TLV that was not supported. The high-order octet is 0
and the low-order 3 octets are the SMI Network Management
Private Enterprise Code of the Vendor in network byte order.
The Vendor-Id field MUST be zero for TLVs that are not Vendor-
Specific TLVs.
NAK-Type
The NAK-Type field is two octets. The field contains the Type
of the TLV that was not supported. A TLV of this Type MUST
have been included in the previous packet.
TLVs
This field contains a list of TLVs, each of which MUST NOT have
the mandatory bit set. These optional TLVs are for future
extensibility to communicate why the offending TLV was
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determined to be unsupported.
4.2.4 Error TLV
The Error TLV allows an EAP peer or server to indicate errors to the
other party. An EAP-FAST packet can contain 0 or more Error TLVs.
The Error-Code field describes the type of error. Error Codes 1-999
represent successful outcomes (informative messages), 1000-1999
represent warnings, and codes 2000-2999 represent fatal errors. A
fatal Error TLV MUST be accompanied by a Result TLV indicating
failure and the conversation must be terminated as described in
Section 3.4.2. The Error TLV is defined as follows:
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|M|R| TLV Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Error-Code |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
M
Mandatory, set to one (1)
R
Reserved, set to zero (0)
TLV Type
5 for Error TLV
Length
4
Error-Code
The Error-Code field is four octets. Currently defined values
for Error-Code include:
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2001 Tunnel_Compromise_Error
2002 Unexpected_TLVs_Exchanged
4.2.5 Vendor-Specific TLV
The Vendor-Specific TLV is available to allow vendors to support
their own extended attributes not suitable for general usage. A
Vendor-Specific TLV attribute can contain one or more TLVs, referred
to as Vendor TLVs. The TLV-type of a Vendor-TLV is defined by the
vendor. All the Vendor TLVs inside a single Vendor-Specific TLV
belong to the same vendor. The can be multiple Vendor-Specific TLVs
from different vendors in the same message.
Vendor TLVs may be optional or mandatory. Vendor TLVs sent with
Result TLVs MUST be marked as optional.
The Vendor-Specific TLV is defined as follows:
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|M|R| TLV Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Vendor-Id |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Vendor TLVs....
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
M
0 or 1
R
Reserved, set to zero (0)
TLV Type
7 for Vendor Specific TLV
Length
>=4
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Vendor-Id
The Vendor-Id field is four octets, and contains the Vendor-Id
of the TLV. The high-order octet is 0 and the low-order 3
octets are the SMI Network Management Private Enterprise Code
of the Vendor in network byte order.
Vendor TLVs
This field is of indefinite length. It contains vendor-
specific TLVs, in a format defined by the vendor.
4.2.6 EAP-Payload TLV
To allow piggybacking EAP request and response with other TLVs, the
EAP-Payload TLV is defined, which includes an encapsulated EAP packet
and a list of optional TLVs. The optional TLVs are provided for
future extensibility to provide hints about the current EAP
authentication. Only one EAP-Payload TLV is allowed in a message.
The EAP-Payload TLV is defined as follows:
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|M|R| TLV Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| EAP packet...
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| TLVs...
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
M
Mandatory, set to (1)
R
Reserved, set to zero (0)
TLV Type
9 for EAP-Payload TLV
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Length
>=0
EAP packet
This field contains a complete EAP packet, including the EAP
header (Code, Identifier, Length, Type) fields. The length of
this field is determined by the Length field of the
encapsulated EAP packet.
TLVs
This (optional) field contains a list of TLVs associated with
the EAP packet field. The TLVs MUST NOT have the mandatory bit
set. The total length of this field is equal to the Length
field of the EAP-Payload TLV, minus the Length field in the EAP
header of the EAP packet field.
4.2.7 Intermediate-Result TLV
The Intermediate-Result TLV provides support for acknowledged
intermediate Success and Failure messages between multiple inner EAP
methods within EAP. An Intermediate-Result TLV indicating success
MUST be accompanied by a Crypto-Binding TLV. The optional TLVs
associated with this TLV are provided for future extensibility to
provide hints about the current result. The Intermediate-Result TLV
is defined as follows:
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|M|R| TLV Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Status | TLVs...
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
M
Mandatory, set to (1)
R
Reserved, set to zero (0)
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TLV Type
10 for Intermediate-Result TLV
Length
>=2
Status
The Status field is two octets. Values include:
1 Success
2 Failure
TLVs
This (optional) field is of indeterminate length, and contains
the TLVs associated with the Intermediate Result TLV. The TLVs
in this field MUST NOT have the mandatory bit set.
4.2.8 Crypto-Binding TLV
The Crypto-Binding TLV is used to prove that both the peer and server
participated in the tunnel establishment and sequence of
authentications. It also provides verification of the EAP-FAST
version negotiated before TLS tunnel establishment, see Section 3.1.
The Crypto-Binding TLV MUST be included with Intermediate-Result TLV
to perform Cryptographic Binding after each successful EAP method in
a sequence of EAP methods. The Crypto-Binding TLV can be issued at
other times as well.
The Crypto-Binding TLV is valid only if the following checks pass:
o The Crypto-Binding TLV version is supported
o The MAC verifies correctly
o The received version in the Crypto-Binding TLV matches the version
sent by the receiver during the EAP version negotiation
o The subtype is set to the correct value
If any of the above checks fail then the TLV is invalid. An invalid
Crypto-Binding TLV is a fatal error and is handled as described in
Section 3.4.2
The Crypto-Binding TLV is defined as follows:
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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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|M|R| TLV Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Reserved | Version | Received Ver. | Sub-Type |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
~ Nonce ~
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
~ Compound MAC ~
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
M
Mandatory, set to (1)
R
Reserved, set to zero (0)
TLV Type
12 for Crypto-Binding TLV
Length
56
Reserved
Reserved, set to zero (0)
Version
The Version field is a single octet, which is set to the
version of Crypto-Binding TLV the EAP method is using. For
implementation compliant with this version of EAP-FAST, the
version number MUST set to 1.
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Received Version
The Received Version field is a single octet and MUST be set to
the EAP version number received during version negotiation.
Note that this field only provides protection against downgrade
attacks where a version of EAP requiring support for this TLV
is required on both sides.
Sub-Type
The Sub-Type field is two octets. Defined values are
0 Binding Request
1 Binding Response
Nonce
The Nonce field is 32 octets. It contains a 256 bit nonce that
is temporally unique, used for compound MAC key derivation at
each end. The nonce in a request MUST have its least
significant bit set to 0 and the nonce in a response MUST have
the same value as the request nonce except the least
significant bit MUST be set to 1.
Compound MAC
The Compound MAC field is 20 octets. This can be the Server
MAC (B1_MAC) or the Client MAC (B2_MAC). The computation of
the MAC is described in Section 5.3
4.2.9 Request-Action TLV
The Request-Action TLV MAY be sent by the peer along with a Result
TLV in response to a server's successful Result TLV. It allows the
peer to request the EAP server to negotiate additional EAP methods or
process TLVs specified in the response packet. The server MAY ignore
this TLV.
