Internet DRAFT - draft-aura-eap-noob
draft-aura-eap-noob
Network Working Group T. Aura
Internet-Draft Aalto University
Intended status: Standards Track M. Sethi
Expires: September 10, 2020 Ericsson
March 9, 2020
Nimble out-of-band authentication for EAP (EAP-NOOB)
draft-aura-eap-noob-08
Abstract
Extensible Authentication Protocol (EAP) provides support for
multiple authentication methods. This document defines the EAP-NOOB
authentication method for nimble out-of-band (OOB) authentication and
key derivation. The EAP method is intended for bootstrapping all
kinds of Internet-of-Things (IoT) devices that have no pre-configured
authentication credentials. The method makes use of a user-assisted
one-directional OOB message between the peer device and
authentication server to authenticate the in-band key exchange. The
device must have an input or output interface, such as a display,
microphone, speakers or blinking light, which can send or receive
dynamically generated messages of tens of bytes in length.
Status of This Memo
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Copyright (c) 2020 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3
2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 4
3. EAP-NOOB protocol . . . . . . . . . . . . . . . . . . . . . . 5
3.1. Protocol overview . . . . . . . . . . . . . . . . . . . . 5
3.2. Protocol messages and sequences . . . . . . . . . . . . . 8
3.2.1. Common handshake in all EAP-NOOB exchanges . . . . . 8
3.2.2. Initial Exchange . . . . . . . . . . . . . . . . . . 10
3.2.3. OOB Step . . . . . . . . . . . . . . . . . . . . . . 11
3.2.4. Completion Exchange . . . . . . . . . . . . . . . . . 13
3.2.5. Waiting Exchange . . . . . . . . . . . . . . . . . . 15
3.3. Protocol data fields . . . . . . . . . . . . . . . . . . 16
3.3.1. Peer identifier, realm and NAI . . . . . . . . . . . 16
3.3.2. Message data fields . . . . . . . . . . . . . . . . . 18
3.4. Fast reconnect and rekeying . . . . . . . . . . . . . . . 23
3.4.1. Persistent EAP-NOOB association . . . . . . . . . . . 23
3.4.2. Reconnect Exchange . . . . . . . . . . . . . . . . . 24
3.4.3. User reset . . . . . . . . . . . . . . . . . . . . . 27
3.5. Key derivation . . . . . . . . . . . . . . . . . . . . . 28
3.6. Error handling . . . . . . . . . . . . . . . . . . . . . 31
3.6.1. Invalid messages . . . . . . . . . . . . . . . . . . 33
3.6.2. Unwanted peer . . . . . . . . . . . . . . . . . . . . 33
3.6.3. State mismatch . . . . . . . . . . . . . . . . . . . 33
3.6.4. Negotiation failure . . . . . . . . . . . . . . . . . 33
3.6.5. Cryptographic verification failure . . . . . . . . . 34
3.6.6. Application-specific failure . . . . . . . . . . . . 34
4. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 35
4.1. Cryptosuites . . . . . . . . . . . . . . . . . . . . . . 35
4.2. Message Types . . . . . . . . . . . . . . . . . . . . . . 35
4.3. Error codes . . . . . . . . . . . . . . . . . . . . . . . 36
4.4. Domain name reservation considerations . . . . . . . . . 37
5. Implementation Status . . . . . . . . . . . . . . . . . . . . 38
5.1. Implementation with wpa_supplicant and hostapd . . . . . 38
5.2. Implementation on Contiki . . . . . . . . . . . . . . . . 39
5.3. Protocol modeling . . . . . . . . . . . . . . . . . . . . 39
6. Security considerations . . . . . . . . . . . . . . . . . . . 39
6.1. Authentication principle . . . . . . . . . . . . . . . . 39
6.2. Identifying correct endpoints . . . . . . . . . . . . . . 41
6.3. Trusted path issues and misbinding attacks . . . . . . . 42
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6.4. Peer identifiers and attributes . . . . . . . . . . . . . 43
6.5. Identity protection . . . . . . . . . . . . . . . . . . . 44
6.6. Downgrading threats . . . . . . . . . . . . . . . . . . . 44
6.7. Recovery from loss of last message . . . . . . . . . . . 45
6.8. EAP security claims . . . . . . . . . . . . . . . . . . . 46
7. References . . . . . . . . . . . . . . . . . . . . . . . . . 48
7.1. Normative references . . . . . . . . . . . . . . . . . . 48
7.2. Informative references . . . . . . . . . . . . . . . . . 49
Appendix A. Exchanges and events per state . . . . . . . . . . . 51
Appendix B. Application-specific parameters . . . . . . . . . . 52
Appendix C. ServerInfo and PeerInfo contents . . . . . . . . . . 53
Appendix D. EAP-NOOB roaming . . . . . . . . . . . . . . . . . . 55
Appendix E. OOB message as URL . . . . . . . . . . . . . . . . . 56
Appendix F. Example messages . . . . . . . . . . . . . . . . . . 57
Appendix G. TODO list . . . . . . . . . . . . . . . . . . . . . 59
Appendix H. Version history . . . . . . . . . . . . . . . . . . 59
Appendix I. Acknowledgments . . . . . . . . . . . . . . . . . . 62
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 62
1. Introduction
This document describes a method for registration, authentication and
key derivation for network-connected ubiquitous computing devices,
such as consumer and enterprise appliances that are part of the
Internet of Things (IoT). These devices may be off-the-shelf
hardware that is sold and distributed without any prior registration
or credential-provisioning process, or they may be recycled devices
after a hard reset. Thus, the device registration in a server
database, ownership of the device, and the authentication credentials
for both network access and application-level security must all be
established at the time of the device deployment. Furthermore, many
such devices have only limited user interfaces that could be used for
their configuration. Often, the interfaces are limited to either
only input (e.g. camera) or output (e.g. display screen). The device
configuration is made more challenging by the fact that the devices
may exist in large numbers and may have to be deployed or re-
configured nimbly based on user needs.
To summarize, devices may have the following characteristics:
o no pre-established relation with the intended server or user,
o no pre-provisioned device identifier or authentication
credentials,
o input or output interface that may be capable of only one-
directional communication.
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Many proprietary OOB configuration methods exits for specific IoT
devices. The goal of this specification is to provide an open
standard and a generic protocol for bootstrapping the security of
network-connected appliances, such as displays, printers, speakers,
and cameras. The security bootstrapping in this specification makes
use of a user-assisted out-of-band (OOB) channel. The device
authentication relies on user having physical access to the device,
and the of the key exchange security is based on the assumption that
attackers are not able to observe or modify the messages conveyed
through the OOB channel. We follow the common approach taken in
pairing protocols: performing a Diffie-Hellman key exchange over the
insecure network and authenticating the established key with the help
of the OOB channel in order to prevent impersonation and man-in-the-
middle (MitM) attacks.
The solution presented here is intended for devices that have either
an input or output interface, such as a camera, microphone, display
screen, speakers or blinking LED light, which is able to send or
receive dynamically generated messages of tens of bytes in length.
Naturally, this solution may not be appropriate for very small
sensors or actuators that have no user interface at all or for
devices that are inaccessible to the user. We also assume that the
OOB channel is at least partly automated (e.g. camera scanning a bar
code) and, thus, there is no need to absolutely minimize the length
of the data transferred through the OOB channel. This differs, for
example, from Bluetooth simple pairing [BluetoothPairing], where it
is critical to minimize the length of the manually transferred or
compared codes. Since the OOB messages are dynamically generated, we
do not support static printed registration codes. This also prevents
attacks where a static secret code would be leaked.
2. Terminology
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].
In addition, this document frequently uses the following terms as
they have been defined in [RFC5216]:
authenticator The entity initiating EAP authentication.
peer The entity that responds to the authenticator. In
[IEEE-802.1X], this entity is known as the supplicant. (We use
the terms peer, device and peer device interchangeably.)
server The entity that terminates the EAP authentication method with
the peer. In the case where no backend authentication server
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is used, the EAP server is part of the authenticator. In the
case where the authenticator operates in pass-through mode, the
EAP server is located on the backend authentication server.
3. EAP-NOOB protocol
This section defines the EAP-NOOB protocol. The protocol is a
generalized version of the original idea presented by Sethi et al.
[Sethi14].
3.1. Protocol overview
One EAP-NOOB protocol execution spans two or more EAP conversations,
called Exchanges in this specification. Each Exchange consists of
several EAP request-response pairs. At least two separate EAP
conversations are needed to give the human user time to deliver the
OOB message between them.
The overall protocol starts with the Initial Exchange, which
comprises four EAP request-response pairs. In the Initial Exchange,
the server allocates an identifier to the peer, and the server and
peer negotiate the protocol version and cryptosuite (i.e.
cryptographic algorithm suite), exchange nonces and perform an
Ephemeral Elliptic Curve Diffie-Hellman (ECDHE) key exchange. The
user-assisted OOB Step then takes place. This step requires only one
out-of-band message either from the peer to the server or from the
server to the peer. While waiting for the OOB Step action, the peer
MAY probe the server by reconnecting to it with EAP-NOOB. If the OOB
Step has already taken place, the probe leads to the Completion
Exchange, which completes the mutual authentication and key
confirmation. On the other hand, if the OOB Step has not yet taken
place, the probe leads to the Waiting Exchange, and the peer will
perform another probe after a server-defined minimum waiting time.
The Initial Exchange and Waiting Exchange always end in EAP-Failure,
while the Completion Exchange may result in EAP-Success. Once the
peer and server have performed a successful Completion Exchange, both
endpoints store the created association in persistent storage, and
the OOB Step is not repeated. Thereafter, creation of new temporal
keys, ECDHE rekeying, and updates of cryptographic algorithms can be
achieved with the Reconnect Exchange.
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OOB Output/Initial Exchange/
Waiting Exchange
.-----.
| v
.------------------. Initial .------------------.
| | Exchange | |
.->| Unregistered (0) |---------------->|Waiting for OOB(1)|
| | | | |
| '------------------' '------------------'
| | | ^
User Reset Completion | | |
| Exchange | OOB OOB
|<-------. .-------------------------' Input Reject/
| | | | Initial
| | | | Exchange
| | v v |
| .------------------. Completion .------------------.
| | | Exchange | |
| | Registered (4) |<----------------| OOB Received (2) |
| | | | |
| '------------------' '------------------'
| | ^
| Mobility/ |
| Timeout/ Reconnect
| Failure Exchange
| | |
| v |
| .-----------------.
| | |
'--| Reconnecting (3)|
| |
'-----------------'
Figure 1: EAP-NOOB server-peer association state machine
Figure 1 shows the association state machine, which is the same for
the server and for the peer. (For readability, only the main state
transitions are shown. The complete table of transitions can be
found in Appendix A.) When the peer initiates the EAP-NOOB method,
the server chooses the ensuing message exchange based on the
combination of the server and peer states. The EAP server and peer
are initially in the Unregistered state, in which no state
information needs to be stored. Before a successful Completion
Exchange, the server-peer association state is ephemeral in both the
server and peer (ephemeral states 0..2), and either endpoint may
cause the protocol to fall back to the Initial Exchange. After the
Completion Exchange has resulted in EAP-Success, the association
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state becomes persistent (persistent states 3..4). Only user reset
or memory failure can cause the return of the server or the peer from
the persistent states to the ephemeral states and to the Initial
Exchange.
The server MUST NOT repeat a successful OOB Step with the same peer
except if the association with the peer is explicitly reset by the
user or lost due to failure of the persistent storage in the server.
More specifically, once the association has entered the Registered
state, the server MUST NOT delete the association or go back to
states 0..2 without explicit user approval. Similarly, the peer MUST
NOT repeat the OOB Step unless the user explicitly deletes from the
peer the association with the server or resets the peer to the
Unregistered state. The server and peer MAY implement user reset of
the association by deleting the state data from that endpoint. If an
endpoint continues to store data about the association after the user
reset, its behavior SHOULD be equivalent to having deleted the
association data.
It can happen that the peer accidentally or through user reset loses
its persistent state and reconnects to the server without a
previously allocated peer identifier. In that case, the server MUST
treat the peer as a new peer. The server MAY use auxiliary
information, such as the PeerInfo field received in the Initial
Exchange, to detect multiple associations with the same peer.
However, it MUST NOT delete or merge redundant associations without
user or application approval because EAP-NOOB internally has no
secure way of verifying that the two peers are the same physical
device. Similarly, the server might lose the association state
because of a memory failure or user reset. In that case, the only
way to recover is that the user resets also the peer.
A special feature of the EAP-NOOB method is that the server is not
assumed to have any a-priori knowledge of the peer. Therefore, the
peer initially uses the generic identity string "noob@eap-noob.net"
(.arpa domain TBA) as its network access identifier (NAI). The
server then allocates a server-specific identifier to the peer. The
generic NAI serves two purposes: firstly, it tells the server that
the peer supports and expects the EAP-NOOB method and, secondly, it
allows routing of the EAP-NOOB sessions to a specific authentication
server in the AAA architecture.
EAP-NOOB is an unusual EAP method in that the peer has to have
multiple EAP conversations with the server before it can receive EAP-
Success. The reason is that, while EAP allows delays between the
request-response pairs, e.g. for repeated password entry, the user
delays in OOB authentication can be much longer than in password
trials. In particular, EAP-NOOB supports also peers with no input
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capability in the user interface. Since user cannot initiate the
protocol in these devices, they have to perform the Initial Exchange
opportunistically and hope for the OOB Step to take place within a
timeout period (NoobTimeout), which is why the timeout needs to be
several minutes rather than seconds. For example, consider a printer
(peer) that outputs the OOB message on paper, which is then scanned
for the server. To support such high-latency OOB channels, the peer
and server perform the Initial Exchange in one EAP conversation, then
allow time for the OOB message to be delivered, and later perform the
Waiting and Completion Exchanges in different EAP conversations.
3.2. Protocol messages and sequences
This section defines the EAP-NOOB exchanges, which correspond to EAP
conversations. The exchanges start with a common handshake, which
determines the type of the following exchange. The common handshake
messages and the subsequent messages for each exchange type are
listed in the diagrams below. The diagrams also specify the data
members present in each message. Each exchange comprises multiple
EAP requests-response pairs and ends in either EAP-Failure,
indicating that authentication is not (yet) successful, or in EAP-
Success.
