ACE Working Group C. Sengul
Internet-Draft A. Kirby
Intended status: Standards Track Nominet
Expires: October 12, 2018 P. Fremantle
University of Portsmouth
April 10, 2018
MQTT-TLS profile of ACE
draft-sengul-ace-mqtt-tls-profile-02
Abstract
This document specifies a profile for the ACE (Authentication and
Authorization for Constrained Environments) to enable authorization
in an MQTT-based publish-subscribe messaging system. Proof-of-
possession keys, bound to OAuth2.0 access tokens, are used to
authenticate and authorize publisher and subscriber clients. The
protocol relies on TLS for confidentiality and server authentication.
Status of This Memo
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provisions of BCP 78 and BCP 79.
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This Internet-Draft will expire on October 12, 2018.
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 2
1.1. Requirements Language . . . . . . . . . . . . . . . . . . 4
1.2. ACE-Related Terminology . . . . . . . . . . . . . . . . . 4
1.3. MQTT-Related Terminology . . . . . . . . . . . . . . . . 4
2. Basic Protocol Interactions . . . . . . . . . . . . . . . . . 5
2.1. Authorizing Connection Establishment . . . . . . . . . . 6
2.1.1. Client Authorization Server (CAS) and Authorization
Server (AS) Interaction . . . . . . . . . . . . . . . 7
2.1.2. Client connection request to the broker . . . . . . . 8
2.1.3. Token validation . . . . . . . . . . . . . . . . . . 10
2.1.4. The broker's response to client connection request . 11
2.2. Authorizing PUBLISH messages . . . . . . . . . . . . . . 11
2.2.1. PUBLISH messages from the publisher client to the
broker . . . . . . . . . . . . . . . . . . . . . . . 11
2.2.2. PUBLISH messages from the broker to the subscriber
clients . . . . . . . . . . . . . . . . . . . . . . . 12
2.3. Authorizing SUBSCRIBE messages . . . . . . . . . . . . . 12
2.4. Token expiration . . . . . . . . . . . . . . . . . . . . 13
2.5. Handling disconnections and retained messages . . . . . . 13
3. Improved Protocol Interactions with MQTT v5 . . . . . . . . . 14
3.1. Token Transport via Authentication Exchange (AUTH) . . . 14
3.2. Authorization Errors and Client Re-authentication . . . . 16
4. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 16
5. Security Considerations . . . . . . . . . . . . . . . . . . . 16
6. Privacy Considerations . . . . . . . . . . . . . . . . . . . 17
7. References . . . . . . . . . . . . . . . . . . . . . . . . . 17
7.1. Normative References . . . . . . . . . . . . . . . . . . 17
7.2. Informative References . . . . . . . . . . . . . . . . . 17
Appendix A. Checklist for profile requirements . . . . . . . . . 18
Appendix B. The authorization information endpoint . . . . . . . 19
Appendix C. Document Updates . . . . . . . . . . . . . . . . . . 19
Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . . 20
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 20
1. Introduction
This document specifies a profile for the ACE framework
[I-D.ietf-ace-oauth-authz]. In this profile, clients and a resource
server use MQTT to communicate. The protocol relies on TLS for
communication security between entities. The basic protocol
interactions follow MQTT v3.1 - the OASIS Standard
[MQTT-OASIS-Standard]. In addition, this document describes
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improvements to the basic protocol with the new MQTT v5 - the OASIS
Specification Draft [MQTT-OASIS-Standard-v5] (e.g., improved
authentication exchange and error reporting). Both versions are
expected to be supported in practice, and therefore, covered in this
document.
MQTT is a publish-subscribe protocol and supports two types of client
operation: publish and subscribe. Once connected, a client can
publish to multiple topics, and subscribe to multiple topics;
however, for the purpose of this document, these actions are
described separately. The MQTT broker is responsible for
distributing messages published by the publishers to the appropriate
subscribers. Each publish message contains a topic, which is used by
the broker to filter the subscribers for the message. Subscribers
must subscribe to the topics to receive the corresponding messages.
In this document, message topics are treated as resources. Clients
use an access token, bound to a key (the proof-of-possession key) to
authorize with the MQTT broker their connection and publish/subscribe
permissions to topics. In the context of this ACE profile, the MQTT
broker acts as the resource server. In order to provide
communication confidentiality and resource server authentication, TLS
is used.
