Basic Configuration
The onfiguration of the Mosquitto broker is done in a configuration file.
Name
mosquitto.conf — the configuration file for mosquitto
Synopsis
mosquitto.conf
Description
mosquitto.conf
is the configuration file for mosquitto. This file can reside anywhere as long as mosquitto can read it.
File Format
All lines with a # as the very first character are treated as a comment.
Configuration lines start with a variable name. The variable value is separated from the name by a single space.
Authentication
The authentication options described below allow a wide range of possibilities in conjunction with the listener options. This section aims to clarify the possibilities.
The simplest option is to have no authentication at all. This is the default if no other options are given. Unauthenticated encrypted support is provided by using the certificate based SSL/TLS based options certfile and keyfile.
MQTT provides username/password authentication as part of the protocol. Use the password_file option to define the valid usernames and passwords. Be sure to use network encryption if you are using this option otherwise the username and password will be vulnerable to interception. Use the per_listener_settings
to control whether passwords are required globally or on a per-listener basis.
When using certificate based encryption there are three options that affect authentication. The first is require_certificate, which may be set to true or false. If false, the SSL/TLS component of the client will verify the server, but there is no requirement for the client to provide anything for the server: authentication is limited to the MQTT built in username/password. If require_certificate is true, the client must provide a valid certificate in order to connect successfully. In this case, the second and third options, use_identity_as_username
and use_subject_as_username
, become relevant. If set to true, use_identity_as_username
causes the Common Name (CN) from the client certificate to be used instead of the MQTT username for access control purposes. The password is not used because it is assumed that only authenticated clients have valid certificates. This means that any CA certificates you include in cafile or capath will be able to issue client certificates that are valid for connecting to your broker. If use_identity_as_username
is false, the client must authenticate as normal (if required by password_file) through the MQTT options. The same principle applies for the use_subject_as_username
option, but the entire certificate subject is used as the username instead of just the CN.
If require_certificate
is true and use_identity/subject_as_username
is true, then clients can only connect with a valid cert, and they are hence forced to have a valid username. In that case the password check is completely bypassed.
When using pre-shared-key based encryption through the psk_hint and psk_file options, the client must provide a valid identity and key in order to connect to the broker before any MQTT communication takes place. If use_identity_as_username
is true, the PSK identity is used instead of the MQTT username for access control purposes. If use_identity_as_username
is false, the client may still authenticate using the MQTT username/password if using the password_file
option.
Both certificate and PSK based encryption are configured on a per-listener basis.
Authentication plugins can be created to augment the password_file
, acl_file
and psk_file
options with e.g. SQL based lookups.
It is possible to support multiple authentication schemes at once. A config could be created that had a listener for all of the different encryption options described above and hence a large number of ways of authenticating.
General Options
acl_file file path
Set the path to an access control list file. If defined, the contents of the file are used to control client access to topics on the broker.
If this parameter is defined then only the topics listed will have access. Topic access is added with lines of the format:
topic [read|write|readwrite|deny] \<topic>
The access type is controlled using "read", "write", "readwrite" or "deny". This parameter is optional (unless \<topic> includes a space character) - if not given then the access is read/write. \<topic> can contain the + or # wildcards as in subscriptions. The "deny" option can used to explicitly deny access to a topic that would otherwise be granted by a broader read/write/readwrite statement. Any "deny" topics are handled before topics that grant read/write access.
The first set of topics are applied to anonymous clients, assuming allow_anonymous is true. User specific topic ACLs are added after a user line as follows:
user \<username>
The username referred to here is the same as in password_file. It is not the clientid.
It is also possible to define ACLs based on pattern substitution within the topic. The form is the same as for the topic keyword, but using pattern as the keyword.
pattern [read|write|readwrite|deny] \<topic>
The patterns available for substition are:
%c
to match the client id of the client%u
to match the username of the client
The substitution pattern must be the only text for that level of hierarchy. Pattern ACLs apply to all users even if the "user" keyword has previously been given.
Example:
pattern write sensor/%u/data
Allow access for bridge connection messages:
pattern write $SYS/broker/connection/%c/state
If the first character of a line of the ACL file is a #
it is treated as a comment.
If per_listener_settings
is true, this option applies to the current listener being configured only. If per_listener_settings
is false, this option applies to all listeners.
