MQTT
MQTT is a light weight, client to server, publish / subscribe messaging protocol. MQTT has been specifically designed to reduce transport overhead (and thus network traffic) and code footprint on client devices. For this reason MQTT is ideally suited to constrained devices such as sensors and actuators and is quickly becoming the defacto standard communication protocol for IoT.
Apache ActiveMQ Artemis supports the following MQTT versions (with links to their respective specifications):
By default there are acceptor
elements configured to accept MQTT connections
on ports 61616
and 1883
.
See the general Protocols and Interoperability
chapter for details on configuring an acceptor
for MQTT.
Refer to the MQTT examples for a look at some of this functionality in action.
MQTT Quality of Service
MQTT offers 3 quality of service levels.
Each message (or topic subscription) can define a quality of service that is associated with it. The quality of service level defined on a topic is the maximum level a client is willing to accept. The quality of service level on a message is the desired quality of service level for this message. The broker will attempt to deliver messages to subscribers at the highest quality of service level based on what is defined on the message and topic subscription.
Each quality of service level offers a level of guarantee by which a message is sent or received:
QoS 0:
AT MOST ONCE
Guarantees that a particular message is only ever received by the subscriber a maximum of one time. This does mean that the message may never arrive. The sender and the receiver will attempt to deliver the message, but if something fails and the message does not reach its destination (say due to a network connection) the message may be lost. This QoS has the least network traffic overhead and the least burden on the client and the broker and is often useful for telemetry data where it doesn't matter if some of the data is lost.
QoS 1:
AT LEAST ONCE
Guarantees that a message will reach its intended recipient one or more times. The sender will continue to send the message until it receives an acknowledgment from the recipient, confirming it has received the message. The result of this QoS is that the recipient may receive the message multiple times, and also increases the network overhead than QoS 0, (due to acks). In addition more burden is placed on the sender as it needs to store the message and retry should it fail to receive an ack in a reasonable time.
QoS 2:
EXACTLY ONCE
The most costly of the QoS (in terms of network traffic and burden on sender and receiver) this QoS will ensure that the message is received by a recipient exactly one time. This ensures that the receiver never gets any duplicate copies of the message and will eventually get it, but at the extra cost of network overhead and complexity required on the sender and receiver.
MQTT Retain Messages
MQTT has an interesting feature in which messages can be "retained" for a particular address. This means that once a retain message has been sent to an address, any new subscribers to that address will receive the last sent retain message before any others messages, this happens even if the retained message was sent before a client has connected or subscribed. An example of where this feature might be useful is in environments such as IoT where devices need to quickly get the current state of a system when they are on boarded into a system.
Will Messages
A will message can be sent when a client initially connects to a broker. Clients are able to set a "will message" as part of the connect packet. If the client abnormally disconnects, say due to a device or network failure the broker will proceed to publish the will message to the specified address (as defined also in the connect packet). Other subscribers to the will topic will receive the will message and can react accordingly. This feature can be useful in an IoT style scenario to detect errors across a potentially large scale deployment of devices.
Debug Logging
Detailed protocol logging (e.g. packets in/out) can be activated by turning
on TRACE
logging for org.apache.activemq.artemis.core.protocol.mqtt
. Follow
these steps to configure
logging appropriately.
The MQTT specification doesn't dictate the format of the payloads which clients publish. As far as the broker is concerned a payload is just an array of bytes. However, to facilitate logging the broker will encode the payloads as UTF-8 strings and print them up to 256 characters. Payload logging is limited to avoid filling the logs with potentially hundreds of megabytes of unhelpful information.
Custom Client ID Handling
The client ID used by an MQTT application is very important as it uniquely
identifies the application. In some situations broker administrators may want
to perform extra validation or even modify incoming client IDs to support
specific use-cases. This is possible by implementing a custom security manager
as demonstrated in the security-manager
example shipped with the broker.
The simplest implementation is a "wrapper" just like the security-manager
example uses. In the authenticate
method you can modify the client ID using
setClientId()
on the org.apache.activemq.artemis.spi.core.protocol.RemotingConnection
that is passed in. If you perform some custom validation of the client ID you
can reject the client ID by throwing a org.apache.activemq.artemis.core.protocol.mqtt.exceptions.InvalidClientIdException
.
Wildcard subscriptions
MQTT addresses are hierarchical much like a file system, and they use a special
character (i.e. /
by default) to separate hierarchical levels. Subscribers
are able to subscribe to specific topics or to whole branches of a hierarchy.
To subscribe to branches of an address hierarchy a subscriber can use wild cards. There are 2 types of wildcards in MQTT:
Multi level (
#
)Adding this wildcard to an address would match all branches of the address hierarchy under a specified node. For example:
/uk/#
Would match/uk/cities
,/uk/cities/newcastle
and also/uk/rivers/tyne
. Subscribing to an address#
would result in subscribing to all topics in the broker. This can be useful, but should be done so with care since it has significant performance implications.Single level (
+
)Matches a single level in the address hierarchy. For example
/uk/+/stores
would match/uk/newcastle/stores
but not/uk/cities/newcastle/stores
.
These MQTT-specific wildcards are automatically translated into the wildcard syntax used by ActiveMQ Artemis. These wildcards are configurable. See the Wildcard Syntax chapter for details about how to configure custom wildcards.
Web Sockets
Apache ActiveMQ Artemis also supports MQTT over Web Sockets. Modern web browsers which support Web Sockets can send and receive MQTT messages.