The Request-Action TLV is defined as follows:
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|M|R| TLV Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Action |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
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M
Mandatory set to one (1)
R
Reserved, set to zero (0)
TLV Type
19 for Request-Action TLV
Length
2
Action
The Action field is two octets. Values include:
1 Process-TLV
2 Negotiate-EAP
4.3 Table of TLVs
The following table provides a guide to which TLVs may be found in
which kinds of messages, and in what quantity. The messages are as
follows: Request is an EAP-FAST Request, Response is an EAP-FAST
Response, Success is a message containing a successful Result TLV,
and Failure is a message containing a failed Result TLV.
Request Response Success Failure TLVs
0-1 0-1 0-1 0-1 Intermediate-Result
0-1 0-1 0 0 EAP-Payload
0-1 0-1 1 1 Result
0-1 0-1 0-1 0-1 Crypto-Binding
0+ 0+ 0+ 0+ Error
0+ 0+ 0 0 NAK
0+ 0+ 0+ 0+ Vendor-Specific [NOTE1]
0 0-1 0-1 0-1 Request-Action
[Note1] Vendor TLVs (included in Vendor-Specific TLVs) sent with a
Result TLV MUST be marked as optional.
The following table defines the meaning of the table entries in the
sections below:
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0 This TLV MUST NOT be present in the message.
0+ Zero or more instances of this TLV MAY be present in the message.
0-1 Zero or one instance of this TLV MAY be present in the message.
1 Exactly one instance of this TLV MUST be present in the message.
5. Cryptographic Calculations
5.1 EAP-FAST Authentication Phase 1: Key Derivations
The EAP-FAST Authentication tunnel key is calculated similarly to the
TLS key calculation with an additional 40 octets (referred to, as the
session_key_seed) generated. The additional session_key_seed is used
in the Session Key calculation in the EAP-FAST Tunneled
Authentication conversation.
To generate the key material required for EAP-FAST Authentication
tunnel, the following construction from [RFC2246] is used:
key_block = PRF(master_secret, "key expansion",
server_random + client_random)
where '+' denotes concatenation.
The PRF function used to generate keying material is defined by
[RFC2246].
For example, if the EAP-FAST Authentication employs 128bit RC4 and
SHA1, the key_block is 112 bytes long and is partitioned as follows:
client_write_MAC_secret[20]
server_write_MAC_secret[20]
client_write_key[16]
server_write_key[16]
client_write_IV[0]
server_write_IV[0]
session_key_seed[40]
The session_key_seed is used by the EAP-FAST Authentication Phase 2
conversation to both cryptographically bind the inner method(s) to
the tunnel as well as generate the resulting EAP-FAST session keys.
The other quantities are used as they are defined in [RFC2246].
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The master_secret is generated as specified in TLS unless a PAC is
used to establish the TLS tunnel. When a PAC is used to establish
the TLS tunnel, the master_secret is calculated from the specified
client_random, server_random and PAC-Key as follows:
master_secret = T-PRF(PAC-Key, "PAC to master secret label hash",
server_random + client_random, 48)
where T-PRF is described in Section 5.5.
5.2 Intermediate Compound Key Derivations
The session_key_seed derived as part of EAP-FAST phase 2 is used in
EAP-FAST phase 2 to generate an Intermediate Compound Key (IMCK) used
to verify the integrity of the TLS tunnel after each successful inner
authentication and in the generation of Master Session Key (MSK) and
Extended Master Session Key (EMSK) defined in [RFC3748]. Note that
the IMCK must be recalculated after each successful inner EAP method.
The first step in these calculations is the generation of the base
compound key, IMCK[n] from the session_key_seed and any session keys
derived from the successful execution of n inner EAP methods. The
inner EAP method(s) may provide Master Session Keys, MSK1..MSKn,
corresponding to inner methods 1 through n. The MSK is truncated at
32 bytes if it is longer than 32 bytes or padded to a length of 32
bytes with zeros if it is less than 32 bytes. If the ith inner
method does not generate an MSK, then MSKi is set to zero (e.g. MSKi
= 32 octets of 0x00s). If an inner method fails then it is not
included in this calculation. The derivations of S-IMSK is as
follow:
S-IMCK[0] = session_key_seed
For j = 1 to n-1 do
IMCK[j] = T-PRF(S-IMCK[j-1], "Inner Methods Compound Keys",
MSK[j], 60)
S-IMCK[j] = first 40 octets of IMCK[j]
CMK[j] = last 20 octets of IMCK[j]
where T-PRF is described in Section 5.5.
5.3 Computing the Compound MAC
For authentication methods that generate keying material, further
protection against man-in-the-middle attacks is provided through
cryptographically binding keying material established by both EAP-
FAST Phase 1 and EAP-FAST Phase 2 conversations. After each
successful inner EAP authentication, EAP MSKs are cryptographically
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combined with key material from EAP-FAST phase 1 to generate a
compound session key, CMK. The CMK is used to calculate the Compound
MAC as part of the Crypto-Binding TLV described in Section 4.2.8,
which helps provide assurance that the same entities are involved all
communications in EAP-FAST.
The Compound MAC computation is as follows:
CMK = CMK[j]
Compound-MAC = HMAC-SHA1( CMK, Crypto-Binding TLV )
where j is the number of the last successfully executed inner EAP
method.
5.4 EAP Master Session Key Generation
EAP-FAST Authentication assures the master session key (MSK) and
Extended Master Session Key (EMSK) output from the EAP method are the
result of all authentication conversations by generating an
intermediate compound session key (IMCK). The IMCK is mutually
derived by the peer and the server as described in Section 5.2 by
combining the MSKs from inner EAP methods with key material from EAP-
FAST phase 1. The resulting MSK and EMSK are generated as part of
the IMCKn key hierarchy as follows:
MSK = T-PRF(S-IMCK[j], "Session Key Generating Function", 64)
EMSK = T-PRF(S-IMCK[j],
"Extended Session Key Generating Function", 64)
where j is the number of the last successfully executed inner EAP
method.
The EMSK is typically only known to the EAP-FAST peer and server and
is not provided to a third party. The derivation of additional keys
and transportation of these keys to third party is outside the scope
of this document.
If no EAP methods have been negotiated inside the tunnel or no EAP
methods have been successfully completed inside the tunnel, the MSK
and EMSK will be generated directly from the session_key_seed meaning
S-IMCK = session_key_seed.
5.5 T-PRF
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EAP-FAST employs the following PRF prototype and definition:
T-PRF = F(key, label, seed, outputlength)
Where label is intended to be a unique label for each different use
of the T-PRF. outputlength is a two octet value that is represented
in big endian order. Also note that the seed value may be optional
and may be omitted as in the case of the MSK derivation described in
Section 5.4.
To generate the desired outputlength octet length of key material,
the T-PRF is calculated as follows:
S = label + 0x00 + seed
T-PRF output = T1 + T2 + T3 + T4 + ... + Tn
T1 = HMAC-SHA1 (key, S + outputlength + 0x01)
T2 = HMAC-SHA1 (key, T1 + S + outputlength + 0x02)
T3 = HMAC-SHA1 (key, T2 + S + outputlength + 0x03)
T4 = HMAC-SHA1 (key, T3 + S + outputlength + 0x04)
Where '+' indicates concatenation and "\0" is a NULL character. Each
Ti generates 20-octets of keying material, the last Tn may be
truncated to accommodate the desired length specified by
outputlength.