3.2.1. Common handshake in all EAP-NOOB exchanges
All EAP-NOOB exchanges start with common handshake messages. The
handshake starts with the identity request and response that are
common to all EAP methods. Their purpose is to enable the AAA
architecture to route the EAP conversation to the EAP server and to
enable the EAP server to select the EAP method. The handshake then
continues with one EAP-NOOB request-response pair in which the server
discovers the peer identifier used in EAP-NOOB and the peer state.
In more detail, each EAP-NOOB exchange begins with the authenticator
sending an EAP-Request/Identity packet to the peer. From this point
on, the EAP conversation occurs between the server and the peer, and
the authenticator acts as a pass-through device. The peer responds
to the authenticator with an EAP-Response/Identity packet, which
contains the network access identifier (NAI). The authenticator,
acting as a pass-through device, forwards this response and the
following EAP conversation between the peer and the AAA architecture.
The AAA architecture routes the conversation to a specific AAA server
(called "EAP server" or simply "server" in this specification) based
on the realm part of the NAI. The server selects the EAP-NOOB method
based on the user part of the NAI, as defined in Section 3.3.1.
After receiving the EAP-Response/Identity message, the server sends
the first EAP-NOOB request (Type=9) to the peer, which responds with
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the peer identifier (PeerId) and state (PeerState) in the range 0..3.
However, the peer SHOULD omit the PeerId from the response (Type=9)
when PeerState=0. The server then chooses the EAP-NOOB exchange,
i.e. the ensuing message sequence, as explained below. The peer
recognizes the exchange based on the message type field (Type) of the
next EAP-NOOB request received from the server.
The server MUST determine the exchange type based on the combination
of the peer and server states as follows (also summarized in
Figure 11). If one of the peer and server is in the Unregistered (0)
state and the other is in one of the ephemeral states (0..2), the
server chooses the Initial Exchange. If one of the peer or server is
in the OOB Received (2) state and the other is either in the Waiting
for OOB (1) or OOB Received (2) state, the OOB Step has taken place
and the server chooses the Completion Exchange. If both the server
and peer are in the Waiting for OOB (1) state, the server chooses the
Waiting Exchange. If the peer is in the Reconnecting (3) state and
the server is in the Registered (4) or Reconnecting (3) state, the
server chooses the Reconnect Exchange. All other state combinations
are error situations where user action is required, and the server
SHOULD indicate such errors to the peer with the error code 2002 (see
Section 3.6.3). Note also that the peer MUST NOT initiate EAP-NOOB
when the peer is in Registered (4) state.
EAP Peer EAP Server
| |
|<----------- EAP-Request/Identity -| |
| |
| |
|------------ EAP-Response/Identity -------------->|
| (NAI=noob@eap-noob.net) |
| |
| |
|<----------- EAP-Request/EAP-NOOB ----------------|
| (Type=9) |
| |
| |
|------------ EAP-Response/EAP-NOOB -------------->|
| (Type=9,[PeerId],PeerState=1) |
| |
| continuing with exchange-specific messages... |
Figure 2: Common handshake in all EAP-NOOB exchanges
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3.2.2. Initial Exchange
The Initial Exchange comprises the common handshake and two further
EAP-NOOB request-response pairs, one for version, cryptosuite and
parameter negotiation and the other for the ECDHE key exchange. The
first EAP-NOOB request (Type=1) from the server contains a newly
allocated PeerId for the peer and an optional Realm. The server
allocates a new PeerId in the Initial Exchange regardless of any old
PeerId in the username part of the received NAI. The server also
sends in the request a list of the protocol versions (Vers) and
cryptosuites (Cryptosuites) it supports, an indicator of the OOB
channel directions it supports (Dirs), and a ServerInfo object. The
peer chooses one of the versions and cryptosuites. The peer sends a
response (Type=1) with the selected protocol version (Verp), the
received PeerId, the selected cryptosuite (Cryptosuitep), an
indicator of the OOB channel directions selected by the peer (Dirp),
and a PeerInfo object. In the second EAP-NOOB request and response
(Type=2), the server and peer exchange the public components of their
ECDHE keys and nonces (PKs,Ns,PKp,Np). The ECDHE keys MUST be based
on the negotiated cryptosuite i.e. Cryptosuitep. The Initial
Exchange always ends with EAP-Failure from the server because the
authentication cannot yet be completed.
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EAP Peer EAP Server
| ...continuing from common handshake |
| |
|<----------- EAP-Request/EAP-NOOB ----------------|
| (Type=1,Vers,PeerId,[Realm], |
| Cryptosuites,Dirs,ServerInfo) |
| |
| |
|------------ EAP-Response/EAP-NOOB -------------->|
| (Type=1,Verp,PeerId,Cryptosuitep, |
| Dirp,PeerInfo) |
| |
| |
|<----------- EAP-Request/EAP-NOOB ----------------|
| (Type=2,PeerId,PKs,Ns,[SleepTime]) |
| |
| |
|------------ EAP-Response/EAP-NOOB -------------->|
| (Type=2,PeerId,PKp,Np) |
| |
| |
|<----------- EAP-Failure -------------------------|
| |
Figure 3: Initial Exchange
At the conclusion of the Initial Exchange, both the server and the
peer move to the Waiting for OOB (1) state.
3.2.3. OOB Step
The OOB Step, labeled as OOB Output and OOB Input in Figure 1, takes
place after the Initial Exchange. Depending on the negotiated OOB
channel direction, the peer or the server outputs the OOB message
shown in Figure 4 or Figure 5, respectively. The data fields are the
PeerId, the secret nonce Noob, and the cryptographic fingerprint
Hoob. The contents of the data fields are defined in Section 3.3.2.
The OOB message is delivered to the other endpoint via a user-
assisted OOB channel.
For brevity, we will use the terms OOB sender and OOB receiver in
addition to the already familiar EAP server and EAP peer. If the OOB
message is sent in in the server-to-peer direction, the OOB sender is
the server and the OOB receiver is the peer. On the other hand, if
the OOB message is sent in the peer-to-server direction, the OOB
sender is the peer and the OOB receiver is the server.
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EAP Peer EAP Server
| |
|=================OOB=============================>|
| (PeerId,Noob,Hoob) |
| |
Figure 4: OOB Step, from peer to EAP server
EAP Peer EAP Server
| |
|<================OOB==============================|
| (PeerId,Noob,Hoob) |
| |
Figure 5: OOB Step, from EAP server to peer
The OOB receiver MUST compare the received value of the fingerprint
Hoob (see Section 3.3.2) with a value that it computes locally. This
integrity check ensures that the endpoints agree on contents of the
Initial Exchange. If the values are equal, the receiver moves to the
OOB Received (2) state. Otherwise, the receiver MUST reject the OOB
message. For usability reasons, the OOB receiver SHOULD indicate the
acceptance or rejection of the OOB message to the user. The receiver
SHOULD reject invalid OOB messages without changing its state, until
an application-specific number of invalid messages (OobRetries) has
been reached, after which the receiver SHOULD consider it an error
and go back to the Unregistered (0) state.
The server or peer MAY send multiple OOB messages with different Noob
values while in the Waiting for OOB (1) state. The OOB sender SHOULD
remember the Noob values until they expire and accept any one of them
in the following Completion Exchange. The Noob values sent by the
server expire after an application-dependent timeout (NoobTimeout),
and the server MUST NOT accept Noob values older than that in the
Completion Exchange. The RECOMMENDED value for NoobTimeout is 3600
seconds if there are no application-specific reasons for making it
shorter or longer. The Noob values sent by the peer expire as
defined in Section 3.2.5.
The OOB receiver does not accept further OOB messages after it has
accepted one and moved to the OOB Received (2) state. However, the
receiver MAY buffer redundant OOB messages in case OOB message expiry
or similar error detected in the Completion Exchange causes it to
return to the Waiting for OOB (1) state. It is RECOMMENDED that the
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OOB receiver notifies the user about redundant OOB messages, but it
MAY also discard them silently.
The sender will typically generate a new Noob, and therefore a new
OOB message, at constant time intervals (NoobInterval). The
RECOMMENDED interval is NoobInterval = NoobTimeout / 2, in which case
the receiver of the OOB will at any given time accept either of the
two latest Noob values. However, the timing of the Noob generation
may also be based on user interaction or on implementation
considerations.
Even though not recommended (see Section 3.3), this specification
allows both directions to be negotiated (Dirp=3) for the OOB channel.
In that case, both sides SHOULD output the OOB message, and it is up
to the user to deliver one of them.
The details of the OOB channel implementation including the message
encoding are defined by the application. Appendix E gives an example
of how the OOB message can be encoded as a URL that may be embedded
in a QR code and NFC tag.
3.2.4. Completion Exchange
After the Initial Exchange, if both the server and the peer support
the peer-to-server direction for the OOB channel, the peer SHOULD
initiate the EAP-NOOB method again after an applications-specific
waiting time in order to probe for completion of the OOB Step. Also,
if both sides support the server-to-peer direction of the OOB
exchange and the peer receives the OOB message, it SHOULD initiate
the EAP-NOOB method immediately. Depending on the combination of the
peer and server states, the server continues with with the Completion
Exchange or Waiting Exchange (see Section 3.2.1 on how the server
makes this decision).
The Completion Exchange comprises the common handshake and one or two
further EAP-NOOB request-response pairs. If the peer is in the
Waiting for OOB (1) state, the OOB message has been sent in the peer-
to-server direction. In that case, only one request-response pair
(Type=4) takes place. In the request, the server sends the NoobId
value, which the peer uses to identify the exact OOB message received
by the server. On the other hand, if the peer is in the OOB Received
(2) state, the direction of the OOB message is from server to peer.
In that case, two request-response pairs (Type=8 and Type=4) are
needed. The purpose of the first request-response pair (Type=8) is
that it enables the server to discover NoobId, which identifies the
exact OOB message received by the peer. The server returns the same
NoobId to the peer in the latter request.
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In the last and sometimes only request-response pair (Type=4) of the
Completion Exchange, the server and peer exchange message
authentication codes. Both sides MUST compute the keys Kms and Kmp
as defined in Section 3.5 and the message authentication codes MACs
and MACp as defined in Section 3.3.2. Both sides MUST compare the
received message authentication code with a locally computed value.
If the peer finds that it has received the correct value of MACs and
the server finds that it has received the correct value of MACp, the
Completion Exchange ends in EAP-Success. Otherwise, the endpoint
where the comparison fails indicates this with an error message
(error code 4001, see Section 3.6.1) and the Completion Exchange ends
in EAP-Failure.
After successful Completion Exchange, both the server and the peer
move to the Registered (4) state. They also derive the output keying
material and store the persistent EAP-NOOB association state as
defined in Section 3.4 and Section 3.5.
It is possible that the OOB message expires before it is received.
In that case, the sender of the OOB message no longer recognizes the
NoobId that it receives in the Completion Exchange. Another reason
why the OOB sender might not recognize the NoobId is if the received
OOB message was spoofed and contained an attacker-generated Noob
value. The recipient of an unrecognized NoobId indicates this with
an error message (error code 2003, see Section 3.6.1) and the
Completion Exchange ends in EAP-Failure. The recipient of the error
message 2003 moves back to the Waiting for OOB (1) state. This state
transition is shown as OOB Reject in Figure 1 (even though it really
is a specific type of failed Completion Exchange). The sender of the
error message, on the other hand, stays in its previous state.
Although it is not expected to occur in practice, poor user interface
design could lead to two OOB messages delivered simultaneously, one
from the peer to the server and the other from the server to the
peer. The server detects this event in the beginning of the
Completion Exchange by observing that both the server and peer are in
the OOB Received state (2). In that case, as a tiebreaker, the
server MUST behave as if only the server-to-peer message had been
delivered.
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EAP Peer EAP Server
| ...continuing from common handshake |
| |
|<----------- [ EAP-Request/EAP-NOOB ] ------------|
| (Type=8,PeerId) |
| |
| |
|------------ [ EAP-Response/EAP-NOOB ] ---------->|
| (Type=8,PeerId,NoobId) |
| |
| |
|<----------- EAP-Request/EAP-NOOB ----------------|
| (Type=4,PeerId,NoobId,MACs) |
| |
| |
|------------ EAP-Response/EAP-NOOB -------------->|
| (Type=4,PeerId,MACp) |
| |
| |
|<----------- EAP-Success -------------------------|
| |
Figure 6: Completion Exchange
3.2.5. Waiting Exchange
As explained in Section 3.2.4, the peer SHOULD probe the server for
completion of the OOB Step. When the combination of the peer and
server states indicates that the OOB message has not yet been
delivered, the server chooses the Waiting Exchange (see Section 3.2.1
on how the server makes this decision). The Waiting Exchange
comprises the common handshake and one further request-response pair,
and it ends always in EAP-Failure.
In order to limit the rate at which peers probe the server, the
server MAY send to the peer either in the Initial Exchange or in the
Waiting Exchange a minimum time to wait before probing the server
again. A peer that has not received an OOB message MUST wait at
least the server-specified minimum waiting time in seconds
(SleepTime) before initiating EAP again with the same server. The
peer uses the latest SleepTime value that it has received in or after
the Initial Exchange. If the server has not sent any SleepTime
value, the peer SHOULD wait for an application-specified minimum time
(SleepTimeDefault).
After the Waiting Exchange, the peer MUST discard (from its local
ephemeral storage) Noob values that it has sent to the server in OOB
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messages that are older than the application-defined timeout
NoobTimeout (see Section 3.2.3). The peer SHOULD discard such
expired Noob values even if the probing failed, e.g. because of
failure to connect to the EAP server or incorrect HMAC. The timeout
of peer-generated Noob values is defined like this in order to allow
the peer to probe the server once after it has waited for the server-
specified SleepTime.
If the server and peer have negotiated to use only the server-to-peer
direction for the OOB channel (Dirp=2), the peer SHOULD nevertheless
probe the server. The purpose of this is to keep the server informed
about the peers that are still waiting for OOB messages. The server
MAY set SleepTime to a high number (3600) to prevent the peer from
probing the server frequently.