Clients use client authorization servers [I-D.ietf-ace-actors] to
obtain tokens from the authorization server. The communication
protocol between the client authorization server and the
authorization server is assumed to be HTTPS. Also, if the broker
supports token introspection, it is assumed to use HTTPS to
communicate with the authorization server. These interfaces MAY be
implemented using other protocols e.g., CoAP or MQTT. This document
makes the same assumptions as the Section 4 of the ACE framework
[I-D.ietf-ace-oauth-authz] in terms of client and RS registration
with the AS and establishing of keying material.
This document describes authorization of the following exchanges
between publisher and subscriber clients, and the broker.
o Connection establishment between the clients and the broker
o Publish messages from the publishers to the broker, and from the
broker to the subscribers
o Subscribe messages from the subscribers to the broker
In Section 2, these exchanges are described based on the MQTT v3.1 -
the OASIS Standard [MQTT-OASIS-Standard]. These exchanges are also
supported by the new MQTT v5 - the OASIS Specification Draft
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[MQTT-OASIS-Standard-v5]. Section 3 describes how they may be
improved by the new MQTT v5.
1.1. Requirements Language
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 RFC 2119 [RFC2119].
1.2. ACE-Related Terminology
The terminology for entities in the architecture is defined in OAuth
2.0 RFC 6749 [RFC6749] and ACE actors [I-D.ietf-ace-actors], such as
"Client" (C), "Resource Server" (RS) and "Authorization Server" (AS).
The term "endpoint" is used following its OAuth definition, to denote
resources such as /token and /introspect at the AS.
The term "Resource" is used to refer to an MQTT "topic", which is
defined in Section 1.2. Hence, the "Resource Owner" is any entity
that can authoritatively speak for the "topic".
Certain security-related terms such as "authentication",
"authorization", "confidentiality", "(data) integrity", "message
authentication code", and "verify" are taken from RFC 4949 [RFC4949].
1.3. MQTT-Related Terminology
The document describes message exchanges as MQTT protocol
interactions. For additional information, please refer to the MQTT
v3.1 - the OASIS Standard [MQTT-OASIS-Standard] or the MQTT v5 - the
OASIS Specification Draft [MQTT-OASIS-Standard-v5].
Topic name
The label attached to an application message, which is
matched to a subscription.
Topic filter
An expression that indicates interest in one or more topic
names. Topic filters may include wildcards.
Subscription
A subscription comprises a Topic filter and a maximum quality
of service (QoS).
Application Message
The data carried by the MQTT protocol. The data has an
associated QoS level and a Topic name.
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MQTT sends various control messages across a network connection. The
following is not an exhaustive list and the control packets that are
not relevant for authorization are not explained. These include, for
instance, the PUBREL and PUBCOMP packets used in the 4-step handshake
required for the QoS level 2.
CONNECT
Client request to connect to the broker. After a network
connection is established, this is the first packet sent by a
client.
CONNACK
The broker connection acknowledgment. The first packet sent
from the broker to a client is a CONNACK packet. CONNACK
packets contain return codes indicating either a success or
an error state to a client.
PUBLISH
Publish packet that can be sent from a client to the broker,
or from the broker to a client.
PUBACK
Response to PUBLISH packet with QoS level 1. PUBACK can be
sent from the broker to a client or a client to the broker.
PUBREC
Response to PUBLISH packet with QoS level 2. PUBREC can be
sent from the broker to a client or a client to the broker.
SUBSCRIBE
The client subscribe request.
SUBACK
Subscribe acknowledgment.
PINGREQ A ping request sent from a client to the broker. It signals
to the broker that the client is alive, and is used to
confirm that the broker is still alive.
2. Basic Protocol Interactions
This section describes the following exchanges between publisher and
subscriber clients, the broker, and the authorization server
according to the MQTT v3.1 - the OASIS Standard
[MQTT-OASIS-Standard]. These exchanges are compatible also with the
new MQTT v5 - the OASIS Specification Draft [MQTT-OASIS-Standard-v5].
In addition, Section 3 describes how these exchanges may be improved
with the MQTT v5.
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o Authorizing connection establishment between the clients and the
broker
o Authorizing publish messages from the publishers to the broker,
and from the broker to the subscribers
o Authorizing subscribe messages from the subscribers to the broker
Message topics are treated as resources. The publisher and
subscriber clients are assumed to have identified the topics of
interest out-of-band (topic discovery is not a feature of the MQTT
protocol).
A connection request carries a token specifying the permissions that
the client has (e.g., publish permission to a given topic). A
resource owner can pre-configure policies at the AS that give clients
publish or subscribe permissions to different topics.