6. IANA Considerations
This section provides guidance to the Internet Assigned Numbers
Authority (IANA) regarding registration of values related to the EAP
protocol, in accordance with BCP 26, [RFC2434].
There is a name space in EAP-FAST that requires registration: TLV
Types. All these numbers may be assigned by Specification Required
as defined in BCP 26.
The various values under Vendor-Specific TLV are assigned by Private
Use and do not need to be assigned by IANA.
7. Security Considerations
EAP-FAST is designed with a focus on wireless media, where the medium
itself is inherent to eavesdropping. Whereas in wired media, an
attacker would have to gain physical access to the wired medium;
wireless media enables anyone to capture information as it is
transmitted over the air, enabling passive attacks. Thus, physical
security can not be assumed and security vulnerabilities are far
greater. The threat model used for the security evaluation of EAP-
FAST is that defined in the EAP [RFC3748].
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7.1 Mutual Authentication and Integrity Protection
EAP-FAST as a whole, provides message and integrity protection by
establishing a secure tunnel for protecting the authentication
method(s). The confidentiality and integrity protection is that
defined by TLS [RFC 2246] and provides the same security strengths
afforded by TLS employing a strong entropy shared master secret.
When EAP-FAST is invoked for enabling network access, mutual
authentication is first achieved by proof of a mutually shared unique
PAC-Key during the tunnel establishment and optional inner method
authentication. Further, the Crypto-Binding TLV is enforced to be
run after any EAP method that supports (mutual) authentication
ensuring that it was the same peer and EAP server that communicated
in all transpired methods (including tunnel establishment).
The Result TLV is protected and conveys the true Success or Failure
of EAP-FAST and should be used as the indicator of its success or
failure respectively. However, as EAP must terminate with a clear
text EAP Success or Failure, a peer will also receive a clear text
EAP success or failure. The received clear text EAP success or
failure must match that received in the Result TLV; the peer SHOULD
silently discard those clear text EAP success or failure messages
that do not coincide with the status sent in the protected Result
TLV.
7.2 Method Negotiation
As is true for any negotiated EAP protocol, NAK packets used to
suggest an alternate authentication method are sent unprotected and
as such, are subject to spoofing. During EAP method negotiation, NAK
packets may be interjected as active attacks to negotiate down to a
weaker form of authentication, such as EAP-MD5 (which only provides
one way authentication and does not derive a key). Since a
subsequent protected EAP conversation can take place within the TLS
session, selection of EAP-FAST as an authentication method does not
limit the potential secondary authentication methods. As a result,
the only legitimate reason for a peer to NAK EAP-FAST as an
authentication method is that it does not support it. Where the
additional security of EAP-FAST is required, the server shall best
determine how to respond to a NAK as this is beyond the scope of this
specification.
Inner method negotiation is protected by the mutually authenticated
TLS tunnel established in EAP-FAST and immune to attacks. An
attacker cannot readily determine the EAP method used, except perhaps
by traffic analysis.
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7.3 Separation of the EAP Server and the Authenticator
When EAP-FAST is successfully invoked to gain network access, the EAP
endpoints will mutually authenticate, and derive a session key for
subsequent use in link layer security. Since it is presumed that the
peer and EAP client reside on the same machine, it is necessary for
the EAP client module to pass the session key to the link layer
encryption module.
As EAP-FAST is defined to achieve mutual authentication between a
peer and AS, it will not achieve direct authentication to the
Authenticator (which is true for most if not all currently specified
EAP methods).
It is implied that there is an established trust between
Authenticator and AS before the AS securely distributes the session
keys to the authenticator. Using the transitive property and the
authenticator to AS trust assumption, if the AS trusts the
authenticator and distributes the session key to the authenticator,
and the peer has successfully gained authorization by mutually
deriving fresh session keys, the peer may then presume trust with the
authenticator who can prove it has those session keys. Note however,
that this presumed trust does not authenticate the authenticator to
the peer, it merely proves that the AS has a trust relationship with
said authenticator. Further, it is presumed that a secure mechanism
is used by the AS to distribute the session key to the authenticator.
In the case of the AS and the home AAA server logical model, similar
security properties hold as that between the AS and authenticator.
Though in general, it is highly recommended that the AAA server be
reside on the same host as the AS. In both cases, the presumed trust
between authenticator and AS as well as AS and AAA server as well as
the security in the transport (such as IPsec) and key delivery (such
as NIST approved key wrapping) mechanisms for these links are outside
the scope of the EAP-FAST specification. Without these presumed
trusts and secure transport mechanisms, security vulnerabilities will
exist.
7.4 Separation of Phase 1 and Phase 2 Servers
Separation of the EAP-FAST Phase 1 from the Phase 2 conversation is
not recommended. Without a trust relationship and proper protection
(such as IPsec) for RADIUS, by allowing a the Phase 1 conversation to
be terminated at a different (proxy) AS (AS1) than the Phase 2
conversation (terminated at AS2), vulnerabilities are introduced
since clear text transmission between AS1 and AS2 ensue. Some
vulnerabilities include:
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o Loss of identity protection
o Offline dictionary attacks
o Lack of policy enforcement
In order to find the proper EAP-FAST destination, the peer SHOULD
place a Network Access Identifier (NAI) conforming to [RFC2486] in
the clear-text Identity Response.
There may be cases where a natural trust relationship exists between
the (foreign) authentication server and final EAP server, such as on
a campus or between two offices within the same company, where there
is no danger in revealing the identity of the station to the
authentication server. In these cases, using a proxy solution
without end to end protection of EAP-FAST MAY be used. The EAP-FAST
encrypting/decrypting gateway SHOULD provide support for IPsec
protection of RADIUS in order to provide confidentiality for the
portion of the conversation between the gateway and the EAP server,
as described in [RFC3162].
7.5 Mitigation of Known Vulnerabilities and Protocol Deficiencies
EAP-FAST addresses the known deficiencies and weaknesses in the EAP
method. By employing a shared secret between the peer and server to
establish a secured tunnel, EAP-FAST enables:
o Per packet confidentiality and integrity protection
o User identity protection
o Better support for notification messages
o Protected EAP inner method negotiation
o Sequencing of EAP methods
o Strong mutually derived master session keys
o Acknowledged success/failure indication
o Faster re-authentications through session resumption
o Mitigation of dictionary attacks
o Mitigation of man-in-the-middle attacks
o Mitigation of some denial of service attacks
It should be noted that EAP-FAST as in many other authentication
protocols, a denial of service attack can be easily mounted by
adversaries imposing as either peer or AS and failing to present the
proper credential. This is an inherent problem in most
authentication or key agreement protocols and is so noted for EAP-
FAST as well.