EAP Peer EAP Server
| ...continuing from common handshake |
| |
|<----------- EAP-Request/EAP-NOOB ----------------|
| (Type=3,PeerId,[SleepTime]) |
| |
| |
|------------ EAP-Response/EAP-NOOB -------------->|
| (Type=3,PeerId) |
| |
| |
|<----------- EAP-Failure -------------------------|
| |
Figure 7: Waiting Exchange
3.3. Protocol data fields
This section defines the various identifiers and data fields used in
the EAP-NOOB protocol.
3.3.1. Peer identifier, realm and NAI
The server allocates a new peer identifier (PeerId) for the peer in
the Initial Exchange. The peer identifier MUST follow the syntax of
the utf8-username specified in [RFC7542]. The server MUST generate
the identifiers in such a way that they do not repeat and cannot be
guessed by the peer or third parties before the server sends them to
the peer in the Initial Exchange. One way to generate the
identifiers is to choose a random 16-byte identifier and to base64url
encode it without padding [RFC4648] into a 22-character string.
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Another way to generate the identifiers is to choose a random
22-character alphanumeric string. It is RECOMMENDED to not use
identifiers longer than this because they result in longer OOB
messages.
The peer uses the allocated PeerId to identify itself to the server
in the subsequent exchanges. It sets the PeerId value in response
type 9 as follows. When the peer is in the Unregistered (0) state,
it SHOULD omit the PeerId from response type 9. When the peer is in
one of the states 1..2, it MUST use the PeerId that the server
assigned to it in the latest Initial Exchange. When the peer is in
one of the persistent states 3..4, it MUST use the PeerId from its
persistent EAP-NOOB association. (The PeerId is written to the
association when the peer moves to the Registered (4) state after a
Completion Exchange.)
The default realm for the peer is "eap-noob.net" (.arpa domain TBA).
However, the user or application MAY provide a different default
realm to the peer. Furthermore, the server MAY assign a new realm to
the peer in the Initial Exchange or Reconnect Exchange, in the Realm
field of response types 1 and 5. The Realm value MUST follow the
syntax of the utf8-realm specified in [RFC7542]. When the peer is in
the Unregistered (0) state, or when the peer is in one of the states
1..2 and the server did not send a Realm in the latest Initial
Exchange, the peer MUST use the default realm. When the peer is in
one of the states 1..2 and the server sent a Realm in the latest
Initial Exchange, the peer MUST use that realm. Finally, when the
peer is in one of the persistent states 3..4, it MUST use the Realm
from its persistent EAP-NOOB association. (The Realm is written to
the association when the peer moves to the Registered (4) state after
a Completion Exchange or Reconnect Exchange.)
To compose its NAI [RFC7542], the peer concatenates the string
"noob@" and the server-assigned realm. When no server-assigned realm
is available, the default value is used instead.
The purpose of the server-assigned realm is to enable more flexible
routing of the EAP sessions over the AAA infrastructure, including
roaming scenarios (see Appendix D). Moreover, some Authenticators or
AAA servers use the assigned Realm to determine peer-specific
connection parameters, such as isolating the peer to a specific VLAN.
The possibility to configure a different default realm enables
registration of new devices while roaming. It also enables
manufacturers to set up their own AAA servers for bootstrapping of
new peer devices.
The peer's PeerId and Realm are ephemeral until a successful
Completion Exchange takes place. Thereafter, the values become parts
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of the persistent EAP-NOOB association, until the user resets the
peer and the server or until a new Realm is assigned in the Reconnect
Exchange.
3.3.2. Message data fields
Table 1 defines the data fields in the protocol messages. The in-
band messages are formatted as JSON objects [RFC8259] in UTF-8
encoding. The JSON member names are in the left-hand column of the
table.
+------------------+------------------------------------------------+
| Data field | Description |
+------------------+------------------------------------------------+
| Vers, Verp | EAP-NOOB protocol versions supported by the |
| | EAP server, and the protocol version chosen by |
| | the peer. Vers is a JSON array of unsigned |
| | integers, and Verp is an unsigned integer. |
| | Example values are "[1]" and "1", |
| | respectively. |
| | |
| PeerId | Peer identifier as defined in Section 3.3.1. |
| | |
| Realm | Peer realm as defined in Section 3.3.1. |
| | |
| PeerState | Peer state is an integer in the range 0..4 |
| | (see Figure 1). However, only values 0..3 are |
| | ever sent in the protocol messages. |
| | |
| Type | EAP-NOOB message type. The type is an integer |
| | in the range 0..9. EAP-NOOB requests and the |
| | corresponding responses share the same type |
| | value. |
| | |
| PKs, PKp | The public components of the ECDHE keys of the |
| | server and peer. PKs and PKp are sent in the |
| | JSON Web Key (JWK) format [RFC7517]. Detailed |
| | format of the JWK object is defined by the |
| | cryptosuite. |
| | |
| Cryptosuites, | The identifiers of cryptosuites supported by |
| Cryptosuitep | the server and of the cryptosuite selected by |
| | the peer. The server-supported cryptosuites in |
| | Cryptosuites are formatted as a JSON array of |
| | the identifier integers. The server MUST send |
| | a nonempty array with no repeating elements, |
| | ordered by decreasing priority. The peer MUST |
| | respond with exactly one suite in the |
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| | Cryptosuitep value, formatted as an identifier |
| | integer. The registration of cryptosuites is |
| | specified in Section 4.1. Example values are |
| | "[1]" and "1", respectively. |
| | |
| Dirs, Dirp | The OOB channel directions supported by the |
| | server and the directions selected by the |
| | peer. The possible values are 1=peer-to- |
| | server, 2=server-to-peer, 3=both directions. |
| | |
| Dir | The actual direction of the OOB message |
| | (1=peer-to-server, 2=server-to-peer). This |
| | value is not sent over any communication |
| | channel but it is included in the computation |
| | of the cryptographic fingerprint Hoob. |
| | |
| Ns, Np | 32-byte nonces for the Initial Exchange. |
| | |
| ServerInfo | This field contains information about the |
| | server to be passed from the EAP method to the |
| | application layer in the peer. The information |
| | is specific to the application or to the OOB |
| | channel and it is encoded as a JSON object of |
| | at most 500 bytes. It could include, for |
| | example, the access-network name and server |
| | name or a Uniform Resource Locator (URL) |
| | [RFC4266] or some other information that helps |
| | the user to deliver the OOB message to the |
| | server through the out-of-band channel. |
| | |
| PeerInfo | This field contains information about the peer |
| | to be passed from the EAP method to the |
| | application layer in the server. The |
| | information is specific to the application or |
| | to the OOB channel and it is encoded as a JSON |
| | object of at most 500 bytes. It could include, |
| | for example, the peer brand, model and serial |
| | number, which help the user to distinguish |
| | between devices and to deliver the OOB message |
| | to the correct peer through the out-of-band |
| | channel. |
| | |
| SleepTime | The number of seconds for which peer MUST NOT |
| | start a new execution of the EAP-NOOB method |
| | with the authenticator, unless the peer |
| | receives the OOB message or the peer is reset |
| | by the user. The server can use this field to |
| | limit the rate at which peers probe it. |
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| | SleepTime is an unsigned integer in the range |
| | 0..3600. |
| | |
| Noob | 16-byte secret nonce sent through the OOB |
| | channel and used for the session key |
| | derivation. The endpoint that received the OOB |
| | message uses this secret in the Completion |
| | Exchange to authenticate the exchanged key to |
| | the endpoint that sent the OOB message. |
| | |
| Hoob | 16-byte cryptographic fingerprint (i.e. hash |
| | value) computed from all the parameters |
| | exchanged in the Initial Exchange and in the |
| | OOB message. Receiving this fingerprint over |
| | the OOB channel guarantees the integrity of |
| | the key exchange and parameter negotiation. |
| | Hence, it authenticates the exchanged key to |
| | the endpoint that receives the OOB message. |
| | |
| NoobId | 16-byte identifier for the OOB message, |
| | computed with a one-way function from the |
| | nonce Noob in the message. |
| | |
| MACs, MACp | Message authentication codes (HMAC) for mutual |
| | authentication, key confirmation, and |
| | integrity check on the exchanged information. |
| | The input to the HMAC is defined below, and |
| | the key for the HMAC is defined in |
| | Section 3.5. |
| | |
| Ns2, Np2 | 32-byte Nonces for the Reconnect Exchange. |
| | |
| KeyingMode | Integer indicating the key derivation method. |
| | 0 in the Completion Exchange, and 1..3 in the |
| | Reconnect Exchange. |
| | |
| PKs2, PKp2 | The public components of the ECDHE keys of the |
| | server and peer for the Reconnect Exchange. |
| | PKp2 and PKs2 are sent in the JSON Web Key |
| | (JWK) format [RFC7517]. Detailed format of the |
| | JWK object is defined by the cryptosuite. |
| | |
| MACs2, MACp2 | Message authentication codes (HMAC) for mutual |
| | authentication, key confirmation, and |
| | integrity check on the Reconnect Exchange. The |
| | input to the HMAC is defined below, and the |
| | key for the HMAC is defined in Section 3.5. |
| | |
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| ErrorCode | Integer indicating an error condition. Defined |
| | in Section 4.3. |
| | |
| ErrorInfo | Textual error message for logging and |
| | debugging purposes. UTF-8 string of at most |
| | 500 bytes. |
| | |
+------------------+------------------------------------------------+
Table 1: Message data fields
It is RECOMMENDED for servers to support both OOB channel directions
(Dirs=3), unless the type of the OOB channel limits them to one
direction (Dirs=1 or Dirs=2). On the other hand, it is RECOMMENDED
that the peer selects only one direction (Dirp=1 or Dirp=2) even when
both directions (Dirp=3) would be technically possible. The reason
is that, if value 3 is negotiated, the user may be presented with two
OOB messages, one for each direction, even though only one of them
needs to be delivered. This can be confusing to the user.
Nevertheless, the EAP-NOOB protocol is designed to cope also with
selected value 3, in which case it uses the first delivered OOB
message. In the unlikely case of simultaneously delivered OOB
messages, the protocol prioritizes the server-to-peer direction.
The nonces in the in-band messages (Ns, Np, Ns2, Np2) are 32-byte
fresh random byte strings, and the secret nonce Noob is a 16-byte
fresh random byte string. All the nonces are generated by the
endpoint that sends the message.
The fingerprint Hoob and the identifier NoobId are computed with the
cryptographic hash function specified in the negotiated cryptosuite
and truncated to the 16 leftmost bytes of the output. The message
authentication codes (MACs, MACp, MACs2, MACp2) are computed with the
HMAC function [RFC2104] based on the same cryptographic hash function
and truncated to the 32 leftmost bytes of the output.
The inputs to the hash function for computing the fingerprint Hoob
and to the HMAC for computing MACs, MACp, MACs2 and MACp2 are JSON
arrays containing a fixed number (17) of elements. The array
elements MUST be copied to the array verbatim from the sent and
received in-band messages. When the element is a JSON object, its
members MUST NOT be reordered or re-encoded. Whitespace MUST NOT be
added anywhere in the JSON structure. Implementers should check that
their JSON library copies the elements as UTF-8 strings and does not
modify then in any way, and that it does not add whitespace to the
HMAC input.
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The inputs for computing the fingerprint and message authentication
codes are the following:
Hoob = H(Dir,Vers,Verp,PeerId,Cryptosuites,Dirs,ServerInfo,Cryptos
uitep,Dirp,[Realm],PeerInfo,0,PKs,Ns,PKp,Np,Noob).
NoobId = H("NoobId",Noob).
MACs = HMAC(Kms; 2,Vers,Verp,PeerId,Cryptosuites,Dirs,ServerInfo,C
ryptosuitep,Dirp,[Realm],PeerInfo,0,PKs,Ns,PKp,Np,Noob).
MACp = HMAC(Kmp; 1,Vers,Verp,PeerId,Cryptosuites,Dirs,ServerInfo,C
ryptosuitep,Dirp,[Realm],PeerInfo,0,PKs,Ns,PKp,Np,Noob).
MACs2 = HMAC(Kms2; 2,Vers,Verp,PeerId,Cryptosuites,"",[ServerInfo]
,Cryptosuitep,"",[Realm],[PeerInfo],KeyingMode,[PKs2],Ns2,[PKp2],N
p2,"")
MACp2 = HMAC(Kmp2; 1,Vers,Verp,PeerId,Cryptosuites,"",[ServerInfo]
,Cryptosuitep,"",[Realm],[PeerInfo],KeyingMode,[PKs2],Ns2,[PKp2],N
p2,"")
The inputs denoted with "" above are not present, and the values in
brackets [] are optional. Both kinds of missing input values are are
represented by empty strings "" in the HMAC input (JSON array).
Realm is included in the computation of MACs and MACp if it was sent
or received in the preceding Initial Exchange. Each of the values in
brackets for the computation of Macs2 and Macp2 MUST be included if
it was sent or received in the same Reconnect Exchange; otherwise the
value is replaced by an empty string "".
The parameter Dir indicates the direction in which the OOB message
containing the Noob value is being sent (1=peer-to-server, 2=server-
to-peer). This field is included in the Hoob input to prevent the
user from accidentally delivering the OOB message back to its
originator in the rare cases where both OOB directions have been
negotiated. The keys (Kms, Kmp, Kms2, Kmp2) for the HMACs are
defined in Section 3.5.
The nonces (Ns, Np, Ns2, Np2, Noob) and the hash value (NoobId) MUST
be base64url encoded [RFC4648] when they are used as input to the
cryptographic functions H or HMAC. These values and the message
authentication codes (MACs, MACp, MACs2, MACp2) MUST also be
base64url encoded when they are sent in the in-band messages. The
values Noob and Hoob in the OOB channel MAY be base64url encoded if
that is appropriate for the application and the OOB channel. All
base64url encoding is done without padding. The base64url encoded
values will naturally consume more space than the number of bytes
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specified above (22-character string for a 16-byte nonce and
43-character string for a 32-byte nonce or message authentication
code). In the key derivation in Section 3.5, on the other hand, the
unencoded nonces (raw bytes) are used as input to the key derivation
function.