2.1. Authorizing Connection Establishment
This section specifies how publishers and subscribers establish an
authorized connection to an MQTT broker. The token request and
response use the /token endpoint of the authorization server, as
specified in Section 6 of the ACE framework
[I-D.ietf-ace-oauth-authz].
Figure 1 shows the basic protocol flow during connection
establishment.
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+----------------+
+---(A) Token request----| Client |
| | Authorization |
| +-(B) Access token-->| Server |
| | |________________|
| | |
| | (C) Client On-boarding
| | |
| | +---------v-----+
+--v-------------+ | Publisher or |
| | | Subscriber |
| Authorization | |_______________|
| Server | | ^
|________________| | |
| ^ (D)Connection (G)Connection
| | request + response
| | access token |
| | | |
| | +---v--------------+
| | | Broker |
| +(E)Introspection-| Resource Server |
| request | |
+-(F)Introspection---->|__________________|
response
Figure 1: Connection establishment
2.1.1. Client Authorization Server (CAS) and Authorization Server (AS)
Interaction
The first step in the protocol flow (Figure 1 (A)) is token
acquisition by the client authorization server (CAS) from the AS. If
a client has enough resources and can support HTTPS, or optionally
the AS supports MQTTS, these steps can instead be carried out by a
client directly.
When requesting an access token from the AS, the CAS MAY include
parameters in its request as defined in Section 6.1 of the ACE
framework [I-D.ietf-ace-oauth-authz]. The content type is set to
"application/json". The profile name is 'mqtt_tls'.
If the access token request has been successfully verified by the AS
and the client is authorized to obtain a token for the indicated
audience (e.g., topics) and scopes (e.g., publish/subscribe
permissions), the AS issues an access token (Figure 1 (B)). The
response includes the parameters described in Section 6.2 of the ACE
framework [I-D.ietf-ace-oauth-authz]. This includes a token, which
is assumed to be PoP by default. Hence, a 'cnf' parameter with a
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symmetric or asymmetric PoP key is returned. The token may be a
reference, or a CBOR or JWT web token. Note that the 'cnf' parameter
in the web tokens are to be consumed by the resource server and not
the client. For more information on Proof of Possession semantics in
JWTs see RFC 7800 [RFC7800] and for CWTs, see Proof-of-Possession Key
Semantics for CBOR Web Tokens (CWTs)
[I-D.ietf-ace-cwt-proof-of-possession].
In the case of an error, the AS returns error responses for HTTP-
based interactions as ASCII codes in JSON content, as defined in
Section 5.2 of RFC 6749 [RFC6749].
2.1.2. Client connection request to the broker
Client on-boarding (Figure 1 (C)) is out of the scope of this
document. Once the client acquires the token, it can use it to
request an MQTT connection to the broker over a TLS session with
server authentication (Figure 1 (D)). This section describes the
client transporting the token to the broker (RS) via the CONNECT
control message after the TLS handshake. This is similar to an
earlier proposal by Fremantle et al. [fremantle14]. An improvement
to this is presented in Section 3 for the MQTT v5 - the OASIS
Specification Draft [MQTT-OASIS-Standard-v5]. Alternatively, the
token may be used for the TLS session establishment as described in
the DTLS profile for ACE [I-D.gerdes-ace-dtls-authorize]. In this
case, both the TLS PSK and RPK handshakes MAY be supported. This may
additionally require that the client transports the token to the
broker before the connection establishment. To this end, the broker
MAY support /authz-info endpoint via the "authz-info" topic. Then,
to transport the token, clients publish to "authz-info" topic
unauthorized. The topic "authz-info" MUST be publish-only for
clients (i.e., the clients are not allowed to subscribe to it). This
option is described in more detail in Appendix B.
When the client wishes to connect to the broker, it uses the CONNECT
message of MQTT. Figure 2 shows the structure of the MQTT CONNECT
control message.
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0 8 16 24 32
+------------------------------------------------------+
|CPT=1 | Rsvd.|Remaining len.| Protocol name len. = 4 |
+------------------------------------------------------+
| 'M' 'Q' 'T' 'T' |
+------------------------------------------------------+
| Proto.level=4|Connect flags| Keep alive |
+------------------------------------------------------+
| Payload including User Name (='token') |
| Password length and data (=signature/MAC) |
| ... |
+------------------------------------------------------+
Figure 2: MQTT CONNECT control message. (CPT=Control Packet Type,
Rsvd=Reserved, len.=length, Proto.=Protocol)
To communicate the necessary connection parameters, the Client uses
the appropriate flags of the CONNECT message. Figure 3 shows how the
MQTT connect flags MUST be set to initiate a connection with the
broker.