EAP-FAST protection addresses a number of weaknesses present in LEAP,
PEAPv1, EAP-TTLS and the inner EAP methods used in the EAP- FAST
Authentication Phase 2 conversation. These weaknesses have been
described in draft-puthenkulam-eap-binding-03.txt.
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EAP-FAST was designed with a focus on protected authentication
methods that typically rely on weak credentials, such as password
based secrets. To that extent, the EAP-FAST Authentication mitigates
several vulnerabilities such as dictionary attacks by protecting the
weak credential based authentication method. The protection is based
on strong cryptographic algorithms in TLS to provide message
confidentiality and integrity respectively. The keys derived for the
protection relies on strong random challenges provided by both peer
and AS as well as a shared secret with strong entropy (minimally 32
octets). It is recommended that peers provide strong random number
generators that can satisfy the criteria as that described by NIST
Special Publication 800-22b (e.g. NIST SP800-22b). The AS acting as
the PAC distributor must generate unique and randomly generated 32
octet keys for each peer.
7.5.1 User Identity Protection and Verification
As EAP-FAST employs TLS to establish a secure tunnel, the initial
Identity request/response may be omitted as it must be transmitted in
the clear and thus subject to snooping and forgery. It may be
omitted also in deployments where it is known that all users are
required to authenticate with EAP-FAST. Alternately, an anonymous
identity may be used in the Identity response.
If the initial Identity request/response has been tampered with, the
AS may be unable to verify the peer's identity. For example, the
peer's user name may not be valid or may not be within a realm
handled by the AS. Rather than attempting to proxy the
authentication to the server within the correct realm, the AS should
terminate the conversation.
The EAP-FAST peer can present the server with multiple identities.
This includes the claim of identity within the initial EAP- Response/
Identity (MyID) packet, which is typically used to route the EAP
conversation to the appropriate home back end AS. There may also be
subsequent EAP-Response/Identity packets sent by the peer once the
secure tunnel has been established.
The PAC-Opaque field conveyed by the peer to the AS contains the
peer's identity that should be validated with at least one identity
presented in the EAP-FAST Authentication Phase 2 conversation. This
ensures that the PAC-Key is employed by the intended peer. Though
EAP-FAST implementations should not attempt to compare the EAP-FAST
Authentication Phase 1 Identity disclosed in the EAP Identity
response packet with those Identities claimed in Phase 2; the AS
should match the identity disclosed in the PAC-Opaque field with at
least one identity disclosed in EAP-FAST Authentication Phase 2.
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Note that since TLS client certificates are sent in the clear, if
identity protection is required, then it is possible for the TLS
authentication to be re-negotiated after the first server
authentication. Alternatively, if identity protection is required,
then it is possible to perform certificate authentication using an
EAP method (for example: EAP-TLS) within the TLS session in EAP-FAST
Phase 2.
To accomplish TLS restart, the server will typically not request a
certificate in the server_hello, then after the server_finished
message is sent, and before EAP-FAST Phase 2, the server MAY send a
TLS hello_request. This allows the client to perform client
authentication by sending a client_hello if it wants to, or send a
no_renegotiation alert to the server indicating that it wants to
continue with EAP-FAST Phase 2 instead. Assuming that the client
permits renegotiation by sending a client_hello, then the server will
respond with server_hello, a certificate and certificate_request
messages. The client replies with certificate, client_key_exchange
and certificate_verify messages. Since this re-negotiation occurs
within the encrypted TLS channel, it does not reveal client
certificate details.}
7.5.2 Dictionary Attack Resistance
EAP-FAST was designed with a focus on protected authentication
methods that typically rely on weak credentials, such as password
based secrets. To that extent, by establishing a mutually
authenticated protected tunnel, EAP-FAST mitigates dictionary attacks
by protecting the weak credential based authentication method. The
protection is based on strong cryptographic algorithms such as RC4
and HMAC-SHA1 to provide message confidentiality and integrity
respectively. The keys derived for the protection relies on strong
random challenges provided by both peer and AS as well as a strong
entropy (minimally 32 octet) shared secret. The AS acting as the PAC
distributor MUST generate unique and randomly generated 32 octet keys
for each peer.
7.5.3 Protection against MitM Attacks
The recommended solution is to always deploy authentication methods
with protection of EAP-FAST. If a deployment chooses to allow an EAP
method protected by EAP-FAST without protection of EAP-FAST at the
same time, then this opens up a possibility of a Compound
Authentication Binding man-in-the-middle attack [MITM].
A man-in-the-middle can spoof the client to authenticate to it
instead of the real EAP server; and forward the authentication to the
real server over a protected tunnel. Since the attacker has access
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to the keys derived from the tunnel, it can gain access to the
network. EAP-FAST prevents this attack in two ways:
1. An adversary must have the corresponding peer's PAC-Key to
mutually authenticate during EAP-FAST Authentication Phase 1
establishment of a secure tunnel; and
2. By using the keys generated by the inner authentication method in
the crypto-binding exchange described in above protected
termination section 6.5.
Both compound MAC and compound session key approaches are used to
prevent the aforementioned man-in-the-middle attack. Both the peer
and the EAP server MUST derive compound MAC and compound session keys
using the procedure described in Section 6.7. As a strong PAC-Key is
used to establish mutual authentication in EAP-FAST Phase 1, this
attack is also prevented if the inner authentication method does not
generate keys. Thus, most EAP authentication methods are protected
from these MitM attacks when protected by EAP-FAST.
To summarize, EAP-FAST Authentication mitigates most MitM attacks in
the following ways:
1. Identity binding with PAC-Key: in presenting the PAC-Opaque field
to the AS, a peer is presenting an authenticated credential.
With the user identity serving as another validation point for
the inner EAP authentication method, a MitM may not interject and
impersonate itself as the peer unless it has recovered the PAC-
Key as well as the PAC-Opaque field. Thus, the PAC-Key binding
to an Identity prevents an adversary from interjection regardless
of whether the authentication method generates session keys.
2. Cryptographic binding of EAP-FAST Phase 1 and all methods within
Phase 2: by cryptographically binding key material generated in
all methods, peer and AS are assured that they were the sole
participants of all transpired methods.
7.5.4 PAC Validation with User Credentials
The PAC-Opaque field is consumed by the AS during a network access
EAP-FAST invocation to both acquire and validate the authenticity of
the PAC credential. However, during the EAP-FAST Phase 1
conversation it validates the peer based on the secret, PAC-Key and
not on the identity. Further, since the EAP-FAST Phase 1
conversation occurs in clear text, it is feasible for an adversary to
acquire a PAC-Opaque credential.
While a PAC-Opaque credential can be easily acquired, the shared
secret, PAC-Key is not discernible from the PAC-Opaque field. Thus,
an adversary must resort to a brute force attack to gain the PAC- Key
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from PAC-Opaque information.
Another feasible scenario due to the clear text transmission is the
spoofing of the PAC-Opaque field. While the PAC-Opaque is
authenticated to mitigate forgery, a denial of service and potential
user lockout (based on deployment configurations that may choose to
lock a peer after a configurable number of failed attempts) is
feasible.