The ServerInfo and PeerInfo are JSON objects with UTF-8 encoding.
The length of either encoded object as a byte array MUST NOT exceed
500 bytes. The format and semantics of these objects MUST be defined
by the application that uses the EAP-NOOB method.
3.4. Fast reconnect and rekeying
EAP-NOOB implements Fast Reconnect ([RFC3748], section 7.2.1) that
avoids repeated use of the user-assisted OOB channel.
The rekeying and the Reconnect Exchange may be needed for several
reasons. New EAP output values MSK and EMSK may be needed because of
mobility or timeout of session keys. Software or hardware failure or
user action may also cause the authenticator, EAP server or peer to
lose its non-persistent state data. The failure would typically be
detected by the peer or authenticator when session keys no longer are
accepted by the other endpoint. Change in the supported cryptosuites
in the EAP server or peer may also cause the need for a new key
exchange. When the EAP server or peer detects any one of these
events, it MUST change from the Registered to Reconnecting state.
These state transitions are labeled Mobility/Timeout/Failure in
Figure 1. The EAP-NOOB method will then perform the Reconnect
Exchange next time when EAP is triggered.
3.4.1. Persistent EAP-NOOB association
To enable rekeying, the EAP server and peer store the session state
in persistent memory after a successful Completion Exchange. This
state data, called "persistent EAP-NOOB association", MUST include at
least the data fields shown in Table 2. They are used for
identifying and authenticating the peer in the Reconnect Exchange.
When a persistent EAP-NOOB association exists, the EAP server and
peer are in the Registered state (4) or Reconnecting state (3), as
shown in Figure 1.
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+------------------+--------------------------------+---------------+
| Data field | Value | Type |
+------------------+--------------------------------+---------------+
| PeerId | Peer identifier allocated by | UTF-8 string |
| | server | (typically 22 |
| | | bytes) |
| | | |
| Verp | Negotiated protocol version | integer |
| | | |
| Cryptosuitep | Negotiated cryptosuite | integer |
| | | |
| CryptosuitepPrev | Previous cryptosuite | integer |
| (at peer only) | | |
| | | |
| Realm | Optional realm assigned by | UTF-8 string |
| | server (default value is "eap- | |
| | noob.net" (.arpa domain TBA)) | |
| | | |
| Kz | Persistent key material | 32 bytes |
| | | |
| KzPrev (at | Previous Kz value | 32 bytes |
| peer only) | | |
+------------------+--------------------------------+---------------+
Table 2: Persistent EAP-NOOB association
3.4.2. Reconnect Exchange
The server chooses the Reconnect Exchange when both the peer and the
server are in a persistent state and fast reconnection is needed (see
Section 3.2.1 for details).
The Reconnect Exchange comprises the common handshake and three
further EAP-NOOB request-response pairs, one for cryptosuite and
parameter negotiation, another for the nonce and ECDHE key exchange,
and the last one for exchanging message authentication codes. In the
first request and response (Type=5) the server and peer negotiate a
protocol version and cryptosuite in the same way as in the Initial
Exchange. The server SHOULD NOT offer and the peer MUST NOT accept
protocol versions or cryptosuites that it knows to be weaker than the
one currently in the Cryptosuitep field of the persistent EAP-NOOB
association. The server SHOULD NOT needlessly change the
cryptosuites it offers to the same peer because peer devices may have
limited ability to update their persistent storage. However, if the
peer has different values in the Cryptosuitep and CryptosuitepPrev
fields, it SHOULD also accept offers that are not weaker than
CryptosuitepPrev. Note that Cryptosuitep and CryptosuitePrev from
the persistent EAP-NOOB association are only used to support the
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negotiation as described above; all actual cryptographic operations
use the negotiated cryptosuite. The request and response (Type=5)
MAY additionally contain PeerInfo and ServerInfo objects.
The server then determines the KeyingMode (defined in Section 3.5)
based on changes in the negotiated cryptosuite and whether it desires
to achieve forward secrecy or not. The server SHOULD only select
KeyingMode 3 when the negotiated cryptosuite differs from the
Cryptosuitep in the server's persistent EAP-NOOB association,
although it is technically possible to select this values without
changing the cryptosuite. In the second request and response
(Type=6), the server informs the peer about the KeyingMode, and the
server and peer exchange nonces (Ns2, Np2). When KeyingMode is 2 or
3 (rekeying with ECDHE), they also exchange public components of
ECDHE keys (PKs2, PKp2). The server ECDHE key MUST be fresh, i.e.
not previously used with the same peer, and the peer ECDHE key SHOULD
be fresh, i.e. not previously used.
In the third and final request and response (Type=7), the server and
peer exchange message authentication codes. Both sides MUST compute
the keys Kms2 and Kmp2 as defined in Section 3.5 and the message
authentication codes MACs2 and MACp2 as defined in Section 3.3.2.
Both sides MUST compare the received message authentication code with
a locally computed value.
The rules by which the peer compares the received MACs2 are non-
trivial because, in addition to authenticating the current exchange,
MACs2 may confirm the success or failure of a recent cryptosuite
upgrade. The peer processes the final request (Type=7) as follows:
1. The peer first compares the received MACs2 value with one it
computed using the Kz stored in the persistent EAP-NOOB
association. If the received and computed values match, the peer
deletes any data stored in the CryptosuitepPrev and KzPrev fields
of the persistent EAP-NOOB association. It does this because the
received MACs2 confirms that the peer and server share the same
Cryptosuitep and Kz, and any previous values must no longer be
accepted.
2. If, on the other hand, the peer finds that the received MACs2
value does not match the one it computed locally with Kz, the
peer checks whether the KzPrev field in the persistent EAP-NOOB
association stores a key. If it does, the peer repeats the key
derivation (Section 3.5) and local MACs2 computation
(Section 3.3.2) using KzPrev in place of Kz. If this second
computed MACs2 matches the received value, the match indicates
synchronization failure caused by the loss of the last response
(Type=7) in a previously attempted cryptosuite upgrade. In this
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case, the peer rolls back that upgrade by overwriting
Cryptosuitep with CryptosuitepPrev and Kz with KzPrev in the
persistent EAP-NOOB association. It also clears the
CryptosuitepPrev and KzPrev fields.
3. If the received MACs2 matched one of the locally computed values,
the peer proceeds to send the final response (Type=7). The peer
also moves to the Registered (4) state. When KeyingMode is 1 or
2, the peer stops here. When KeyingMode is 3, the peer also
updates the persistent EAP-NOOB association with the negotiated
Cryptosuitep and the newly-derived Kz value. To prepare for
possible synchronization failure caused by the loss of the final
response (Type=7) during cryptosuite upgrade, the peer copies the
old Cryptosuitep and Kz values in the persistent EAP-NOOB
association to the CryptosuitepPrev and KzPrev fields.
4. Finally, if the peer finds that the received MACs2 does not match
either of the two values that it computed locally (or one value
if no KzPrev was stored), the peer sends an error message (error
code 4001, see Section 3.6.1), which causes the the Reconnect
Exchange to end in EAP-Failure.
The server rules for processing the final message are simpler than
the peer rules because the server does not store previous keys and it
never rolls back a cryptosuite upgrade. Upon receiving the final
response (Type=7), the server compares the received value of MACp2
with one it computes locally. If the values match, the Reconnect
Exchange ends in EAP-Success. When KeyingMode is 3, the server also
updates Cryptosuitep and Kz in the persistent EAP-NOOB association.
On the other hand, if the server finds that the values do not match,
it sends an error message (error code 4001), and the Reconnect
Exchange ends in EAP-Failure.
The endpoints MAY send updated Realm, ServerInfo and PeerInfo objects
in the Reconnect Exchange. When there is no update to the values,
they SHOULD omit this information from the messages. If the Realm
was sent, each side updates Realm in the persistent EAP-NOOB
association when moving to the Registered (4) state.
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EAP Peer EAP Server
| ...continuing from common handshake |
| |
|<----------- EAP-Request/EAP-NOOB ----------------|
| (Type=5,Vers,PeerId,Cryptosuites, |
| [Realm],[ServerInfo]) |
| |
| |
|------------ EAP-Response/EAP-NOOB -------------->|
| (Type=5,Verp,PeerId,Cryptosuitep,[PeerInfo])|
| |
| |
|<----------- EAP-Request/EAP-NOOB ----------------|
| (Type=6,PeerId,KeyingMode,[PKs2],Ns2) |
| |
| |
|------------ EAP-Response/EAP-NOOB -------------->|
| (Type=6,PeerId,[PKp2],Np2) |
| |
| |
|<----------- EAP-Request/EAP-NOOB ----------------|
| (Type=7,PeerId,MACs2) |
| |
| |
|------------ EAP-Response/EAP-NOOB -------------->|
| (Type=7,PeerId,MACp2) |
| |
| |
|<----------- EAP-Success -------------------------|
| |
Figure 8: Reconnect Exchange
3.4.3. User reset
As shown in the association state machine in Figure 1, the only
specified way for the association to return from the Registered state
(4) to the Unregistered state (0) is through user-initiated reset.
After the reset, a new OOB message will be needed to establish a new
association between the EAP server and peer. Typical situations in
which the user reset is required are when the other side has
accidentally lost the persistent EAP-NOOB association data, or when
the peer device is decommissioned.
The server could detect that the peer is in the Registered or
Reconnecting state but the server itself is in one of the ephemeral
states 0..2 (including situations where the server does not recognize
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the PeerId). In this case, effort should be made to recover the
persistent server state, for example, from a backup storage -
especially if many peer devices are similarly affected. If that is
not possible, the EAP server SHOULD log the error or notify an
administrator. The only way to continue from such a situation is by
having the user reset the peer device.
On the other hand, if the peer is in any of the ephemeral states
0..2, including the Unregistered state, the server will treat the
peer as a new peer device and allocate a new PeerId to it. The
PeerInfo can be used by the user as a clue to which physical device
has lost its state. However, there is no secure way of matching the
"new" peer with the old PeerId without repeating the OOB Step. This
situation will be resolved when the user performs the OOB Step and,
thus, identifies the physical peer device. The server user interface
MAY support situations where the "new" peer is actually a previously
registered peer that has been reset by a user or otherwise lost its
persistent data. In those cases, the user could choose to merge new
peer identity with the old one in the server. The alternative is to
treat the device just like a new peer.
3.5. Key derivation
EAP-NOOB derives the EAP output values MSK and EMSK and other secret
keying material from the output of an Ephemeral Elliptic Curve
Diffie-Hellman (ECDHE) algorithm following the NIST specification
[NIST-DH]. In NIST terminology, we use a C(2, 0, ECC CDH) scheme,
i.e. two ephemeral keys and no static keys. In the Initial and
Reconnect Exchanges, the server and peer compute the ECDHE shared
secret Z as defined in section 6.1.2.2 of the NIST specification
[NIST-DH]. In the Completion and Reconnect Exchanges, the server and
peer compute the secret keying material from Z with the single-step
key derivation function (KDF) defined in section 5.8.1 of the NIST
specification. The hash function H for KDF is taken from the
negotiated cryptosuite.
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+------------+------------------------------------------------------+
| KeyingMode | Description |
+------------+------------------------------------------------------+
| 0 | Completion Exchange (always with ECDHE) |
| | |
| 1 | Reconnect Exchange, rekeying without ECDHE |
| | |
| 2 | Reconnect Exchange, rekeying with ECHDE, no change |
| | in cryptosuite |
| | |
| 3 | Reconnect Exchange, rekeying with ECDHE, new |
| | cryptosuite negotiated |
+------------+------------------------------------------------------+
Table 3: Keying modes
The key derivation has four different modes (KeyingMode), which are
specified in Table 3. Table 4 defines the inputs to KDF in each
KeyingMode.
In the Completion Exchange (KeyingMode=0), the input Z comes from the
preceding Initial exchange. KDF takes some additional inputs
(OtherInfo), for which we use the concatenation format defined in
section 5.8.1.2.1 of the NIST specification [NIST-DH]. OtherInfo
consists of the AlgorithmId, PartyUInfo, PartyVInfo, and SuppPrivInfo
fields. The first three fields are fixed-length bit strings, and
SuppPrivInfo is a variable-length string with a one-byte Datalength
counter. AlgorithmId is the fixed-length 8-byte ASCII string "EAP-
NOOB". The other input values are the server and peer nonces. In
the Completion Exchange, the inputs also include the secret nonce
Noob from the OOB message.
In the simplest form of the Reconnect Exchange (KeyingMode=1), fresh
nonces are exchanged but no ECDHE keys are sent. In this case, input
Z to the KDF is replaced with the shared key Kz from the persistent
EAP-NOOB association. The result is rekeying without the
computational cost of the ECDHE exchange, but also without forward
secrecy.
When forward secrecy is desired in the Reconnect Exchange
(KeyingMode=2 or KeyingMode=3), both nonces and ECDHE keys are
exchanged. Input Z is the fresh shared secret from the ECDHE
exchange with PKs2 and PKp2. The inputs also include the shared
secret Kz from the persistent EAP-NOOB association. This binds the
rekeying output to the previously authenticated keys.
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+--------------+--------------+------------------------+------------+
| KeyingMode | KDF input | Value | Length |
| | field | | (bytes) |
+--------------+--------------+------------------------+------------+
| 0 | Z | ECDHE shared secret | variable |
| Completion | | from PKs and PKp | |
| | AlgorithmId | "EAP-NOOB" | 8 |
| | PartyUInfo | Np | 32 |
| | PartyVInfo | Ns | 32 |
| | SuppPubInfo | (not allowed) | |
| | SuppPrivInfo | Noob | 16 |
| | | | |
| 1 | Z | Kz | 32 |
| Reconnect, | AlgorithmId | "EAP-NOOB" | 8 |
| rekeying | PartyUInfo | Np2 | 32 |
| without | PartyVInfo | Ns2 | 32 |
| ECDHE | SuppPubInfo | (not allowed) | |
| | SuppPrivInfo | (null) | 0 |
| | | | |
| 2 or 3 | Z | ECDHE shared secret | variable |
| Reconnect, | | from PKs2 and PKp2 | |
| rekeying, | AlgorithmId | "EAP-NOOB" | 8 |
| with ECDHE, | PartyUInfo | Np2 | 32 |
| same or new | PartyVInfo | Ns2 | 32 |
| cryptosuite | SuppPubInfo | (not allowed) | |
| | SuppPrivInfo | Kz | 32 |
+--------------+--------------+------------------------+------------+
Table 4: Key derivation input
Table 5 defines how the output bytes of KDF are used. In addition to
the EAP output values MSK and EMSK, the server and peer derive
another shared secret key AMSK, which MAY be used for application-
layer security. Further output bytes are used internally by EAP-NOOB
for the message authentication keys (Kms, Kmp, Kms2, Kmp2).