+-----------------------------------------------------------+
|User name|Pass.|Will retain|Will QoS|Will Flag|Clean| Rsvd.|
| flag |flag | | | | | |
+-----------------------------------------------------------+
| 1 | 1 | X | X X | X | 1 | 0 |
+-----------------------------------------------------------+
Figure 3: MQTT CONNECT flags. (Rsvd=Reserved)
In order to ensure that the client and the broker discard any
previous session and start a new session, the Clean Session Flag MUST
be set to 1.
The Will flag indicates that a Will message needs to be sent when a
client disconnection occurs. The situations in which the Will
message is published include disconnections due to I/O or network
failures, and the server closing the networking connection due to a
protocol error. The client may set the Will flag as desired (marked
as 'X' in Figure 3). If the Will flag is set to 1 and the broker
accepts the connection request, the broker must store the Will
message, and publish it when the network connection is closed
according to Will QoS and Will retain parameters, and MQTT Will
management rules. Section 2.5 explains how the broker deals with the
retained messages in further detail.
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Finally, Username and Password flags MUST be set to 1 to ensure that
the Payload of the CONNECT message includes both Username and
Password fields.
The CONNECT message defaults to ACE for authentication and
authorization. For the basic operation described in this section,
the Username field MUST be set to the token. The Password field MUST
be set to the keyed message digest (MAC) or signature. The client
MAY apply the PoP key either to the token or the entire request by
computing a keyed message digest (for symmetric key) or a digital
signature (for asymmetric key). (The Username field is a UTF-8
encoded string, which is prefixed with a two-byte length field and
can have any length in the range of 0 and 65535. Similarly, the
password field contains 0 to 65535 bytes of binary data, prefixed by
a two-byte length field.)
2.1.3. Token validation
RS MUST verify the validity of the token. This validation MAY be
done locally (e.g., in the case of a self-contained token) or the RS
MAY send an introspection request to the AS. If introspection is
used, this section follows similar steps to those described in
Sections 7.2 and 7.3 of the ACE framework [I-D.ietf-ace-oauth-authz].
The communication between AS and RS MAY be HTTPS, but it, in every
case, MUST be confidential, mutually authenticated and integrity
protected.
The broker MUST check if the token is active either using
'expires_in' parameter of the token or 'active' parameter of the
introspection response.
The access token is constructed by the AS such that RS can associate
the access token with the client key. This document assumes that the
Access Token is a PoP token as described in
[I-D.ietf-ace-oauth-authz]. Therefore, the necessary information is
contained in the 'cnf' claim of the access token and may use either
public or shared key approaches. The client uses the signature or
the MAC in the password field to prove the possession of the key.
Depending on the chosen implementation, the resource server validates
the signature or the MAC over the token or the contents of the
packet, authenticating the client.
The broker uses the scope field in the token (or in the introspection
result) to determine the publish and subscribe permissions for the
client. If the Will flag is set, then the broker MUST check that the
token allows the publication of the Will message too.
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The broker MAY cache the introspection result because it will need to
decide whether to accept subsequent PUBLISH and SUBSCRIBE messages
and these messages, which are sent after a connection is set-up, do
not contain tokens. If the introspection result is not cached, then
the RS needs to introspect the saved token for each request.
Note: Scope strings MAY follow an application specific convention.
One option is to encode the permission and the topics it applies to
the scope string e.g., 'publish_topic1' or 'subscribe_topic2'. A
second option is to simply use the keywords 'publish' or 'subscribe'
as scope strings and use the 'aud' field to define the topic.
Another option is to use topic names as scope strings and use the
'aud' field to define whether the 'publish' or 'subscribe' permission
applies to these scopes. The choice is left to the implementer and
depends on how the following trade-off is expected to be handled:
token simplicity versus the number of tokens the broker is expected
to handle per client.
2.1.4. The broker's response to client connection request
Based on the validation result (obtained either via local inspection
or using the /introspection interface of the AS), the broker MUST
send a CONNACK message to the client.
The broker responses may follow either the MQTT v3.1 - the OASIS
Standard [MQTT-OASIS-Standard] or the MQTT v5 - the OASIS
Specification Draft [MQTT-OASIS-Standard-v5], depending on which
version(s) the broker supports.
In MQTT v3.1 - the OASIS Standard [MQTT-OASIS-Standard], it is not
possible to support AS discovery via sending a tokenless CONNECT
message to the broker. This is because a CONNACK packet does not
include a means to provide additional information to the client.