The final validation and binding of the PAC credential is the
identity validation in the EAP-FAST Phase 2 conversation. A
compliant implementation of EAP-FAST MUST match the identity
presented to the AS in the PAC-Opaque field with at minimum one of
the identities provided in the EAP-FAST Phase 2 authentication
method. This validation provides another binding to ensure that the
intended peer (based on identity) has successfully completed the EAP-
FAST Phase 1 and proved identity in the Phase 2 conversations. This
validation helps mitigate the MitM attack as described in Section
12.5.3.
7.6 Protecting against Forged Clear Text EAP Packets
As described earlier, EAP Success and EAP Failure packets are in
general sent in clear text and may be forged by an attacker without
fear of detection. Forged EAP Failure packets can be used to
convince an EAP peer to disconnect. Forged EAP Success packets may
be used by any rogue to convince a peer to let itself access the
network, even though the authenticator has not authenticated itself
to the peer.
By providing message confidentiality and integrity, EAP-FAST provides
protection against these attacks. Once the peer and AS initiate the
EAP-FAST Authentication Phase 2, compliant EAP-FAST implementations
must silently discard all clear text EAP messages unless both the
EAP-FAST peer and server have indicated success or failure using a
protected mechanism. Protected mechanisms include TLS alert
mechanism and the protected termination mechanism described in
Section 6.5.
The success/failure decisions sent by a protected mechanism indicate
the final decision of the EAP-FAST authentication conversation.
After a success/failure result has been indicated by a protected
mechanism, the EAP-FAST peer can process unprotected EAP success and
EAP failure message; however the peer must ignore any unprotected EAP
success or failure messages where the result does not match the
result of the protected mechanism.
To abide by RFC 3748, the AS must send a clear text EAP Success or
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EAP Failure packet to terminate the EAP conversation, so that no
response is possible. However, since EAP Success and EAP Failure
packets are not retransmitted, if the final packet is lost, then
authentication will fail. As a result, where packet loss is expected
to be non-negligible, unacknowledged success/failure indications lack
robustness.
While an EAP-FAST protected EAP Success or EAP Failure packet should
not be a final packet in an EAP-FAST conversation, it may be feasible
based on the conditions stated above and construed as an optimization
savings of a full round-trip in low packet loss environments.
7.7 Implementation
Both server and in particular, client implementations must provide a
suitably strong PRNG to ensure good entropy challenges. Suitable
recommendations for PRNGs can be found in PKCS#5, PKCS#11 and
criteria for suitable PRNGS are also defined by NIST Special
Publication 800-22b.
7.8 Server Certificate Validation
As part of the TLS negotiation, the server presents a certificate to
the peer. The peer MUST verify the validity of the EAP server
certificate, and SHOULD also examine the EAP server name presented in
the certificate, in order to determine whether the EAP server can be
trusted. Please note that in the case where the EAP authentication
is remoted, the EAP server will not reside on the same machine as the
authenticator, and therefore the name in the EAP server's certificate
cannot be expected to match that of the intended destination. In
this case, a more appropriate test might be whether the EAP server's
certificate is signed by a CA controlling the intended destination
and whether the EAP server exists within a target sub-domain.
7.9 Security Claims
This section provides needed security claim requirement for EAP
[RFC3748].
Auth. mechanism: Tunneled authentication as well as pre-
shared key.
Ciphersuite negotiation: Yes
Mutual authentication: Yes
Integrity protection: Yes,Only EAP Type Data field and inner EAP
methods contained in this field are
protected.
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Replay protection: Yes
Confidentiality: Yes
Key derivation: Yes
Key strength: TLS key strength, may be enhanced by binding
keys with inner methods
Dictionary attack prot.: yes
Fast reconnect: yes
Cryptographic binding: yes
Session independence: yes
Fragmentation: yes
Key Hierarchy: yes
Channel binding: No, but TLVs could be defined for this.
8. Acknowledgements
The EAP-FAST design and protocol specification is based on the ideas
and hard efforts of Pad Jakkahalli, Mark Krischer, Doug Smith, Ilan
Frenkel, Glen Zorn and Jeremy Steiglitz of Cisco Systems, Inc.
The TLV processing was inspired from work on PEAPv2 with Ashwin
Palekar, Dan Smith and Simon Josefsson. Helpful review comments were
provided by Russ Housley and Jari Arkko.
9. References
9.1 Normative References
[I-D.cam-winget-eap-fast-provisioning]
Cam-Winget, N., "Dynamic Provisioning using EAP-FAST",
draft-cam-winget-eap-fast-provisioning-01 (work in
progress), July 2005.
[I-D.salowey-tls-ticket]
Salowey, J., "Transport Layer Security Session Resumption
without Server-Side State", draft-salowey-tls-ticket-04
(work in progress), September 2005.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC2246] Dierks, T. and C. Allen, "The TLS Protocol Version 1.0",
RFC 2246, January 1999.
[RFC2434] Narten, T. and H. Alvestrand, "Guidelines for Writing an
IANA Considerations Section in RFCs", BCP 26, RFC 2434,
October 1998.
[RFC3268] Chown, P., "Advanced Encryption Standard (AES)
Cam-Winget, et al. Expires April 22, 2006 [Page 43]
Internet-Draft EAP-FAST October 2005
Ciphersuites for Transport Layer Security (TLS)",
RFC 3268, June 2002.
[RFC3546] Blake-Wilson, S., Nystrom, M., Hopwood, D., Mikkelsen, J.,
and T. Wright, "Transport Layer Security (TLS)
Extensions", RFC 3546, June 2003.
[RFC3748] Aboba, B., Blunk, L., Vollbrecht, J., Carlson, J., and H.
Levkowetz, "Extensible Authentication Protocol (EAP)",
RFC 3748, June 2004.
9.2 Informative References
[RFC2486] Aboba, B. and M. Beadles, "The Network Access Identifier",
RFC 2486, January 1999.
[RFC2716] Aboba, B. and D. Simon, "PPP EAP TLS Authentication
Protocol", RFC 2716, October 1999.
[RFC3162] Aboba, B., Zorn, G., and D. Mitton, "RADIUS and IPv6",
RFC 3162, August 2001.
Authors' Addresses
Nancy Cam-Winget
Cisco Systems
3625 Cisco Way
San Jose, CA 95134
US
Email: ncamwing@cisco.com
David McGrew
Cisco Systems
San Jose, CA 95134
US
Email: mcgrew@cisco.com
Cam-Winget, et al. Expires April 22, 2006 [Page 44]
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Joseph Salowey
Cisco Systems
2901 3rd Ave
Seattle, WA 98121
US
Email: jsalowey@cisco.com
Hao Zhou
Cisco Systems
4125 Highlander Parkway
Richfield, OH 44286
US
Email: hzhou@cisco.com
Appendix A. Examples
A.1 Successful Authentication
The following exchanges show a successful EAP-FAST authentication
with optional PAC refreshment, the conversation will appear as
follows:
Authenticating Peer Authenticator
------------------- -------------
<- EAP-Request/
Identity
EAP-Response/
Identity (MyID1) ->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(EAP-FAST Start, S bit set, A-ID)
EAP-Response/
EAP-Type=EAP-FAST, V=1
(TLS client_hello with
PAC-Opaque in SessionTicket extension)->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(TLS server_hello,
(TLS change_cipher_spec,
TLS finished)
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EAP-Response/
EAP-Type=EAP-FAST, V=1 ->
(TLS change_cipher_spec,
TLS finished)
TLS channel established
(messages sent within the TLS channel)
<- EAP Payload TLV, EAP-Request,
EAP-GTC, Challenge
EAP Payload TLV, EAP-Response,
EAP-GTC, Response with both
user name and password) ->
optional additional exchanges (new pin mode,
password change etc.) ...