The Completion Exchange (KeyingMode=0) produces the shared secret Kz,
which the server and peer store in the persistent EAP-NOOB
association. When a new cryptosuite is negotiated in the Reconnect
Exchange (KeyingMode=3), it similarly produces a new Kz. In that
case, the server and peer update both the cryptosuite and Kz in the
persistent EAP-NOOB association. Additionally, the peer stores the
previous Cryptosuitep and Kz values in the CryptosuitepPrev and
KzPrev fields of the persistent EAP-NOOB association.
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+-----------------+------------------+----------+----------------+
| KeyingMode | KDF output bytes | Used as | Length (bytes) |
+-----------------+------------------+----------+----------------+
| 0 | 0..63 | MSK | 64 |
| Completion | 64..127 | EMSK | 64 |
| | 128..191 | AMSK | 64 |
| | 192..223 | MethodId | 32 |
| | 224..255 | Kms | 32 |
| | 256..287 | Kmp | 32 |
| | 288..319 | Kz | 32 |
| | | | |
| 1 or 2 | 0..63 | MSK | 64 |
| Reconnect, | 64..127 | EMSK | 64 |
| rekeying | 128..191 | AMSK | 64 |
| without ECDHE, | 192..223 | MethodId | 32 |
| or with ECDHE | 224..255 | Kms2 | 32 |
| and unchanged | 256..287 | Kmp2 | 32 |
| cryptosuite | | | |
| | | | |
| | | | |
| 3 Reconnect, | 0..63 | MSK | 64 |
| rekeying | 64..127 | EMSK | 64 |
| with ECDHE, | 128..191 | AMSK | 64 |
| new cryptosuite | 192..223 | MethodId | 32 |
| | 224..255 | Kms2 | 32 |
| | 256..287 | Kmp2 | 32 |
| | 288..319 | Kz | 32 |
+-----------------+------------------+----------+----------------+
Table 5: Key derivation output
Finally, every EAP method must export a Server-Id, Peer-Id and
Session-Id [RFC5247]. In EAP-NOOB, the exported Peer-Id is the
PeerId which the server has assigned to the peer. The exported
Server-Id is a zero-length string (i.e. null string) because EAP-NOOB
neither knows nor assigns any server identifier. The exported
Session-Id is created by concatenating the Type-Code xxx (TBA) with
the MethodId, which is obtained from the KDF output as shown in
Table 5.
3.6. Error handling
Various error conditions in EAP-NOOB are handled by sending an error
notification message (Type=0) instead of the expected next EAP
request or response message. Both the EAP server and the peer may
send the error notification, as shown in Figure 9 and Figure 10.
After sending or receiving an error notification, the server MUST
send an EAP-Failure (as required by [RFC3748] section 4.2). The
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notification MAY contain an ErrorInfo field, which is a UTF-8 encoded
text string with a maximum length of 500 bytes. It is used for
sending descriptive information about the error for logging and
debugging purposes.
EAP Peer EAP Server
... ...
| |
|<----------- EAP-Request/EAP-NOOB ----------------|
| (Type=0,[PeerId],ErrorCode,[ErrorInfo]) |
| |
| |
|<----------- EAP-Failure -------------------------|
| |
Figure 9: Error notification from server to peer
EAP Peer EAP Server
... ...
| |
|------------ EAP-Response/EAP-NOOB -------------->|
| (Type=0,[PeerId],ErrorCode,[ErrorInfo]) |
| |
| |
|<----------- EAP-Failure -------------------------|
| |
Figure 10: Error notification from peer to server
After the exchange fails due to an error notification, the server and
peer set the association state as follows. In the Initial Exchange,
both the sender and recipient of the error notification MUST set the
association state to the Unregistered (0) state. In the Waiting and
Completion Exchanges, each side MUST remain in its old state as if
the failed exchange had not taken place, with the exception that the
recipient of error code 2003 processes it as specified in
Section 3.2.4. In the Reconnect Exchange, both sides MUST set the
association state to the Reconnecting (3) state.
Errors that occur in the OOB channel are not explicitly notified in-
band.
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3.6.1. Invalid messages
If the NAI structure is invalid, the server SHOULD send the error
code 1001 to the peer. The recipient of an EAP-NOOB request or
response SHOULD send the following error codes back to the sender:
1002 if it cannot parse the message as a JSON object or the top-level
JSON object has missing or unrecognized members; 1003 if a data field
has an invalid value, such as an integer out of range, and there is
no more specific error code available; 1004 if the received message
type was unexpected in the current state; 2004 if the PeerId has an
unexpected value; 2003 if the NoobId is not recognized; and 1007 if
the ECDHE key is invalid.
3.6.2. Unwanted peer
The preferred way for the EAP server to rate limit EAP-NOOB
connections from a peer is to use the SleepTime parameter in the
Waiting Exchange. However, if the EAP server receives repeated EAP-
NOOB connections from a peer which apparently should not connect to
this server, the server MAY indicate that the connections are
unwanted by sending the error code 2001. After receiving this error
message, the peer MAY refrain from reconnecting to the same EAP
server and, if possible, both the EAP server and peer SHOULD indicate
this error condition to the user or server administrator. However,
in order to avoid persistent denial of service, the peer is not
required to stop entirely from reconnecting to the server.
3.6.3. State mismatch
In the states indicated by "-" in Figure 11 in Appendix A, user
action is required to reset the association state or to recover it,
for example, from backup storage. In those cases, the server sends
the error code 2002 to the peer. If possible, both the EAP server
and peer SHOULD indicate this error condition to the user or server
administrator.
3.6.4. Negotiation failure
If there is no matching protocol version, the peer sends the error
code 3001 to the server. If there is no matching cryptosuite, the
peer sends the error code 3002 to the server. If there is no
matching OOB direction, the peer sends the error code 3003 to the
server.
In practice, there is no way of recovering from these errors without
software or hardware changes. If possible, both the EAP server and
peer SHOULD indicate these error conditions to the user.
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3.6.5. Cryptographic verification failure
If the receiver of the OOB message detects an unrecognized PeerId or
incorrect fingerprint (Hoob) in the OOB message, the receiver MUST
remain in the Waiting for OOB state (1) as if no OOB message was
received. The receiver SHOULD indicate the failure to accept the OOB
message to the user. No in-band error message is sent.
Note that if the OOB message was delivered from the server to the
peer and the peer does not recognize the PeerId, the likely cause is
that the user has unintentionally delivered the OOB message to the
wrong peer device. If possible, the peer SHOULD indicate this to the
user; however, the peer device may not have the capability for many
different error indications to the user and it MAY use the same
indication as in the case of an incorrect fingerprint.
The rationale for the above is that the invalid OOB message could
have been presented to the receiver by mistake or intentionally by a
malicious party and, thus, it should be ignored in the hope that the
honest user will soon deliver a correct OOB message.
If the EAP server or peer detects an incorrect message authentication
code (MACs, MACp, MACs2, MACp2), it sends the error code 4001 to the
other side. As specified in the beginning of Section 3.6, the failed
Completion Exchange will not result in server or peer state changes
while error in the Reconnect Exchange will put both sides to the
Reconnecting (3) state and thus lead to another reconnect attempt.
The rationale for this is that the invalid cryptographic message may
have been spoofed by a malicious party and, thus, it should be
ignored. In particular, a spoofed message on the in-band channel
should not force the honest user to perform the OOB Step again. In
practice, however, the error may be caused by other failures, such as
a software bug. For this reason, the EAP server MAY limit the rate
of peer connections with SleepTime after the above error. Also,
there SHOULD be a way for the user to reset the peer to the
Unregistered state (0), so that the OOB Step can be repeated at the
last resort.
3.6.6. Application-specific failure
Applications MAY define new error messages for failures that are
specific to the application or to one type of OOB channel. They MAY
also use the generic application-specific error code 5001, or the
error codes 5002 and 5004, which have been reserved for indicating
invalid data in the ServerInfo and PeerInfo fields, respectively.
Additionally, anticipating OOB channels that make use of a URL, the
error code 5003 has been reserved for indicating invalid server URL.
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4. IANA Considerations
This section provides guidance to the Internet Assigned Numbers
Authority (IANA) regarding registration of values related to the EAP-
NOOB protocol, in accordance with [RFC8126].
The EAP Method Type number for EAP-NOOB needs to be assigned.
This memo also requires IANA to create new registries as defined in
the following subsections.
4.1. Cryptosuites
Cryptosuites are identified by an integer. Each cryptosuite MUST
specify an ECDHE curve for the key exchange, encoding of the ECDHE
public key as a JWK object, and a cryptographic hash function for the
fingerprint and HMAC computation and key derivation. The hash value
output by the cryptographic hash function MUST be at least 32 bytes
in length. The following suites are defined by EAP-NOOB:
+-------------+-----------------------------------------------------+
| Cryptosuite | Algorithms |
+-------------+-----------------------------------------------------+
| 1 | ECDHE curve Curve25519 [RFC7748], public-key format |
| | [RFC7518] Section 6.2.1, hash function SHA-256 |
| | [RFC6234] |
+-------------+-----------------------------------------------------+
Table 6: EAP-NOOB cryptosuites
An example of Cryptosuite 1 public-key encoded as a JWK object is
given below (line breaks are for readability only).
"jwk":{"kty":"EC","crv":"Curve25519","x":"3p7bfXt9wbTTW2HC7OQ1Nz-
DQ8hbeGdNrfx-FG-IK08"}
Assignment of new values for new cryptosuites MUST be done through
IANA with "Specification Required" and "IESG Approval" as defined in
[RFC8126].
4.2. Message Types
EAP-NOOB request and response pairs are identified by an integer
Message Type. The following Message Types are defined by EAP-NOOB:
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+----------+------------+-------------------------------------------+
| Message | Used in | Purpose |
| Type | Exchange | |
+----------+------------+-------------------------------------------+
| 1 | Initial | Version, cryptosuite and parameter |
| | | negotiation |
| | | |
| 2 | Initial | Exchange of ECDHE keys and nonces |
| | | |
| 3 | Waiting | Indication to peer that the server has |
| | | not yet received an OOB message |
| | | |
| 4 | Completion | Authentication and key confirmation with |
| | | HMAC |
| | | |
| 5 | Reconnect | Version, cryptosuite, and parameter |
| | | negotiation |
| | | |
| 6 | Reconnect | Exchange of ECDHE keys and nonces |
| | | |
| 7 | Reconnect | Authentication and key confirmation with |
| | | HMAC |
| | | |
| 8 | Completion | NoobId discovery |
| | | |
| 9 | All | PeerId and PeerState discovery |
| | exchanges | |
| | | |
| 0 | Error | Error notification |
| | | |
+----------+------------+-------------------------------------------+
Table 7: EAP-NOOB
Assignment of new values for new Message Types MUST be done through
IANA with "Expert Review" as defined in [RFC8126].
4.3. Error codes
The error codes defined by EAP-NOOB are listed in Table 8.
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+------------+----------------------------------------+
| Error code | Purpose |
+------------+----------------------------------------+
| 1001 | Invalid NAI |
| 1002 | Invalid message structure |
| 1003 | Invalid data |
| 1004 | Unexpected message type |
| 1007 | Invalid ECDHE key |
| 2001 | Unwanted peer |
| 2002 | State mismatch, user action required |
| 2003 | Unrecognized OOB message identifier |
| 2004 | Unexpected peer identifier |
| 3001 | No mutually supported protocol version |
| 3002 | No mutually supported cryptosuite |
| 3003 | No mutually supported OOB direction |
| 4001 | HMAC verification failure |
| 5001 | Application-specific error |
| 5002 | Invalid server info |
| 5003 | Invalid server URL |
| 5004 | Invalid peer info |
| 6001-6999 | Private and experimental use |
+------------+----------------------------------------+
Table 8: EAP-NOOB error codes
Assignment of new error codes MUST be done through IANA with
"Specification Required" and "IESG Approval" as defined in [RFC8126],
with the exception of the range 6001-6999, which is reserved for
"Private Use" and "Experimental Use".
4.4. Domain name reservation considerations
A special-use domain (.arpa) should be registered to replace the
temporary domain "eap-noob.net" used in this draft. The
considerations required by [RFC6761] for registering this special-use
domain name are the following:
o Users: Non-admin users are not expected to encounter this name or
recognize it as special. AAA administrators may need to recognize
the name.
o Application Software: Application software is not expected to
recognize this domain name as special.
o Name Resolution APIs and Libraries: Name resolution APIs and
libraries are not expected to recognize this domain name as
special.
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o Caching DNS Servers: Caching servers are not expected to recognize
this domain name as special.
o Authoritative DNS Servers: Authoritative DNS servers MUST respond
to queries for eap-noob.net (.arpa domain TBA) with NXDOMAIN.
o DNS Server Operators: Except for the authoritative DNS server,
there are no special requirements for the operators.
o DNS Registries/Registrars: There are no special requirements for
DNS registrars.
5. Implementation Status
This section records the status of known implementations of the
protocol defined by this specification at the time of posting of this
Internet-Draft, and is based on a proposal described in [RFC7942].
The description of implementations in this section is intended to
assist the IETF in its decision processes in progressing drafts to
RFCs. Please note that the listing of any individual implementation
here does not imply endorsement by the IETF. Furthermore, no effort
has been spent to verify the information presented here that was
supplied by IETF contributors. This is not intended as, and must not
be construed to be, a catalog of available implementations or their
features. Readers are advised to note that other implementations may
exist.