Therefore, AS discovery needs to take place out-of-band. This is
remedied in the MQTT v5 - the OASIS Specification Draft
[MQTT-OASIS-Standard-v5] and a solution is described in Section 3.
If the RS accepts the connection, it MUST store the token.
2.2. Authorizing PUBLISH messages
2.2.1. PUBLISH messages from the publisher client to the broker
On receiving the PUBLISH message, the broker MUST use the type of
message (i.e., PUBLISH) and the topic name in the message header to
compare against the cached token or its introspection result
(depending on the implementation, different fields of the token or
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the introspection result may be checked, see the Note in
Section 2.1.3).
If the client is allowed to publish to the topic, the RS must publish
the message to all valid subscribers of the topic. The broker may
also return an acknowledgment message if the QoS level is greater
than or equal to 1.
In case of a failure, it is not possible to return an error in MQTT
v3.1 - the OASIS Standard [MQTT-OASIS-Standard]. The return of
acknowledgement messages only indicates success. In the case of an
authorization error, the broker SHOULD disconnect the client.
Otherwise, it MUST ignore the PUBLISH message. Also, DISCONNECT
messages are only sent from a client to the broker. So, server
disconnection needs to take place below the application layer.
However, in MQTT v5 - the OASIS Specification Draft
[MQTT-OASIS-Standard-v5], it is possible to indicate failure and
provide a reason code. Section 3 describes in more detail how
PUBLISH authorization errors are handled.
2.2.2. PUBLISH messages from the broker to the subscriber clients
To forward PUBLISH messages to the subscribing clients, the broker
identifies all the subscribers that have matching valid topic
subscriptions (i.e., the tokens are valid and token scopes allow a
subscription to the particular topic name). The broker sends a
PUBLISH message with the topic name and the topic message to all the
valid subscribers.
In MQTT, after connection establishment, there is no way to inform a
client that an authorization error has occurred for previously
subscribed topics, e.g., token expiry. In the case of an
authorization error, the broker has two options: (1) stop forwarding
PUBLISH messages to the unauthorized client or (2) disconnect the
client. In the MQTT v3.1 - the OASIS Standard [MQTT-OASIS-Standard],
the MQTT DISCONNECT messages are only sent from a client to the
broker. Therefore, the server disconnection needs to take place
below the application layer. In MQTT v5 - the OASIS Specification
Draft [MQTT-OASIS-Standard-v5], a server-side DISCONNECT message is
possible and described in Section 3.
2.3. Authorizing SUBSCRIBE messages
In MQTT, a SUBSCRIBE message is sent from a client to the broker to
create one or more subscriptions to one or more topics. The
SUBSCRIBE message may contain multiple topic filters. The topic
filters may include wildcard characters.
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On receiving the SUBSCRIBE message, the broker MUST use the type of
message (i.e., SUBSCRIBE) and the topic filter in the message header
to compare against the stored token or introspection result
(depending on the implementation, different fields of the token or
introspection result may be checked, see the Note in Section 2.1.3).
As a response to the SUBSCRIBE message, the broker issues a SUBACK
message. For each topic filter, the SUBACK packet includes a return
code matching the QoS level for the corresponding topic filter. In
the case of failure, the return code, in MQTT v3.1, must be 0x80
indicating 'Failure'. In MQTT v5, the appropriate return code is
0x87, indicating that the client is 'Not authorized'. Note that, in
both MQTT versions, a reason code is returned for each topic filter.
Therefore, the client may receive success codes for a subset of its
topic filters, while being unauthorized for the rest.
2.4. Token expiration
The broker MUST check for token expiration whenever a CONNECT,
PUBLISH or SUBSCRIBE message is received or sent. The broker SHOULD
check for token expiration on receiving a PINGREQUEST message. This
may allow for early detection of a token expiry.
The token validation is done either by checking the 'exp' claim of a
CWT/JWT or via performing an introspection request with the
Authorization server as described in Section 8.2 of the ACE framework
[I-D.ietf-ace-oauth-authz]. In the basic operation, token
expirations MAY lead to disconnecting the associated client.
However, in MQTT v5 - the OASIS Specification Draft
[MQTT-OASIS-Standard-v5], better error handling and re-authentication
are possible. This is explained in more detail in Section 3.