<- Intermediate-Result TLV (Success)
Crypto-Binding TLV (Request)
Intermediate-Result TLV (Success)
Crypto-Binding TLV(Response) ->
<- Result TLV (Success)
(Optional PAC TLV)
Result TLV (Success)
(PAC TLV Acknowledgment) ->
TLS channel torn down
(messages sent in clear text)
<- EAP-Success
A.2 Failed Authentication
The following exchanges show a failed EAP-FAST authentication due to
wrong user credentials, the conversation will appear as follows:
Authenticating Peer Authenticator
------------------- -------------
<- EAP-Request/
Identity
EAP-Response/
Cam-Winget, et al. Expires April 22, 2006 [Page 46]
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Identity (MyID1) ->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(EAP-FAST Start, S bit set, A-ID)
EAP-Response/
EAP-Type=EAP-FAST, V=1
(TLS client_hello with
PAC-Opaque in SessionTicket extension)->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(TLS server_hello,
(TLS change_cipher_spec,
TLS finished)
EAP-Response/
EAP-Type=EAP-FAST, V=1 ->
(TLS change_cipher_spec,
TLS finished)
TLS channel established
(messages sent within the TLS channel)
<- EAP Payload TLV, EAP-Request,
EAP-GTC, Challenge
EAP Payload TLV, EAP-Response,
EAP-GTC, Response with both
user name and password) ->
<- EAP Payload TLV, EAP-Request,
EAP-GTC, error message
EAP Payload TLV, EAP-Response,
EAP-GTC, empty data packet to
acknowledge unrecoverable error) ->
<- Result TLV (Failure)
Result TLV (Failure) ->
TLS channel torn down
(messages sent in clear text)
<- EAP-Failure
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A.3 Full TLS Handshake using Certificate-based Cipher Suite
In the case where an abbreviated TLS handshake is tried and failed
and falls back to certificate based full TLS handshake occurs within
EAP-FAST Phase 1, the conversation will appear as follows:
Authenticating Peer Authenticator
------------------- -------------
<- EAP-Request/Identity
EAP-Response/
Identity (MyID1) ->
// Identity sent in the clear. May be a hint to help route
the authentication request to EAP server, instead of the
full user identity.
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(EAP-FAST Start, S bit set, A-ID)
EAP-Response/
EAP-Type=EAP-FAST, V=1
(TLS client_hello
[PAC-Opaque extension])->
// Peer sends PAC-Opaque of Tunnel PAC along with a list of
ciphersuites supported. If Server rejects the PAC-
Opaque, if falls through to the full TLS handshake
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(TLS server_hello,
TLS certificate,
[TLS server_key_exchange,]
[TLS certificate_request,]
TLS server_hello_done)
EAP-Response/
EAP-Type=EAP-FAST, V=1
([TLS certificate,]
TLS client_key_exchange,
[TLS certificate_verify,]
TLS change_cipher_spec,
TLS finished) ->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(TLS change_cipher_spec,
TLS finished,
EAP-Payload-TLV[EAP-Request/
Identity])
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// TLS channel established
(messages sent within the TLS channel)
// First EAP Payload TLV is piggybacked to the TLS Finished as
Application Data and protected by the TLS tunnel
EAP-Payload-TLV
[EAP-Response/Identity (MyID2)]->
// identity protected by TLS.
<- EAP-Payload-TLV
[EAP-Request/EAP-Type=X]
EAP-Payload-TLV
[EAP-Response/EAP-Type=X] ->
// Method X exchanges followed by Protected Termination
<- Crypto-Binding TLV (Version=1,
EAP-FAST Version=1, Nonce,
CompoundMAC),
Result TLV (Success)
Crypto-Binding TLV (Version=1,
EAP-FAST Version=1, Nonce,
CompoundMAC),
Result-TLV (Success) ->
// TLS channel torn down
(messages sent in clear text)
<- EAP-Success
A.4 Client authentication during Phase 1 with identity privacy
In the case where a certificate based TLS handshake occurs within
EAP-FAST Phase 1, and client certificate authentication and identity
privacy is desired, the conversation will appear as follows:
Authenticating Peer Authenticator
------------------- -------------
<- EAP-Request/Identity
EAP-Response/
Identity (MyID1) ->
// Identity sent in the clear. May be a hint to help route
the authentication request to EAP server, instead of the
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full user identity.
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(EAP-FAST Start, S bit set, A-ID)
EAP-Response/
EAP-Type=EAP-FAST, V=1
(TLS client_hello)->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(TLS server_hello,
TLS certificate,
[TLS server_key_exchange,]
[TLS certificate_request,]
TLS server_hello_done)
EAP-Response/
EAP-Type=EAP-FAST, V=1
(TLS client_key_exchange,
TLS change_cipher_spec,
TLS finished) ->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(TLS change_cipher_spec,
TLS finished,TLS Hello-Request)
// TLS channel established
(messages sent within the TLS channel)
// TLS Hello-Request is piggybacked to the TLS Finished as
Handshake Data and protected by the TLS tunnel
TLS client_hello ->
<- TLS server_hello,
TLS certificate,
[TLS server_key_exchange,]
[TLS certificate_request,]
TLS server_hello_done
[TLS certificate,]
TLS client_key_exchange,
[TLS certificate_verify,]
TLS change_cipher_spec,
TLS finished ->
<- TLS change_cipher_spec,
TLS finished,
Result TLV (Success)
Cam-Winget, et al. Expires April 22, 2006 [Page 50]
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Result-TLV (Success)) ->
//TLS channel torn down
(messages sent in clear text)
<- EAP-Success
A.5 Fragmentation and Reassembly
In the case where EAP-FAST fragmentation is required, the
conversation will appear as follows:
Authenticating Peer Authenticator
------------------- -------------
<- EAP-Request/
Identity
EAP-Response/
Identity (MyID) ->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(EAP-FAST Start, S bit set, A-ID)
EAP-Response/
EAP-Type=EAP-FAST, V=1
(TLS client_hello)->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(TLS server_hello,
TLS certificate,
[TLS server_key_exchange,]
[TLS certificate_request,]
TLS server_hello_done)
(Fragment 1: L, M bits set)
EAP-Response/
EAP-Type=EAP-FAST, V=1 ->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(Fragment 2: M bit set)
EAP-Response/
EAP-Type=EAP-FAST, V=1 ->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(Fragment 3)
EAP-Response/
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EAP-Type=EAP-FAST, V=1
([TLS certificate,]
TLS client_key_exchange,
[TLS certificate_verify,]
TLS change_cipher_spec,
TLS finished)
(Fragment 1: L, M bits set)->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
EAP-Response/
EAP-Type=EAP-FAST, V=1
(Fragment 2)->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(TLS change_cipher_spec,
TLS finished,
[EAP-Payload-TLV[
EAP-Request/Identity]])
// TLS channel established
(messages sent within the TLS channel)
// First EAP Payload TLV is piggybacked to the TLS Finished as
Application Data and protected by the TLS tunnel
EAP-Payload-TLV
[EAP-Response/Identity (MyID2)]->
// identity protected by TLS.