5.1. Implementation with wpa_supplicant and hostapd
o Responsible Organization: Aalto University
o Location: <https://github.com/tuomaura/eap-noob>
o Coverage: This implementation includes all of the features
described in the current specification. The implementation
supports two dimensional QR codes and NFC as example out-of-band
(OOB) channels
o Level of Maturity: Alpha
o Version compatibility: Version 06 of the draft implemented
o Licensing: BSD
o Contact Information: Tuomas Aura, tuomas.aura@aalto.fi
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5.2. Implementation on Contiki
o Responsible Organization: University of Murcia and Aalto
University
o Location: <https://github.com/eduingles/coap-eap-noob>
o Coverage: This implementation includes all of the features
described in the current specification. The implementation uses a
blinking LED light as the out-of-band (OOB) channel
o Level of Maturity: Alpha
o Version compatibility: Version 05 of the draft implemented
o Licensing: BSD
o Contact Information: Eduardo Ingles, eduardo.ingles@um.es
5.3. Protocol modeling
The current EAP-NOOB specification has been modeled with the mCRL2
formal specification language [mcrl2]. The model
<https://github.com/tuomaura/eap-noob/tree/master/protocolmodel/
mcrl2> was used mainly for simulating the protocol behavior and for
verifying basic safety and liveness properties as part of the
specification process. For example, we verified the correctness of
the tiebreaking mechanism when two OOB messages are received
simultaneously, one in each direction. We also verified that a man-
in-the-middle attacker cannot cause persistent failure by spoofing a
finite number of messages in the Reconnect Exchange. Additionally,
the protocol has been modeled with the ProVerif [proverif] tool.
This model <https://github.com/tuomaura/eap-
noob/tree/master/protocolmodel/proverif> was used to verify security
properties such as mutual authentication.
6. Security considerations
EAP-NOOB is an authentication and key derivation protocol and, thus,
security considerations can be found in most sections of this
specification. In the following, we explain the protocol design and
highlight some other special considerations.
6.1. Authentication principle
EAP-NOOB establishes a shared secret with an authenticated ECDHE key
exchange. The mutual authentication in EAP-NOOB is based on two
separate features, both conveyed in the OOB message. The first
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authentication feature is the secret nonce Noob. The peer and server
use this secret in the Completion Exchange to mutually authenticate
the session key previously created with ECDHE. The message
authentication codes computed with the secret nonce Noob are alone
sufficient for authenticating the key exchange. The second
authentication feature is the integrity-protecting fingerprint Hoob.
Its purpose is to prevent impersonation and man-in-the-middle attacks
even in situations where the attacker is able to eavesdrop the OOB
channel and the nonce Noob is compromised. In some human-assisted
OOB channels, such as human-perceptible audio or user-typed URL, it
may be easier to detect tampering than spying of the OOB message, and
such applications benefit from the second authentication feature.
The additional security provided by the cryptographic fingerprint
Hoob is somewhat intricate to understand. The endpoint that receives
the OOB message uses Hoob to verify the integrity of the ECDHE
exchange. Thus, the OOB receiver can detect impersonation and man-
in-the-middle attacks that may have happened on the in-band channel.
The other endpoint, however, is not equally protected because the OOB
message and fingerprint are sent only in one direction. Some
protection to the OOB sender is afforded by the fact that the user
may notice the failure of the association at the OOB receiver and
therefore reset the OOB sender. Other device-pairing protocols have
solved similar situations by requiring the user to confirm to the OOB
sender that the association was accepted by the OOB receiver, e.g.
with a button press on the sender side. Applications MAY implement
EAP-NOOB in this way. Nevertheless, since EAP-NOOB was designed to
work with strictly one-directional OOB communication and the
fingerprint is only the second authentication feature, the EAP-NOOB
specification does not mandate such explicit confirmation to the OOB
sender.
To summarize, EAP-NOOB uses the combined protection of the secret
nonce Noob and the cryptographic fingerprint Hoob, both conveyed in
the OOB message. The secret nonce Noob alone is sufficient for
mutual authentication, unless the attacker can eavesdrop it from the
OOB channel. Even if an attacker is able to eavesdrop the secret
nonce Noob, it nevertheless cannot perform a full man-in-the-middle
attack on the in-band channel because a mismatching fingerprint would
alert the OOB receiver, which would reject the OOB message. The
attacker that eavesdropped the secret nonce can impersonate the OOB
receiver to the OOB sender. If it does, the association will appear
to be complete only on the OOB sender side, and such situations have
to be resolved by the user by resetting the OOB sender to the initial
state.
The expected use cases for EAP-NOOB are ones where it replaces a
user-entered access credential in IoT appliances. In wireless
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network access without EAP, the user-entered credential is often a
passphrase that is shared by all the network stations. The advantage
of an EAP-based solution, including EAP-NOOB, is that it establishes
a different master secret for each peer device, which makes the
system more resilient against device compromise. Another advantage
is that it is possible to revoke the security association for an
individual device on the server side.
Forward secrecy in EAP-NOOB is optional. The Reconnect Exchange in
EAP-NOOB provides forward secrecy only if both the server and peer
send their fresh ECDHE keys. This allows both the server and the
peer to limit the frequency of the costly computation that is
required for forward secrecy. The server MAY adjust the frequency of
its attempts at ECDHE rekeying based on what it knows about the
peer's computational capabilities.
The users delivering the OOB messages will often authenticate
themselves to the EAP server, e.g. by logging into a secure web page
or API. In this case, the server can reliably associate the peer
device with the user account. Applications that make use of EAP-NOOB
can use this information for configuring the initial owner of the
freshly-registered device.
6.2. Identifying correct endpoints
Potential weaknesses in EAP-NOOB arise from the fact that the user
must identify physically the correct peer device. If the attacker is
able to trick the user into delivering the OOB message to or from the
wrong peer device, the server may create an association with the
wrong peer. This reliance on user in identifying the correct
endpoints is an inherent property of user-assisted out-of-band
authentication.
It is, however, not possible to exploit accidental delivery of the
OOB message to the wrong device when the user makes an unexpected
mistake. This is because the wrong peer device would not have
prepared for the attack by performing the Initial Exchange with the
server. In comparison, simpler security bootstrapping solutions
where the master key is transferred to the device via the OOB channel
are vulnerable to opportunistic attacks if the user mistakenly
delivers the master key to the wrong device or to more than one
device.
One mechanism that can mitigate user mistakes is certification of
peer devices. The certificate can convey to the server authentic
identifiers and attributes, such as model and serial number, of the
peer device. Compared to a fully certificate-based authentication,
however, EAP-NOOB can be used without trusted third parties and does
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not require the user to know any identifier of the peer device;
physical access to the device is sufficient for bootstrapping with
EAP-NOOB.
Similarly, the attacker can try to trick the user into delivering the
OOB message to the wrong server, so that the peer device becomes
associated with the wrong server. If the EAP server is accessed
through a web user interface, the attack is akin to phishing attacks
where the user is tricked into accessing the wrong URL and wrong web
page. OOB implementation with a dedicated app on a mobile device,
which communicates with a server API at a pre-configured URL, can
protect against such attacks.
6.3. Trusted path issues and misbinding attacks
Another potential threat is spoofed user input or output on the peer
device. When the user is delivering the OOB message to or from the
correct peer device, a trusted path between the user and the peer
device is needed. That is, the user must communicate directly with
an authentic operating system and EAP-NOOB implementation in the peer
device and not with a spoofed user interface. Otherwise, a
Registered device that is under the control of the attacker could
emulate the behavior of an unregistered device. The secure path can
be implemented, for example, by having the user press a reset button
to return the device to the Unregistered state and to invoke a
trusted UI. The problem with such trusted paths is that they are not
standardized across devices.
Another potential consequence of a spoofed UI is the misbinding
attack where the user tries to register a correct but compromised
device, which tricks the user into registering another
(uncompromised) device instead. For example, the compromised device
might have a malicious full-screen app running, which presents to the
user QR codes copied, in real time, from another device's screen. If
the unwitting user scans the QR code and delivers the OOB message in
it to the server, the wrong device may become registered in the
server. Such misbinding vulnerabilities arise because the user does
not have any secure way of verifying that the in-band cryptographic
handshake and the out-of-band physical access are terminated at the
same physical device. Sethi et al. [Sethi19] analyze the misbinding
threat against device-pairing protocols and also EAP-NOOB.
Essentially, all protocols where the authentication relies on the
user's physical access to the device are vulnerable to misbinding,
including EAP-NOOB.
A standardized trusted path for communicating directly with the
trusted computing base in a physical device would mitigate the
misbinding threat, but such paths rarely exist in practice. Careful
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asset tracking on the server side can also prevent most misbinding
attacks if the peer device sends its identifers or attributes in the
PeerInfo field and the server compares them with the expected values.
The wrong but uncompomised device's PeerInfo will not match the
expected values. Device certification by the manufacturer can
further strengthen the asset tracking.
6.4. Peer identifiers and attributes
The PeerId value in the protocol is a server-allocated identifier for
its association with the peer and SHOULD NOT be shown to the user
because its value is initially ephemeral. Since the PeerId is
allocated by the server and the scope of the identifier is the single
server, the so-called identifier squatting attacks, where a malicious
peer could reserve another peer's identifier, are not possible in
EAP-NOOB. The server SHOULD assign a random or pseudo-random PeerId
to each new peer. It SHOULD NOT select the PeerId based on any peer
characteristics that it may know, such as the peer's link-layer
network address.
User reset or failure in the OOB Step can cause the peer to perform
many Initial Exchanges with the server, to allocate many PeerId
values, and to store the ephemeral protocol state for them. The peer
will typically only remember the latest one. EAP-NOOB leaves it to
the implementation to decide when to delete these ephemeral
associations. There is no security reason to delete them early, and
the server does not have any way to verify that the peers are
actually the same one. Thus, it is safest to store the ephemeral
states for at least one day. If the OOB messages are sent only in
the server-to-peer direction, the server SHOULD NOT delete the
ephemeral state before all the related Noob values have expired.
After completion of EAP-NOOB, the server may store the PeerInfo data,
and the user may use it to identify the peer and its attributes, such
as the make and model or serial number. A compromised peer could lie
in the PeerInfo that it sends to the server. If the server stores
any information about the peer, it is important that this information
is approved by the user during or after the OOB Step. Without
verification by the user or authentication with vendor certificates
on the application level, the PeerInfo is not authenticated
information and should not be relied on.
One possible use for the PeerInfo field is EAP channel binding
([RFC3748] Section 7.15). That is, the peer MAY include in PeerInfo
any data items that it wants to bind to the the EAP-NOOB association
and to the exported keys. These can be properties of the
authenticator or the access link, such as the SSID and BSSID of the
wireless network (see Appendix C).
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6.5. Identity protection
The PeerInfo field contains identifiers and other information about
the peer device (see Appendix C), and the peer sends this information
in plaintext to the EAP server before the server authentication in
EAP-NOOB has been completed. While the information refers to the
peer device and not directly to the user, it may be better for user
privacy to avoid sending unnecessary information. In the Reconnect
Exchange, the optional PeerInfo SHOULD be omitted unless some
critical data has changed.
Peer devices that randomize their layer-2 address to prevent tracking
can do this whenever the user resets the EAP-NOOB association.
During the lifetime of the association, the PeerId is a unique
identifier that can be used to track the peer in the access network.
Later versions of this specification may consider updating the PeerId
at each Reconnect Exchange. In that case, it is necessary to
consider how the authenticator and access-network administrators can
recognize and blacklist misbehaving peer devices and how to avoid
loss of synchronization between the server and the peer if messages
are lost during the identifier update.
6.6. Downgrading threats
The fingerprint Hoob protects all the information exchanged in the
Initial Exchange, including the cryptosuite negotiation. The message
authentication codes MACs and MACp also protect the same information.
The message authentication codes MACs2 and MACp2 protect information
exchanged during key renegotiation in the Reconnect Exchange. This
prevents downgrading attacks to weaker cryptosuites as long as the
possible attacks take more time than the maximum time allowed for the
EAP-NOOB completion. This is typically the case for recently
discovered cryptanalytic attacks.
As an additional precaution, the EAP server and peer MUST check for
downgrading attacks in the Reconnect Exchange af follows. As long as
the server or peer saves any information about the other endpoint, it
MUST also remember the previously negotiated cryptosuite and MUST NOT
accept renegotiation of any cryptosuite that is known to be weaker
than the previous one, such as a deprecated cryptosuite.
Integrity of the direction negotiation cannot be verified in the same
way as the integrity of the cryptosuite negotiation. That is, if the
OOB channel used in an application is critically insecure in one
direction, a man-in-the-middle attacker could modify the negotiation
messages and thereby cause that direction to be used. Applications
that support OOB messages in both directions SHOULD therefore ensure
that the OOB channel has sufficiently strong security in both
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directions. While this is a theoretical vulnerability, it could
arise in practice if EAP-NOOB is deployed in new applications.
Currently, we expect most peer devices to support only one OOB
direction, in which case interfering with the direction negotiation
can only prevent the completion of the protocol.
The long-term shared key material Kz in the persistent EAP-NOOB
association is established with an ECDHE key exchange when the peer
and server are first associated. It is a weaker secret than a
manually configured random shared key because advances in
cryptanalysis against the used ECDHE curve could eventually enable
the attacker to recover Kz. EAP-NOOB protects against such attacks
by allowing cryptosuite upgrades in the Reconnect Exchange and by
updating the shared key material Kz whenever the cryptosuite is
upgraded. We do not expect the cryptosuite upgrades to be frequent,
but if an upgrade becomes necessary, it can be done without manual
reset and reassociation of the peer devices.
6.7. Recovery from loss of last message
The EAP-NOOB Completion Exchange, as well as the Reconnect Exchange
with cryptosuite update, result in a persistent state change that
should take place either on both endpoints or on neither; otherwise,
the result is a state mismatch that requires user action to resolve.