2.5. Handling disconnections and retained messages
According to MQTT v3.1 - the OASIS Standard [MQTT-OASIS-Standard],
only Client DISCONNECT messages are allowed. In MQTT v5 - the OASIS
Specification Draft [MQTT-OASIS-Standard-v5], server-side DISCONNECT
messages are possible, allowing to return '0x87 Not Authorized'
return code to the client.
In the case of a DISCONNECT, due to the Clean Session flag, the
broker deletes all session state but MUST keep the retained messages.
By setting a RETAIN flag in a PUBLISH message the publisher indicates
to the broker that it should store the most recent message for the
associated topic. Hence, the new subscribers can receive the last
sent message from the publisher for that particular topic without
waiting for the next PUBLISH message. In the case of a
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disconnection, the broker MUST continue publishing the retained
messages as long as the associated tokens are valid.
In case of disconnections due to network errors or server
disconnection due to a protocol error (which includes authorization
errors), the Will message must be sent if the client supplied a Will
in the CONNECT request message. The token provided in the CONNECT
request must cover the Will topic. The Will message MUST be
published to the Will topic when the network connection is closed
regardless of whether the corresponding token has expired.
3. Improved Protocol Interactions with MQTT v5
In the new MQTT v5 - the OASIS Specification Draft
[MQTT-OASIS-Standard-v5], several new capabilities are introduced,
which enable better integration with the ACE standards. The newly
enhanced authentication and re-authentication methods support a much
wider range of authentication flows beyond username and password.
With the MQTT v5, there is a clearly defined approach for using
token-based approaches. Similarly, in MQTT v5, it is possible for a
client to request a re-authentication. Finally, MQTT v5 generally
improves error reporting, enabling better response to authorization
failures during publishing messages to the subscribers.
3.1. Token Transport via Authentication Exchange (AUTH)
To initiate the authentication and authorization flow, as before, the
CAS initiates the token request as in Section 2.1. When the client
wishes to connect to the RS (broker), it uses the CONNECT message of
MQTT. Figure 4 shows the structure of the MQTT CONNECT control
message used in MQTT v5.
0 8 16 24 32
+------------------------------------------------------+
|CPT=1 | Rsvd.|Remaining len.| Protocol name len. = 4 |
+------------------------------------------------------+
| 'M' 'Q' 'T' 'T' |
+------------------------------------------------------+
| Proto.level=5|Connect flags| Keep alive |
+------------------------------------------------------+
| Property length |
| Auth. Method (0x15) | 'ace_mqtt_tls' |
| Auth. Data (0x16) | empty or token |
| |
+------------------------------------------------------+
Figure 4: MQTT CONNECT control message. (CPT=Control Packet Type,
Rsvd=Reserved, len.=length, Proto.=Protocol)
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To communicate the necessary connection parameters, the client uses
the appropriate flags of the CONNECT message. To achieve a clean
session (i.e., the session should start without an existing session),
the new MQTT v5 session flags MUST be set appropriately: the Clean
Start Flag MUST be set to 1 and Session Expiry Interval MUST be set
to 0.
With the enhanced authentication capabilities, it is not necessary to
overload the username and password fields in the CONNECT message for
ACE authentication. Nevertheless, the RS MUST support both methods
for supporting the token: (1) Token transport via username and
password and (2) using the new AUTH (Authentication Exchange) method.
The token transport via username and password is as described in
Section 2.1.2. The rest of this section describes the AUTH method.
To use the AUTH method, the username flag MUST be set to 0 and the
password flag MUST be set to 0. The client can set the
Authentication Method as a property of a CONNECT packet by setting
Auth Properties (with the property identifier 0x15). The client must
MUST set the UTF-8 encoded string containing the name of the
authentication method as 'ace_mqtt_tls'. If the RS does not support
this profile, it sends a CONNACK with a Reason Code of '0x8C (Bad
authentication method)'
The Authentication Method is followed by the Authentication Data,
which has a property identifier 0x16. Authentication data is binary
data and is defined by the authentication method. The RS MAY support
different implementations for transporting the authentication data.
The first option is that Authentication data contains both the token
and the keyed message digest (MAC) or signature as described in
Section 2.1.2. In this case, the token validation proceeds as
described in Section 2.1.3 and the server responds with a CONNACK.
The reason code of the CONNACK '0x00 (Success)' if the authentication
is successful. In case of an invalid PoP token, the CONNACK reason
code is '0x87 (Not Authorized)'.