<- EAP-Payload-TLV
[EAP-Request/EAP-Type=X]
EAP-Payload-TLV
[EAP-Response/EAP-Type=X] ->
// Method X exchanges followed by Protected Termination
<- Crypto-Binding TLV (Version=1,
EAP-FAST Version=1, Nonce,
CompoundMAC),
Result TLV (Success)
Crypto-Binding TLV (Version=1,
EAP-FAST Version=1, Nonce,
CompoundMAC),
Result-TLV (Success) ->
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// TLS channel torn down
(messages sent in clear text)
<- EAP-Success
A.6 Sequence of EAP Methods
Where EAP-FAST is negotiated, with a sequence of EAP method X
followed by method Y, the conversation will occur as follows:
Authenticating Peer Authenticator
------------------- -------------
<- EAP-Request/
Identity
EAP-Response/
Identity (MyID1) ->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(EAP-FAST Start, S bit set, A-ID)
EAP-Response/
EAP-Type=EAP-FAST, V=1
(TLS client_hello)->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(TLS server_hello,
TLS certificate,
[TLS server_key_exchange,]
[TLS certificate_request,]
TLS server_hello_done)
EAP-Response/
EAP-Type=EAP-FAST, V=1
([TLS certificate,]
TLS client_key_exchange,
[TLS certificate_verify,]
TLS change_cipher_spec,
TLS finished) ->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(TLS change_cipher_spec,
TLS finished,
EAP-Payload-TLV[
EAP-Request/Identity])
// TLS channel established
(messages sent within the TLS channel)
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// First EAP Payload TLV is piggybacked to the TLS Finished as
Application Data and protected by the TLS tunnel
EAP-Payload-TLV
[EAP-Response/Identity] ->
<- EAP-Payload-TLV
[EAP-Request/EAP-Type=X]
EAP-Payload-TLV
[EAP-Response/EAP-Type=X] ->
// Optional additional X Method exchanges...
<- EAP-Payload-TLV
[EAP-Request/EAP-Type=X]
EAP-Payload-TLV
[EAP-Response/EAP-Type=X]->
<- Intermediate Result TLV (Success),
Crypto-Binding TLV (Version=1
EAP-FAST Version=1, Nonce,
CompoundMAC),
EAP Payload TLV [EAP-Type=Y],
// Next EAP conversation started after successful completion
of previous method X. The Intermediate-Result and Crypto-
Binding TLVs are sent in next packet to minimize round-
trips. In this example, identity request is not sent
before negotiating EAP-Type=Y.
// Compound MAC calculated using Keys generated from
EAP methods X and the TLS tunnel.
Intermediate Result TLV (Success),
Crypto-Binding TLV (Version=1,
EAP-FAST Version=1, Nonce,
CompoundMAC),
EAP-Payload-TLV [EAP-Type=Y] ->
// Optional additional Y Method exchanges...
<- EAP Payload TLV [
EAP-Type=Y]
EAP Payload TLV
[EAP-Type=Y] ->
Cam-Winget, et al. Expires April 22, 2006 [Page 54]
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<- Intermediate-Result-TLV (Success),
Crypto-Binding TLV (Version=1
EAP-FAST Version=1, Nonce,
CompoundMAC),
Result TLV (Success)
Intermediate-Result-TLV (Success),
Crypto-Binding TLV (Version=1,
EAP-FAST Version=1, Nonce,
CompoundMAC),
Result-TLV (Success) ->
// Compound MAC calculated using Keys generated from EAP
methods X and Y and the TLS tunnel. Compound Keys
generated using Keys generated from EAP methods X and Y;
and the TLS tunnel.
// TLS channel torn down (messages sent in clear text)
<- EAP-Success
A.7 Failed Crypto-binding
The following exchanges show a failed crypto-binding validation. The
conversation will appear as follows:
Authenticating Peer Authenticator
------------------- -------------
<- EAP-Request/
Identity
EAP-Response/
Identity (MyID1) ->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(EAP-FAST Start, S bit set, A-ID)
EAP-Response/
EAP-Type=EAP-FAST, V=1
(TLS client_hello without
PAC-Opaque extension)->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(TLS Server Key Exchange
TLS Server Hello Done)
EAP-Response/
EAP-Type=EAP-FAST, V=1 ->
(TLS Client Key Exchange
Cam-Winget, et al. Expires April 22, 2006 [Page 55]
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TLS change_cipher_spec,
TLS finished)
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(TLS change_cipher_spec
TLS finished)
EAP-Payload-TLV[
EAP-Request/Identity])
// TLS channel established
(messages sent within the TLS channel)
// First EAP Payload TLV is piggybacked to the TLS Finished as
Application Data and protected by the TLS tunnel
EAP-Payload TLV/
EAP Identity Response ->
<- EAP Payload TLV, EAP-Request,
(EAP-MSCHAPV2, Challenge)
EAP Payload TLV, EAP-Response,
(EAP-MSCHAPV2, Response) ->
<- EAP Payload TLV, EAP-Request,
(EAP-MSCHAPV2, Success Request)
EAP Payload TLV, EAP-Response,
(EAP-MSCHAPV2, Success Response) ->
<- Crypto-Binding TLV (Version=1,
EAP-FAST Version=1, Nonce,
CompoundMAC),
Result TLV (Success)
Result TLV (Failure)
Error TLV with
(Error Code = 2001) ->
// TLS channel torn down
(messages sent in clear text)
<- EAP-Failure
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A.8 Stateless Session Resume Using Authorization PAC
The following exchanges show a successful server stateless EAP-FAST
session resume using Tunnel PAC with User Authorization PAC. The
conversation will appear as follows:
Authenticating Peer Authenticator
------------------- -------------
<- EAP-Request/
Identity
EAP-Response/
Identity (MyID1) ->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(EAP-FAST Start, S bit set, A-ID)
EAP-Response/
EAP-Type=EAP-FAST, V=1
(TLS client_hello with
PAC-Opaque extension)->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(TLS server_hello,
(TLS change_cipher_spec,
TLS finished)
EAP-Response/
EAP-Type=EAP-FAST, V=1
(TLS change_cipher_spec,
TLS finished)
(PAC-TLV with User Authorization
PAC) ->
// TLS channel established
(messages sent within the TLS channel)
// User Authorization PAC is piggybacked to the TLS Finished as
Application Data and protected by the TLS tunnel
<- Result TLV (Success)
// User Authorization PAC is valid and inner methods are bypassed
Result TLV (Success) ->
// TLS channel torn down
(messages sent in clear text)
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<- EAP-Success
A.9 Sequence of EAP Method with Vendor-Specific TLV Exchange
Where EAP-FAST is negotiated, with a sequence of EAP method followed
by Vendor-Specific TLV exchange, the conversation will occur as
follows:
Authenticating Peer Authenticator
------------------- -------------
<- EAP-Request/
Identity
EAP-Response/
Identity (MyID1) ->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(EAP-FAST Start, S bit set, A-ID)
EAP-Response/
EAP-Type=EAP-FAST, V=1
(TLS client_hello)->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(TLS server_hello,
TLS certificate,
[TLS server_key_exchange,]
[TLS certificate_request,]
TLS server_hello_done)
EAP-Response/
EAP-Type=EAP-FAST, V=1
([TLS certificate,]
TLS client_key_exchange,
[TLS certificate_verify,]
TLS change_cipher_spec,
TLS finished) ->
<- EAP-Request/
EAP-Type=EAP-FAST, V=1
(TLS change_cipher_spec,
TLS finished,
EAP-Payload-TLV[
EAP-Request/Identity])
// TLS channel established
(messages sent within the TLS channel)
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// First EAP Payload TLV is piggybacked to the TLS Finished as
Application Data and protected by the TLS tunnel
EAP-Payload-TLV
[EAP-Response/Identity] ->
<- EAP-Payload-TLV
[EAP-Request/EAP-Type=X]
EAP-Payload-TLV
[EAP-Response/EAP-Type=X] ->
<- EAP-Payload-TLV
[EAP-Request/EAP-Type=X]
EAP-Payload-TLV
[EAP-Response/EAP-Type=X]->
<- Intermediate Result TLV (Success),
Crypto-Binding TLV (Version=1
EAP-FAST Version=1, Nonce,
CompoundMAC),
Vendor-Specific TLV,
// Vendor Specific TLV exchange started after successful
completion of previous method X. The Intermediate-Result
and Crypto-Binding TLVs are sent with Vendor Specific TLV
in next packet to minimize round-trips.