MQTT over Web Sockets is supported via a normal MQTT acceptor:
<acceptor name="mqtt-ws-acceptor">tcp://localhost:1883?protocols=MQTT</acceptor>
With this configuration, Apache ActiveMQ Artemis will accept MQTT connections
over Web Sockets on the port 1883
. Web browsers can then connect to
ws://<server>:1883
using a Web Socket to send and receive MQTT messages.
Automatic Subscription Clean-up
Sometimes MQTT clients don't clean up their subscriptions. In such situations
the auto-delete-queues-delay
and auto-delete-queues-message-count
address-settings can be used to clean up the abandoned subscription queues.
However, the MQTT session meta-data is still present in memory and needs to be
cleaned up as well. The URL parameter defaultMqttSessionExpiryInterval
can be
configured on the MQTT acceptor
to deal with this situation.
MQTT 5 added a new session expiry interval
property with the same basic semantics. The broker will use the client's value
for this property if it is set. If it is not set then it will apply the
defaultMqttSessionExpiryInterval
.
The default defaultMqttSessionExpiryInterval
is -1
which means no MQTT 3.x
session states will be expired and no MQTT 5 session states which do not pass
their own session expiry interval will be expired. Otherwise it represents the
number of seconds which must elapse after the client has disconnected
before the broker will remove the session state.
MQTT session state is scanned every 5,000 milliseconds by default. This can be
changed using the mqtt-session-scan-interval
element set in the core
section
of broker.xml
.
Flow Control
MQTT 5 introduced a simple form of flow control. In short, a broker can tell a client how many QoS 1 & 2 messages it can receive before being acknowledged and vice versa.
This is controlled on the broker by setting the receiveMaximum
URL parameter on
the MQTT acceptor
in broker.xml
.
The default value is 65535
(the maximum value of the 2-byte integer used by
MQTT).
A value of 0
is prohibited by the MQTT 5 specification.
A value of -1
will prevent the broker from informing the client of any receive
maximum which means flow-control will be disabled from clients to the broker.
This is effectively the same as setting the value to 65535
, but reduces the size
of the CONNACK
packet by a few bytes.
Topic Alias Maximum
MQTT 5 introduced topic aliasing.
This is an optimization for the size of PUBLISH
control packets as a 2-byte
integer value can now be substituted for the name of the topic which can
potentially be quite long.
Both the client and the broker can inform each other about the maximum alias
value they support (i.e. how many different aliases they support). This is
controlled on the broker using the topicAliasMaximum
URL parameter on the
acceptor
used by the MQTT client.
The default value is 65535
(the maximum value of the 2-byte integer used by
MQTT).
A value of 0
will disable topic aliasing from clients to the broker.
A value of -1
will prevent the broker from informing the client of any topic
alias maximum which means aliasing will be disabled from clients to the broker.
This is effectively the same as setting the value to 0
, but reduces the size
of the CONNACK
packet by a few bytes.
Maximum Packet Size
MQTT 5 introduced the maximum packet size. This is the maximum packet size the server or client is willing to accept.
This is controlled on the broker by setting the maximumPacketSize
URL parameter
on the MQTT acceptor
in broker.xml
.
The default value is 268435455
(i.e. 256MB - the maximum value of the variable
byte integer used by MQTT).
A value of 0
is prohibited by the MQTT 5 specification.
A value of -1
will prevent the broker from informing the client of any maximum
packet size which means no limit will be enforced on the size of incoming packets.
This also reduces the size of the CONNACK
packet by a few bytes.
Server Keep Alive
All MQTT versions support a connection keep alive value defined by the client. MQTT 5 introduced a server keep alive value so that a broker can define the value that the client should use. The primary use of the server keep alive is for the server to inform the client that it will disconnect the client for inactivity sooner than the keep alive specified by the client.
This is controlled on the broker by setting the serverKeepAlive
URL parameter
on the MQTT acceptor
in broker.xml
.
The default value is 60
and is measured in seconds.
A value of 0
completely disables keep alives no matter the client's keep alive
value. This is not recommended because disabling keep alives is generally
considered dangerous since it could lead to resource exhaustion.
A value of -1
means the broker will always accept the client's keep alive
value (even if that value is 0
).
Any other value means the serverKeepAlive
will be applied if it is less than
the client's keep alive value unless the client's keep alive value is 0
in
which case the serverKeepAlive
is applied. This is because a value of 0
would
disable keep alives and disabling keep alives is generally considered dangerous
since it could lead to resource exhaustion.
Enhanced Authentication
MQTT 5 introduced enhanced authentication which extends the existing name & password authentication to include challenge / response style authentication.
However, there are currently no challenge / response mechanisms implemented so if
a client passes the "Authentication Method" property in its CONNECT
packet it will
receive a CONNACK
with a reason code of 0x8C
(i.e. bad authentication method)
and the network connection will be closed.
Publish Authorization Failures
The MQTT 3.1.1 specification is ambiguous regarding the broker's behavior when
a PUBLISH
packet fails due to a lack of authorization. In section 3.3.5
it says:
If a Server implementation does not authorize a PUBLISH to be performed by a Client; it has no way of informing that Client. It MUST either make a positive acknowledgement, according to the normal QoS rules, or close the Network Connection
By default the broker will close the network connection. However if you'd rather
have the broker make a positive acknowledgement then set the URL parameter
closeMqttConnectionOnPublishAuthorizationFailure
to false
on the relevant
MQTT acceptor
in broker.xml
, e.g.:
<acceptor name="mqtt">tcp://0.0.0:1883?protocols=MQTT;closeMqttConnectionOnPublishAuthorizationFailure=false</acceptor>