The second option that RS may accept is a challenge/response
protocol. If the Authentication Data only includes the token, the RS
MUST respond with an AUTH packet, with the Authenticate Reason Code
set to '0x18 (Continue Authentication)'. This packet includes the
Authentication Method, which MUST be set to 'ace_mqtt_tls' and
Authentication Data. The Authentication Data MUST NOT be empty and
contains a challenge for the client. The client responds to this
with an AUTH packet, with a reason code '0x18 (Continue
Authentication)'. Similarly, the client packet sets the
Authentication Method to 'ace_mqtt_tls'. The Authentication Data in
the client's response contains the signature or MAC computed over the
RS's challenge. To this, the server responds with a CONNACK and a
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return code of '0x00 (Success)' if the authentication is successful.
In case of an invalid PoP token, the CONNACK reason code is '0x87
(Not Authorized)'.
Finally, this document allows the CONNECT message to have an empty
Authentication Data field. This is the AS discovery option and the
RS responds with a CONNACK reason code '0x87 (Not Authorized)' and
includes a User Property set to the address of the AS.
3.2. Authorization Errors and Client Re-authentication
MQTT v5 allows better error reporting. To take advantage of this for
PUBLISH messages, the QoS level should be set to greater than or
equal to 1. This guarantees that RS responds with either a PUBACK or
PUBREC packet with a reason code '0x87 (Not authorized)' in the case
of an authorization error. Similarly, for the SUBSCRIBE case, the
SUBACK packet will have a reason code set to '0x87 (Not authorized)'
for the unauthorized topic(s). When RS is forwarding PUBLISH
messages to the subscribed clients, it may discover that some of the
subscribers are no more authorized due to expired tokens. In this
case, the RS SHOULD send a DISCONNECT message with the reason code
'0x87 (Not authorized)'. Note that the server-side DISCONNECT is a
new feature of MQTT v5 (in MQTT v3.1 server needed to drop the
connection). RS MUST stop forwarding messages to the unauthorized
subscribers.
In the case of a PUBACK with '0x87 (Not authorized)', the client can
update its token using the Re-authentication feature of MQTT v5.
Also, the clients can proactively update their tokens without waiting
for such a PUBACK. To re-authenticate, the client sends an AUTH
packet with a reason code '0x19 (Re-authentication)'. The client
MUST set the authentication method as 'ace_mqtt_tls' and transport
the new token in the Authentication Data. The client and the RS go
through the same steps for proof of possession validation described
in the previous section. If the re-authentication fails, the server
MUST send a DISCONNECT with the reason code '0x87 (Not Authorized)'.
4. IANA Considerations
This memo includes no request to IANA.
5. Security Considerations
The security considerations outlined in [I-D.ietf-ace-oauth-authz]
apply to this work.
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6. Privacy Considerations
The privacy considerations outlined in [I-D.ietf-ace-oauth-authz]
apply to this work. Furthermore, the RS is a central trusted party
and may forward potentially sensitive information between clients.
7. References
7.1. Normative References
[I-D.gerdes-ace-dtls-authorize]
Gerdes, S., Bergmann, O., Bormann, C., Selander, G., and
L. Seitz, "Datagram Transport Layer Security (DTLS)
Profile for Authentication and Authorization for
Constrained Environments (ACE)", draft-gerdes-ace-dtls-
authorize-01 (work in progress), March 2017.
[I-D.ietf-ace-oauth-authz]
Seitz, L., Selander, G., Wahlstroem, E., Erdtman, S., and
H. Tschofenig, "Authentication and Authorization for
Constrained Environments (ACE) using the OAuth 2.0
Framework (ACE-OAuth)", draft-ietf-ace-oauth-authz-11
(work in progress), March 2018.
[MQTT-OASIS-Standard]
Banks, A., Ed. and R. Gupta, Ed., "OASIS Standard MQTT
Version 3.1.1 Plus Errata 01", 2015, <http://docs.oasis-
open.org/mqtt/mqtt/v3.1.1/mqtt-v3.1.1.html>.
[MQTT-OASIS-Standard-v5]
Banks, A., Ed., Briggs, E., Ed., Borgendale, K., Ed., and
R. Gupta, Ed., "OASIS Public Review Draft 01 MQTT Version
5.0", 2017, <http://docs.oasis-
open.org/mqtt/mqtt/v5.0/csprd01/mqtt-v5.0-csprd01.html>.
[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>.
7.2. Informative References
[fremantle14]
Fremantle, P., Aziz, B., Kopecky, J., and P. Scott,
"Federated Identity and Access Management for the Internet
of Things", research International Workshop on Secure
Internet of Things, September 2014,
<http://dx.doi.org/10.1109/SIoT.2014.8>.