// Compound MAC calculated using Keys generated from
EAP methods X and the TLS tunnel.
Intermediate Result TLV (Success),
Crypto-Binding TLV (Version=1,
EAP-FAST Version=1, Nonce,
CompoundMAC),
Vendor-Specific TLV ->
// Optional additional Vendor-Specific TLV exchanges...
<- Vendor-Specific TLV
Vendor Specific TLV ->
<- Result TLV (Success)
Result-TLV (Success) ->
// TLS channel torn down (messages sent in clear text)
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<- EAP-Success
Appendix B. Test Vectors
B.1 Key Derivation
PAC KEY:
0B 97 39 0F 37 51 78 09 81 1E FD 9C 6E 65 94 2B
63 2C E9 53 89 38 08 BA 36 0B 03 7C D1 85 E4 14
Server_hello Random
3F FB 11 C4 6C BF A5 7A 54 40 DA E8 22 D3 11 D3
F7 6D E4 1D D9 33 E5 93 70 97 EB A9 B3 66 F4 2A
Client_hello Random
00 00 00 02 6A 66 43 2A 8D 14 43 2C EC 58 2D 2F
C7 9C 33 64 BA 04 AD 3A 52 54 D6 A5 79 AD 1E 00
Master_secret = T-PRF(PAC-Key,
"PAC to master secret label hash",
server_random + Client_random,
48)
4A 1A 51 2C 01 60 BC 02 3C CF BC 83 3F 03 BC 64
88 C1 31 2F 0B A9 A2 77 16 A8 D8 E8 BD C9 D2 29
38 4B 7A 85 BE 16 4D 27 33 D5 24 79 87 B1 C5 A2
Key_block = PRF(Master_secret,
"key expansion",
server_random + Client_random)
59 59 BE 8E 41 3A 77 74 8B B2 E5 D3 60 AC 4D 35
DF FB C8 1E 9C 24 9C 8B 0E C3 1D 72 C8 84 9D 57
48 51 2E 45 97 6C 88 70 BE 5F 01 D3 64 E7 4C BB
11 24 E3 49 E2 3B CD EF 7A B3 05 39 5D 64 8A 44
11 B6 69 88 34 2E 8E 29 D6 4B 7D 72 17 59 28 05
AF F9 B7 FF 66 6D A1 96 8F 0B 5E 06 46 7A 44 84
64 C1 C8 0C 96 44 09 98 FF 92 A8 B4 C6 42 28 71
Session Key Seed
D6 4B 7D 72 17 59 28 05 AF F9 B7 FF 66 6D A1 96
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8F 0B 5E 06 46 7A 44 84 64 C1 C8 0C 96 44 09 98
FF 92 A8 B4 C6 42 28 71
IMCK = T-PRF(SKS,
"Inner Methods Compound Keys",
ISK,
60)
Note: ISK is 32 bytes 0's.
16 15 3C 3F 21 55 EF D9 7F 34 AE C8 1A 4E 66 80
4C C3 76 F2 8A A9 6F 96 C2 54 5F 8C AB 65 02 E1
18 40 7B 56 BE EA A7 C5 76 5D 8F 0B C5 07 C6 B9
04 D0 69 56 72 8B 6B B8 15 EC 57 7B
[SIMCK 1]
16 15 3C 3F 21 55 EF D9 7F 34 AE C8 1A 4E 66 80
4C C3 76 F2 8A A9 6F 96 C2 54 5F 8C AB 65 02 E1
18 40 7B 56 BE EA A7 C5
MSK = T-PRF(S-IMCKn,
"Session Key Generating Function",
64);
4D 83 A9 BE 6F 8A 74 ED 6A 02 66 0A 63 4D 2C 33
C2 DA 60 15 C6 37 04 51 90 38 63 DA 54 3E 14 B9
27 99 18 1E 07 BF 0F 5A 5E 3C 32 93 80 8C 6C 49
67 ED 24 FE 45 40 A0 59 5E 37 C2 E9 D0 5D 0A E3
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B.2 Crypto-Binding MIC
[Compound MAC Key 1]
76 5D 8F 0B C5 07 C6 B9 04 D0 69 56 72 8B 6B B8
15 EC 57 7B
[Crypto-Binding TLV]
80 0C 00 38 00 01 01 00 D8 6A 8C 68 3C 32 31 A8 56 63 B6 40 21 FE
21 14 4E E7 54 20 79 2D 42 62 C9 BF 53 7F 54 FD AC 58 43 24 6E 30
92 17 6D CF E6 E0 69 EB 33 61 6A CC 05 C5 5B B7
[Server Nonce]
D8 6A 8C 68 3C 32 31 A8 56 63 B6 40 21 FE 21 14
4E E7 54 20 79 2D 42 62 C9 BF 53 7F 54 FD AC 58
[Compound MAC]
43 24 6E 30 92 17 6D CF E6 E0 69 EB 33 61 6A CC
05 C5 5B B7
Cam-Winget, et al. Expires April 22, 2006 [Page 62]
Internet-Draft EAP-FAST October 2005
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Cam-Winget, et al. Expires April 22, 2006 [Page 63]
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