Reloaded on reload signal. The currently loaded ACLs will be freed and reloaded. Existing subscriptions will be affected after the reload.
allow_anonymous [ true | false ]
Listeners
The listeners open ports on the broker side, to allow clients connecting to the brokers using the port.
The network ports that Mosquitto listens to can be controlled using listeners.
The default listener options can be overridden and further listeners can be created.
Multiple Listeners
You can have different authentication options on different listeners if you use per_listener_settings true. For example:
per_listener_settings true
listener 1883
password_file no-tls.passwd
listener 8883
cafile ca.crt
certfile server.crt
keyfile server.key
password_file tls.passwd
It's not just password_file which can be listener specific, most of the auth/access options are.
General Configuration Information
Configuration Files
A configuration file, often abbreviated as configuration file, defines the parameters, options, settings and preferences to be applied in an IT context.
Proxy Subscription
A proxy is a communication interface in a network. It works as an intermediary, taking requests and then connecting to the other side via its own address.
This serves as a method to simplify or control the complexity of the request, or provide additional benefits such as load balancing, privacy, or security.
Proxies were devised to add structure and encapsulation to distributed systems.
A proxy server thus functions on behalf of the client when requesting service, potentially masking the true origin of the request to the resource server.
Randomness
provided by the SSL library.
Random Numbers are a cryptographic primitive and cornerstone to nearly all cryptographic systems.
They are used in almost all areas of cryptography, from key agreement and transport to session keys for bulk encryption.
A quality source of random bits and proper use of OpenSSL APIs will help ensure your program is cryptographically sound.
On the other hand, a poor source of randomness or incorrect library usage could result in loss of security.
This article will help you use random number generation routines correctly when programming with the OpenSSL library.
OCSP
supported, not tested
With the Online Certificate Status Protocol, an external service is used to store revocation information for individual certificates centrally with a so-called OCSP responder.
The MQTT broker now queries the validity of a specific client certificate from this service.
This allows the information to be managed centrally instead of being rolled out to all MQTT brokers.
Clients
Username
The client username maps to the username provided in the CONNECT packet when a device connects. The username is unique across the plugin, so attempting to create a client with a duplicate username will result in an error. The username acts as the primary key if you want to change anything about the client.
user username
When run as root, change to this user and its primary group on startup. If set to "mosquitto" or left unset, and if the "mosquitto" user does not exist, then mosquitto will change to the "nobody" user instead. If this is set to another value and mosquitto is unable to change to this user and group, it will exit with an error. The user specified must have read/write access to the persistence database if it is to be written. If run as a non-root user, this setting has no effect. Defaults to mosquitto.
This setting has no effect on Windows and so you should run mosquitto as the user you wish it to run as.
Not reloaded on reload signal.
Read more about [Username] (NEW_security.md#authentication).
Password
The client password maps to the password provided in the CONNECT packet when a device connects. The password may be unset when a client is created, this will mean that devices will be unable to connect as the corresponding client.
The password can be updated at any point, but only by a client with the correct access. Devices typically cannot update their own passwords.
Read more about [Password] (NEW_security.md#authentication).
Client ID
The client id maps to the client id provided in the CONNECT packet when a device connects. This is an optional attribute.
If the client id is empty or not provided, then any device can connect with the username for this client regardless of its client id. This means that multiple devices could connect with the same credentials at the same time, but sharing credentials between devices is not recommended.
If the client id is set, then a device can only connect as this client if the triple of username, password, and client id all match those in the client.
Groups
A client can be a member of any number of groups.
Roles
A client can be assigned to any number of roles. A role gives the client access to different topics.
Text name
This is an optional text field to give a human friendly name to this client.
Text description
This is an optional text field to give a human friendly description to this client.
Disabled A client can be set to be enabled/disabled at any point. Disabling a client means that any devices currently connected using the credentials for that client will be disconnected and unable to reconnect.(#).
Bridges
Introduction
Multiple brokers can be connected together with the bridging functionality. This is useful where it is desirable to share information between locations, but where not all of the information needs to be shared. An example could be where a number of users are running a broker to help record power usage and for a number of other reasons. The power usage could be shared through bridging all of the user brokers to a common broker, allowing the power usage of all users to be collected and compared. The other information would remain local to each broker.