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[I-D.ietf-ace-actors]
Gerdes, S., Seitz, L., Selander, G., and C. Bormann, "An
architecture for authorization in constrained
environments", draft-ietf-ace-actors-06 (work in
progress), November 2017.
[I-D.ietf-ace-cwt-proof-of-possession]
Jones, M., Seitz, L., Selander, G., Wahlstroem, E.,
Erdtman, S., and H. Tschofenig, "Proof-of-Possession Key
Semantics for CBOR Web Tokens (CWTs)", draft-ietf-ace-cwt-
proof-of-possession-02 (work in progress), March 2018.
[RFC4949] Shirey, R., "Internet Security Glossary, Version 2",
FYI 36, RFC 4949, DOI 10.17487/RFC4949, August 2007,
<https://www.rfc-editor.org/info/rfc4949>.
[RFC6749] Hardt, D., Ed., "The OAuth 2.0 Authorization Framework",
RFC 6749, DOI 10.17487/RFC6749, October 2012,
<https://www.rfc-editor.org/info/rfc6749>.
[RFC7800] Jones, M., Bradley, J., and H. Tschofenig, "Proof-of-
Possession Key Semantics for JSON Web Tokens (JWTs)",
RFC 7800, DOI 10.17487/RFC7800, April 2016,
<https://www.rfc-editor.org/info/rfc7800>.
Appendix A. Checklist for profile requirements
o AS discovery: For the basic protocol using either MQTT v3.1 or
MQTT v5, the clients/client authorization servers need to be
configured out-of-band. RS does not provide any hints to help AS
discovery. AS discovery is possible with the MQTT v5 extensions
described in Section 3.
o The communication protocol between the client and RS: MQTT
o The security protocol between the client and RS: TLS
o Client and RS mutual authentication: RS provides a server
certificate during TLS handshake. Client transports token and MAC
via the MQTT CONNECT message.
o Content format: For the HTTPS interactions with AS, "application/
json". The MQTT payloads may be formatted JSON or CBOR.
o PoP protocols: Either symmetric or asymmetric keys can be
supported.
o Unique profile identifier: mqtt_tls
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o Token introspection: RS uses HTTPS /introspect interface of AS.
o Token request: CAS uses HTTPS /token interface of AS.
o /authz-info endpoint: It MAY be supported using the method
described in Appendix B, not protected.
o Token transport: In MQTT CONNECT message or using the AUTH
extensions for MQTT v5 described in Section 3.
Appendix B. The authorization information endpoint
The main document described a method for transporting tokens inside
MQTT CONNECT messages. In this section, we describe an alternative
method to transport an access token.
The method consists of the MQTT broker accepting PUBLISH messages to
a public "authz-info" topic. A client using this method MUST first
connect to the broker, and publish the access token using the "authz-
info" topic. The broker must verify the validity of the token (i.e.,
through local validation or introspection). After publishing the
token, the client disconnects from the broker and is expected to try
reconnecting over TLS.
In MQTT v3.1, after the client published to the "authz-info" topic,
it is not possible for the broker to communicate the result of the
token verification. In MQTT v5, the broker can return 'Not
authorized' error to a PUBLISH request for QoS greater or equal to 1.
In any case, any token authorization failure will affect the TLS
handshake, which can prompt the client to obtain a valid token.
Appendix C. Document Updates
Version 01 updates Version 00 as follows:
o Adds Section 3 to describe improvements to the basic protocol
operation with the new MQTT v5 - OASIS Specification Draft
[MQTT-OASIS-Standard-v5], including improved authentication
exchange and error reporting.
o Condenses background information specific to MQTT in Section 2.
o Clarifies token transport and token structure in Section 2.1.2 and
Section 2.1.3.
o Removes Appendix on error reporting as this is now handled with
MQTT v5.
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Version 02 updates Version 01 as follows:
o Adds PINGREQ packet for token expiry checks.
o Minor typo fixes.
Acknowledgements
The authors would like to thank Ludwig Seitz for his input on the
authorization information endpoint, presented in the appendix.
Authors' Addresses
Cigdem Sengul
Nominet
2 Kingdom Street
London W2 6BD
UK
Email: Cigdem.Sengul@nominet.uk
Anthony Kirby
Nominet
Minerva House, Edmund Halley Road
Oxford OX4 4DQ
UK
Email: Anthony.Kirby@nominet.uk
Paul Fremantle
University of Portsmouth
School of Computing, Buckingham House
Portsmouth PO1 3HE
UK
Email: paul.fremantle@port.ac.uk
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