The state mismatch can occur if the final EAP response of the
exchanges is lost. In the Completion Exchange, the loss of the final
response (Type=4) results in the peer moving to Registered (4) state
and creating a persistent EAP-NOOB association while the server stays
in an ephemeral state (1 or 2). In the Reconnect Exchange, the loss
of the final response (Type=7) results in the peer moving to the
Registered (4) state and updating its persistent key material Kz
while the server stays in the Reconnecting (3) state and keeps the
old key material.
The state mismatch is an example of a unavoidable problem in
distributed systems: it is theoretically impossible to guarantee
synchronous state changes in endpoints that communicate
asynchronously. The protocol will always have one critical message
that may get lost, so that one side commits to the state change and
the other side does not. In EAP, the critical message is the final
response from the peer to the server. While the final response is
normally followed by EAP-Success, [RFC3748] section 4.2 states that
the peer MAY assume that the EAP-Success was lost and the
authentication was successful. Furthermore, EAP method
implementations in the peer do not receive notification of the EAP-
Success message from the parent EAP state machine [RFC4137]. For
these reasons, EAP-NOOB on the peer side commits to a state change
already when it sends the final response.
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The best available solution to the loss of the critical message is to
keep trying. EAP retransmission behavior defined in Section 4.3 of
[RFC3748] suggests 3-5 retransmissions. In the absence of an
attacker, this would be sufficient to reduce the probability of
failure to an acceptable level. However, a determined attacker on
the in-band channel can drop the final EAP-Response message and all
subsequent retransmissions. In the Completion Exchange
(KeyingMode=0) and in the Reconnect Exchange with cryptosuite upgrade
(KeyingMode=3), this could result in a state mismatch and persistent
denial of service until user resets the peer state.
EAP-NOOB implements its own recovery mechanism that allows unlimited
retries of the Reconnect Exchange. When the DoS attacker eventually
stops dropping packets on the in-band channel, the protocol will
recover. The logic for this recovery mechanism is specified in
Section 3.4.2.
EAP-NOOB does not implement the same kind of retry mechanism in the
Completion Exchange. The reason is that there is always a user
involved in the initial association process, and the user can repeat
the OOB Step to complete the association after the DoS attacker has
left. On the other hand, Reconnect Exchange needs to work without
user involvement.
6.8. EAP security claims
EAP security claims are defined in section 7.2.1 of [RFC3748]. The
security claims for EAP-NOOB are listed in Table 9.
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+----------------+--------------------------------------------------+
| Security | EAP-NOOB claim |
| property | |
+----------------+--------------------------------------------------+
| Authentication | ECDHE key exchange with out-of-band |
| mechanism | authentication |
| | |
| Protected | yes |
| cryptosuite | |
| negotiation | |
| | |
| Mutual | yes |
| authentication | |
| | |
| Integrity | yes |
| protection | |
| | |
| Replay | yes |
| protection | |
| | |
| Key derivation | yes |
| | |
| Key strength | The specified cryptosuites provide key strength |
| | of at least 128 bits. |
| | |
| Dictionary | yes |
| attack | |
| protection | |
| | |
| Fast reconnect | yes |
| | |
| Cryptographic | not applicable |
| binding | |
| | |
| Session | yes |
| independence | |
| | |
| Fragmentation | no |
| | |
| Channel | yes (The ServerInfo and PeerInfo can be used to |
| binding | convey integrity-protected channel properties |
| | such as network SSID or peer MAC address.) |
+----------------+--------------------------------------------------+
Table 9: EAP security claims
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7. References
7.1. Normative references
[NIST-DH] Barker, E., Chen, L., Roginsky, A., and M. Smid,
"Recommendation for Pair-Wise Key Establishment Schemes
Using Discrete Logarithm Cryptography", NIST Special
Publication 800-56A Revision 2 , May 2013,
<http://nvlpubs.nist.gov/nistpubs/SpecialPublications/
NIST.SP.800-56Ar2.pdf>.
[RFC2104] Krawczyk, H., Bellare, M., and R. Canetti, "HMAC: Keyed-
Hashing for Message Authentication", RFC 2104,
DOI 10.17487/RFC2104, February 1997,
<https://www.rfc-editor.org/info/rfc2104>.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119,
DOI 10.17487/RFC2119, March 1997,
<https://www.rfc-editor.org/info/rfc2119>.
[RFC3748] Aboba, B., Blunk, L., Vollbrecht, J., Carlson, J., and H.
Levkowetz, Ed., "Extensible Authentication Protocol
(EAP)", RFC 3748, DOI 10.17487/RFC3748, June 2004,
<https://www.rfc-editor.org/info/rfc3748>.
[RFC4648] Josefsson, S., "The Base16, Base32, and Base64 Data
Encodings", RFC 4648, DOI 10.17487/RFC4648, October 2006,
<https://www.rfc-editor.org/info/rfc4648>.
[RFC5247] Aboba, B., Simon, D., and P. Eronen, "Extensible
Authentication Protocol (EAP) Key Management Framework",
RFC 5247, DOI 10.17487/RFC5247, August 2008,
<https://www.rfc-editor.org/info/rfc5247>.
[RFC6234] Eastlake 3rd, D. and T. Hansen, "US Secure Hash Algorithms
(SHA and SHA-based HMAC and HKDF)", RFC 6234,
DOI 10.17487/RFC6234, May 2011,
<https://www.rfc-editor.org/info/rfc6234>.
[RFC6761] Cheshire, S. and M. Krochmal, "Special-Use Domain Names",
RFC 6761, DOI 10.17487/RFC6761, February 2013,
<https://www.rfc-editor.org/info/rfc6761>.
[RFC7517] Jones, M., "JSON Web Key (JWK)", RFC 7517,
DOI 10.17487/RFC7517, May 2015,
<https://www.rfc-editor.org/info/rfc7517>.
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[RFC7518] Jones, M., "JSON Web Algorithms (JWA)", RFC 7518,
DOI 10.17487/RFC7518, May 2015,
<https://www.rfc-editor.org/info/rfc7518>.
[RFC7542] DeKok, A., "The Network Access Identifier", RFC 7542,
DOI 10.17487/RFC7542, May 2015,
<https://www.rfc-editor.org/info/rfc7542>.
[RFC7748] Langley, A., Hamburg, M., and S. Turner, "Elliptic Curves
for Security", RFC 7748, DOI 10.17487/RFC7748, January
2016, <https://www.rfc-editor.org/info/rfc7748>.
[RFC8126] Cotton, M., Leiba, B., and T. Narten, "Guidelines for
Writing an IANA Considerations Section in RFCs", BCP 26,
RFC 8126, DOI 10.17487/RFC8126, June 2017,
<https://www.rfc-editor.org/info/rfc8126>.
[RFC8259] Bray, T., Ed., "The JavaScript Object Notation (JSON) Data
Interchange Format", STD 90, RFC 8259,
DOI 10.17487/RFC8259, December 2017,
<https://www.rfc-editor.org/info/rfc8259>.
7.2. Informative references
[BluetoothPairing]
Bluetooth, SIG, "Simple pairing whitepaper", Technical
report , 2007.
[EUI-48] Institute of Electrical and Electronics Engineers,
"802-2014 IEEE Standard for Local and Metropolitan Area
Networks: Overview and Architecture.", IEEE Standard
802-2014. , June 2014.
[IEEE-802.1X]
Institute of Electrical and Electronics Engineers, "Local
and Metropolitan Area Networks: Port-Based Network Access
Control", IEEE Standard 802.1X-2004. , December 2004.
[mcrl2] Groote, J. and M. Mousavi, "Modeling and analysis of
communicating systems", The MIT press , 2014,
<https://mitpress.mit.edu/books/modeling-and-analysis-
communicating-systems>.
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[proverif]
Blanchet, B., Smyth, B., Cheval, V., and M. Sylvestre,
"ProVerif 2.00: Automatic Cryptographic Protocol Verifier,
User Manual and Tutorial", The MIT press , 2018,
<http://prosecco.gforge.inria.fr/personal/bblanche/
proverif/>.
[RFC2904] Vollbrecht, J., Calhoun, P., Farrell, S., Gommans, L.,
Gross, G., de Bruijn, B., de Laat, C., Holdrege, M., and
D. Spence, "AAA Authorization Framework", RFC 2904,
DOI 10.17487/RFC2904, August 2000,
<https://www.rfc-editor.org/info/rfc2904>.
[RFC4137] Vollbrecht, J., Eronen, P., Petroni, N., and Y. Ohba,
"State Machines for Extensible Authentication Protocol
(EAP) Peer and Authenticator", RFC 4137,
DOI 10.17487/RFC4137, August 2005,
<https://www.rfc-editor.org/info/rfc4137>.
[RFC4266] Hoffman, P., "The gopher URI Scheme", RFC 4266,
DOI 10.17487/RFC4266, November 2005,
<https://www.rfc-editor.org/info/rfc4266>.
[RFC5216] Simon, D., Aboba, B., and R. Hurst, "The EAP-TLS
Authentication Protocol", RFC 5216, DOI 10.17487/RFC5216,
March 2008, <https://www.rfc-editor.org/info/rfc5216>.
[RFC7942] Sheffer, Y. and A. Farrel, "Improving Awareness of Running
Code: The Implementation Status Section", BCP 205,
RFC 7942, DOI 10.17487/RFC7942, July 2016,
<https://www.rfc-editor.org/info/rfc7942>.
[Sethi14] Sethi, M., Oat, E., Di Francesco, M., and T. Aura, "Secure
Bootstrapping of Cloud-Managed Ubiquitous Displays",
Proceedings of ACM International Joint Conference on
Pervasive and Ubiquitous Computing (UbiComp 2014), pp.
739-750, Seattle, USA , September 2014,
<http://dx.doi.org/10.1145/2632048.2632049>.
[Sethi19] Sethi, M., Peltonen, A., and T. Aura, "Misbinding Attacks
on Secure Device Pairing", 2019,
<https://arxiv.org/abs/1902.07550>.
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Appendix A. Exchanges and events per state
Figure 11 shows how the EAP server chooses the exchange type
depending on the server and peer states. In the state combinations
marked with hyphen "-", there is no possible exchange and user action
is required to make progress. Note that peer state 4 is omitted from
the table because the peer never connects to the server when the peer
is in that state. The table also shows the handling of errors in
each exchange. A notable detail is that the recipient of error code
2003 moves to state 1.
+--------+---------------------------+------------------------------+
| peer | exchange chosen by | next peer and |
| states | server | server states |
+========+===========================+==============================+
| server state: Unregistered (0) |
+--------+---------------------------+------------------------------+
| 0..2 | Initial Exchange | both 1 (0 on error) |
| 3 | - | no change, notify user |
+--------+---------------------------+------------------------------+
| server state: Waiting for OOB (1) |
+--------+---------------------------+------------------------------+
| 0 | Initial Exchange | both 1 (0 on error) |
| 1 | Waiting Exchange | both 1 (no change on error) |
| 2 | Completion Exchange | both 4 (A) |
| 3 | - | no change, notify user |
+--------+---------------------------+------------------------------+
| server state: OOB Received (2) |
+--------+---------------------------+------------------------------+
| 0 | Initial Exchange | both 1 (0 on error) |
| 1 | Completion Exchange | both 4 (B) |
| 2 | Completion Exchange | both 4 (A) |
| 3 | - | no change, notify user |
+--------+---------------------------+------------------------------+
| server state: Reconnecting (3) or Registered (4) |
+--------+---------------------------+------------------------------+
| 0..2 | - | no change, notify user |
| 3 | Reconnect Exchange | both 4 (3 on error) |
+--------+---------------------------+------------------------------+
(A) peer to 1 on error 2003, no other changes on error
(B) server to 1 on error 2003, no other changes on error
Figure 11: How server chooses the exchange type
Figure 12 lists the local events that can take place in the server or
peer. Both the server and peer output and accept OOB messages in
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association state 1, leading the receiver to state 2. Communication
errors and timeouts in states 0..2 lead back to state 0, while
similar errors in states 3..4 lead to state 3. Application request
for rekeying (e.g. to refresh session keys or to upgrade cryptosuite)
also takes the association from state 3..4 to state 3. User can
always reset the association state to 0. Recovering association
data, e.g. from a backup, leads to state 3.
+--------+---------------------------+------------------------------+
| server/| possible local events | next state |
| peer | on server and peer | |
| state | | |
+========+===========================+==============================+
| 1 | OOB Output* | 1 |
| 1 | OOB Input* | 2 (1 on error) |
| 0..2 | Timeout/network failure | 0 |
| 3..4 | Timeout/network failure | 3 |
| 3..4 | Rekeying request | 3 |
| 0..4 | User resets peer state | 0 |
| 0..4 | Association state recovery| 3 |
+--------+---------------------------+------------------------------+
Figure 12: Local events on server and peer
Appendix B. Application-specific parameters
Table 10 lists OOB channel parameters that need to be specified in
each application that makes use of EAP-NOOB. The list is not
exhaustive and is included for the convenience of implementors only.
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+--------------------+----------------------------------------------+
| Parameter | Description |
+--------------------+----------------------------------------------+
| OobDirs | Allowed directions of the OOB channel |
| | |
| OobMessageEncoding | How the OOB message data fields are encoded |
| | for the OOB channel |
| | |
| SleepTimeDefault | Default minimum time in seconds that the |
| | peer should sleep before the next Waiting |
| | Exchange |
| | |
| OobRetries | Number of received OOB messages with invalid |
| | Hoob after which the receiver moves to |
| | Unregistered (0) state |
| | |
| NoobTimeout | How many seconds the sender of the OOB |
| | message remembers the sent Noob value. The |
| | RECOMMENDED value is 3600 seconds. |
| | |
| ServerInfoMembers | Required members in ServerInfo |
| | |
| PeerInfoMembers | Required members in PeerInfo |
+--------------------+----------------------------------------------+
Table 10: OOB channel characteristics
Appendix C. ServerInfo and PeerInfo contents
The ServerInfo and PeerInfo fields in the Initial Exchange and
Reconnect Exchange enable the server and peer, respectively, send
information about themselves to the other endpoint. They contain
JSON objects whose structure may be specified separately for each
application and each type of OOB channel. ServerInfo and PeerInfo
MAY contain auxiliary data needed for the OOB channel messaging and
for EAP channel binding. Table 11 lists some suggested data fields
for ServerInfo.
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+----------------+--------------------------------------------------+
| Data field | Description |
+----------------+--------------------------------------------------+
| ServerName | String that may be used to aid human |
| | identification of the server. |
| | |
| ServerURL | Prefix string when the OOB message is formatted |
| | as URL, as suggested in Appendix E. |
| | |
| SSIDList | List of wireless network identifier (SSID) |
| | strings used for roaming support, as suggested |
| | in Appendix D. JSON array of UTF-8 encoded SSID |
| | strings. |
| | |
| Base64SSIDList | List of wireless network identifier (SSID) |
| | strings used for roaming support, as suggested |
| | in Appendix D. JSON array of SSIDs, each of |
| | which is base64url encoded without padding. Peer |
| | SHOULD send at most one of the fields SSIDList |
| | and Base64SSIDList in PeerInfo, and the server |
| | SHOULD ignore SSIDList if Base64SSIDList is |
| | included. |
+----------------+--------------------------------------------------+
Table 11: Suggested ServerInfo data fields
PeerInfo typically contains auxiliary information for identifying and
managing peers on the application level at the server end. Table 12
lists some suggested data fields for PeerInfo.
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+--------------+----------------------------------------------------+
| Data field | Description |
+--------------+----------------------------------------------------+
| PeerName | String that may be used to aid human |
| | identification of the peer. |
| | |
| Manufacturer | Manufacturer or brand string. |
| | |
| Model | Manufacturer-specified model string. |
| | |
| SerialNumber | Manufacturer-assigned serial number. |
| | |
| MACAddress | Peer link-layer identifier (EUI-48) in the |
| | 12-digit base-16 form [EUI-48]. The string MAY |
| | include additional colon ':' or dash '-' |
| | characters that MUST be ignored by the server. |
| | |
| SSID | Wireless network SSID for channel binding. The |
| | SSID is a UTF-8 string. |
| | |
| Base64SSID | Wireless network SSID for channel binding. The |
| | SSID is base64url encoded. Peer SHOULD send at |
| | most one of the fields SSID and Base64SSID in |
| | PeerInfo, and the server SHOULD ignore SSID if |
| | Base64SSID is included. |
| | |
| BSSID | Wireless network BSSID (EUI-48) in the 12-digit |
| | base-16 form [EUI-48]. The string MAY include |
| | additional colon ':' or dash '-' characters that |
| | MUST be ignored by the server. |
| | |
+--------------+----------------------------------------------------+
Table 12: Suggested PeerInfo data fields
Appendix D. EAP-NOOB roaming
AAA architectures [RFC2904] allow for roaming of network-connected
appliances that are authenticated over EAP. While the peer is
roaming in a visited network, authentication still takes place
between the peer and an authentication server at its home network.
EAP-NOOB supports such roaming by assigning a Realm to the peer.
After the Realm has been assigned, the peer's NAI enables the visited
network to route the EAP session to the peer's home AAA server.
A peer device that is new or has gone through a hard reset should be
connected first to the home network and establish an EAP-NOOB
association with its home AAA server before it is able to roam.
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After that, it can perform the Reconnect Exchange from the visited
network.
Alternatively, the device may provide some method for the user to
configure the Realm of the home network. In that case, the EAP-NOOB
association can be created while roaming. The device will use the
user-assigned Realm in the Initial Exchange, which enables the EAP
messages to be routed correctly to the home AAA server.
While roaming, the device needs to identify the networks where the
EAP-NOOB association can be used to gain network access. For 802.11
access networks, the server MAY send a list of SSID strings in the
ServerInfo JSON object in a member called either SSIDList or
Base64SSIDList. The list is formated as explained in Table 11. If
present, the peer MAY use this list as a hint to determine the
networks where the EAP-NOOB association can be used for access
authorization, in addition to the access network where the Initial
Exchange took place.
Appendix E. OOB message as URL
While EAP-NOOB does not mandate any particular OOB communication
channel, typical OOB channels include graphical displays and emulated
NFC tags. In the peer-to-server direction, it may be convenient to
encode the OOB message as a URL, which is then encoded as a QR code
for displays and printers or as an NDEF record for NFC tags. A user
can then simply scan the QR code or NFC tag and open the URL, which
causes the OOB message to be delivered to the authentication server.
The URL MUST specify the https protocol i.e. secure connection to the
server, so that the man-in-the-middle attacker cannot read or modify
the OOB message.
The ServerInfo in this case includes a JSON member called ServerUrl
of the following format with maximum length of 60 characters:
https://<host>[:<port>]/[<path>]
To this, the peer appends the OOB message fields (PeerId, Noob, Hoob)
as a query string. PeerId is provided to the peer by the server and
might be a 22-character string. The peer base64url encodes, without
padding, the 16-byte values Noob and Hoob into 22-character strings.
The query parameters MAY be in any order. The resulting URL is of
the following format:
https://<host>[:<port>]/[<path>]?P=<PeerId>&N=<Noob>&H=<Hoob>
The following is an example of a well-formed URL encoding the OOB
message (without line breaks):
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https://example.com/Noob?P=ZrD7qkczNoHGbGcN2bN0&N=rMinS0-F4EfCU8D9ljx
X_A&H=QvnMp4UGxuQVFaXPW_14UW
Appendix F. Example messages
The message examples in this section are generated with Curve25519
ECDHE test vectors specified in section 6.1 of [RFC7748]
(server=Alice, peer=Bob). The direction of the OOB channel
negotiated is 2 (server-to-peer). The JSON messages are as follows
(line breaks are for readability only).
====== Initial Exchange ======
Identity response:
noob@eap-noob.net
EAP request (type 9):
{"Type":9}
EAP response (type 9):
{"Type":9,"PeerId":"07KRU6OgqX0HIeRFldnbSW","PeerState":0}
EAP request (type 1):
{"Type":1,"Vers":[1],"PeerId":"07KRU6OgqX0HIeRFldnbSW","Realm":"no
ob.example.com","Cryptosuites":[1],"Dirs":3,"ServerInfo":{"Name":"
Example","Url":"https://noob.example.com/sendOOB"}}
EAP response (type 1):
{"Type":1,"Verp":1,"PeerId":"07KRU6OgqX0HIeRFldnbSW","Cryptosuitep
":1,"Dirp":2,"PeerInfo":{"Make":"Acme","Type":"None","Serial":"DU-
9999","SSID":"Noob1","BSSID":"6c:19:8f:83:c2:80"}}
EAP request (type 2):
{"Type":2,"PeerId":"07KRU6OgqX0HIeRFldnbSW","PKs":{"kty":"EC","crv
":"Curve25519","x":"hSDwCYkwp1R0i33ctD73Wg2_Og0mOBr066SpjqqbTmo"},
"Ns":"PYO7NVd9Af3BxEri1MI6hL8Ck49YxwCjSRPqlC1SPbw","SleepTime":60}
EAP response (type 2):
{"Type":2,"PeerId":"07KRU6OgqX0HIeRFldnbSW","PKp":{"kty":"EC","crv
":"Curve25519","x":"3p7bfXt9wbTTW2HC7OQ1Nz-DQ8hbeGdNrfx-FG-
IK08"},"Np":"HIvB6g0n2btpxEcU7YXnWB-451ED6L6veQQd6ugiPFU"}
====== Waiting Exchange ======
Identity response:
noob@eap-noob.net
EAP request (type 9):
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{"Type":9}
EAP response (type 9):
{"Type":9,"PeerId":"07KRU6OgqX0HIeRFldnbSW","PeerState":1}
EAP request (type 3):
{"Type":3,"PeerId":"07KRU6OgqX0HIeRFldnbSW","SleepTime":60}
EAP response (type 3):
{"Type":3,"PeerId":"07KRU6OgqX0HIeRFldnbSW"}
====== OOB Step ======
OOB message:
P=07KRU6OgqX0HIeRFldnbSW&N=x3JlolaPciK4Wa6XlMJxtQ&H=WJ6Covspd50NT2
RxkLHSeA
====== Completion Exchange ======
Identity response:
noob@eap-noob.net
EAP request (type 9):
{"Type":9}
EAP response (type 9):
{"Type":9,"PeerId":"07KRU6OgqX0HIeRFldnbSW","PeerState":2}
EAP request (type 8):
{"Type":8,"PeerId":"07KRU6OgqX0HIeRFldnbSW"}
EAP response (type 8):
{"Type":8,"PeerId":"07KRU6OgqX0HIeRFldnbSW","NoobId":"U0OHwYGCS4nE
kzk2TPIE6g"}
EAP request (type 4):
{"Type":4,"PeerId":"07KRU6OgqX0HIeRFldnbSW","NoobId":"U0OHwYGCS4nE
kzk2TPIE6g","MACs":"APpnhlFLWS2pfJPH5S7N3yr6FJWocuaAiuVrhgh8Xko"}
EAP response (type 4):
{"Type":4,"PeerId":"07KRU6OgqX0HIeRFldnbSW","MACp":"hihGS4v8w4cDy_
yokNlOyQa87GRBLvMfmF9JFwJ6RrQ"}
====== Reconnect Exchange ======
Identity response:
noob@eap-noob.net
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EAP request (type 9):
{"Type":9}
EAP response (type 9):
{"Type":9,"PeerId":"07KRU6OgqX0HIeRFldnbSW","PeerState":3}
EAP request (type 5):
{"Type":5,"Vers":[1],"PeerId":"07KRU6OgqX0HIeRFldnbSW","Cryptosuit
es":[1],"Realm":"noob.example.com","ServerInfo":{"Name":"Example",
"Url":"https://noob.example.com/sendOOB"}}
EAP response (type 5):
{"Type":5,"Verp":1,"PeerId":"07KRU6OgqX0HIeRFldnbSW","Cryptosuitep
":1,"PeerInfo":{"Make":"Acme","Type":"None","Serial":"DU-
9999","SSID":"Noob1","BSSID":"6c:19:8f:83:c2:80"}}
EAP request (type 6):
{"Type":6,"PeerId":"07KRU6OgqX0HIeRFldnbSW","KeyingMode":2,"Ns2":"
RDLahHBlIgnmL_F_xcynrHurLPkCsrp3G3B_S82WUF4"}
EAP response (type 6):
{"Type":6,"PeerId":"07KRU6OgqX0HIeRFldnbSW","Np2":"jN0_V4P0JoTqwI9
VHHQKd9ozUh7tQdc9ABd-j6oTy_4"}
EAP request (type 7):
{"Type":7,"PeerId":"07KRU6OgqX0HIeRFldnbSW","MACs2":"TT_B9w-
o86C1c1O_rhNxzcf9gJa0_8SiIhyxQecdM70"}
EAP response (type 7):
{"Type":7,"PeerId":"07KRU6OgqX0HIeRFldnbSW","MACp2":"GS9f8Mw3mUFvj
IDKS54U27xPt6umIrnVXOGLl-iFRKk"}
Appendix G. TODO list
o
Appendix H. Version history
o Version 01:
* Fixed Reconnection Exchange.
* URL examples.
* Message examples.
* Improved state transition (event) tables.
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o Version 02:
* Reworked the rekeying and key derivation.
* Increased internal key lengths and in-band nonce and HMAC
lengths to 32 bytes.
* Less data in the persistent EAP-NOOB association.
* Updated reference [NIST-DH] to Revision 2 (2013).
* Shorter suggested PeerId format.
* Optimized the example of encoding OOB message as URL.
* NoobId in Completion Exchange to differentiate between multiple
valid Noob values.
* List of application-specific parameters in appendix.
* Clarified the equivalence of Unregistered state and no state.
* Peer SHOULD probe the server regardless of the OOB channel
direction.
* Added new error messages.
* Realm is part of the persistent association and can be updated.
* Clarified error handling.
* Updated message examples.
* Explained roaming in appendix.
* More accurate definition of timeout for the Noob nonce.
* Additions to security considerations.
o Version 03:
* Clarified reasons for going to Reconnecting state.
* Included Verp in persistent state.
* Added appendix on suggested ServerInfo and PeerInfo fields.
* Exporting PeerId and SessionId.
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* Explicitly specified next state after OOB Step.
* Clarified the processing of an expired OOB message and
unrecognized NoobId.
* Enabled protocol version upgrade in Reconnect Exchange.
* Explained handling of redundant received OOB messages.
* Clarified where raw and base64url encoded values are used.
* Cryptosuite must specify the detailed format of the JWK object.
* Base64url encoding in JSON strings is done without padding.
* Simplified explanation of PeerId, Realm and NAI.
* Added error codes for private and experimental use.
* Updated the security considerations.
o Version 04:
* Recovery from synchronization failure due to lost last
response.
o Version 05:
* Kz identifier added to help recovery from lost last messages.
* Error message codes changed for better structure.
* Improved security considerations section.
o Version 06:
* Kz identifier removed to enable PeerId anonymization in the
future.
* Clarified text on when to use server-assigned realm.
* Send PeerId and PeerState in a separate request-reponse pair,
not in NAI.
* New subsection for the common handshake in all exchanges to
avoid repetition.
o Version 07:
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* Updated example messages.
* Added pointers to new implementation in Contiki.
o Version 08:
* Editorial improvements and corrections.
Appendix I. Acknowledgments
Aleksi Peltonen modeled the protocol specification with the mCRL2
formal specification language. Shiva Prasad TP and Raghavendra MS
implemented parts of the protocol with wpa_supplicant and hostapd.
Their inputs helped us in improving the specification.
The authors would also like to thank Rhys Smith and Josh Howlett for
providing valuable feedback as well as new use cases and requirements
for the protocol. Thanks to Eric Rescorla, Darshak Thakore, Stefan
Winter, Hannes Tschofenig, and Daniel Migault for interesting
discussions in this problem space.
Authors' Addresses
Tuomas Aura
Aalto University
Aalto 00076
Finland
EMail: tuomas.aura@aalto.fi
Mohit Sethi
Ericsson
Jorvas 02420
Finland
EMail: mohit@piuha.net
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