MQTT Bridge
Whenever information (data) must be transferred, but the clients do not have permission to access another's MQTT broker, bridges are being used. Each client accesses its own broker, but shared specific information with the other client.
Certificates and Bridges
In advance the client send you a certificate.
Prior the client set up an ACL on the Mosquitto broker. Ensuring the connectiong broker only can have access to location with data meant for the connecting broker.
Within the ACL the client has set a username and password, in order to authenticate the broker connecting.
These last two lines define which topic branches will be published (out) and which will be subscribed to (in) from the point of view of your broker. There are a lot of things you can tweak in this configuration, but this is should get you started.
Publishes
Both broker you want to bridge must subscribe to each other.
The brokers will then receive the messages published and forward them to the sibscribing clients.
Configuring Bridges
SIGHUP
Upon receiving the SIGHUP signal, mosquitto will attempt to reload configuration file data, assuming that the -c argument was provided when mosquitto was started. Not all configuration parameters can be reloaded without restarting.
SIGUSR1
Upon receiving the SIGUSR1 signal, mosquitto will write the persistence database to disk. This signal is only acted upon if persistence is enabled.
persistence [ true | false ]
If true, connection, subscription and message data will be written to the disk in mosquitto.db at the location dictated by persistence_location. When mosquitto is restarted, it will reload the information stored in mosquitto.db. The data will be written to disk when mosquitto closes and also at periodic intervals as defined by autosave_interval. Writing of the persistence database may also be forced by sending mosquitto the SIGUSR1 signal. If false, the data will be stored in memory only. Defaults to false.
The persistence file may change its format in a new version. The broker can currently read all old formats, but will only save in the latest format. It should always be safe to upgrade, but cautious users may wish to take a copy of the persistence file before installing a new version so that they can roll back to an earlier version if necessary.
This option applies globally.
Reloaded on reload signal.
persistence_file file name
The filename to use for the persistent database. Defaults to mosquitto.db.
This option applies globally.
Reloaded on reload signal.
persistent_client_expiration duration
This option allows persistent clients (those with clean session set to false) to be removed if they do not reconnect within a certain time frame. This is a non-standard option. As far as the MQTT spec is concerned, persistent clients persist forever.
Badly designed clients may set clean session to false whilst using a randomly generated client id. This leads to persistent clients that will never reconnect. This option allows these clients to be removed.
The expiration period should be an integer followed by one of h d w m y for hour, day, week, month and year respectively. For example:
persistent_client_expiration
2mpersistent_client_expiration
14dpersistent_client_expiration
1y
As this is a non-standard option, the default if not set is to never expire persistent clients.
This option applies globally.
Reloaded on reload signal.
persistence_location path
The path where the persistence database should be stored. If not given, then the current directory is used.
This option applies globally.
Reloaded on reload signal.
SIGUSR2
The SIGUSR2 signal causes mosquitto to print out the current subscription tree, along with information about where retained messages exist. This is intended as a testing feature only and may be removed at any time.
Heap Configuration
As the document queue fills with unprocessed messages, it consumes heap memory. Further memory is consumed for document processing like parsing and indexing. The combined heap memory consumption must be less than the maximum heap size of the process.
memory_limit limit
This option sets the maximum number of heap memory bytes that the broker will allocate, and hence sets a hard limit on memory use by the broker. Memory requests that exceed this value will be denied. The effect will vary depending on what has been denied. If an incoming message is being processed, then the message will be dropped and the publishing client will be disconnected. If an outgoing message is being sent, then the individual message will be dropped and the receiving client will be disconnected. Defaults to no limit.
This option is only available if memory tracking support is compiled in.
Reloaded on reload signal. Setting to a lower value and reloading will not result in memory being freed.
Further options to avoid heap
message_size_limit limit
This option sets the maximum publish payload size that the broker will allow. Received messages that exceed this size will not be accepted by the broker. This means that the message will not be forwarded on to subscribing clients, but the QoS flow will be completed for QoS 1 or QoS 2 messages. MQTT v5 clients using QoS 1 or QoS 2 will receive a PUBACK or PUBREC with the "implementation specific error" reason code.
The default value is 0, which means that all valid MQTT messages are accepted. MQTT imposes a maximum payload size of 268435455 bytes.
This option applies globally.
Reloaded on reload signal.
max_packet_size value
For MQTT v5 clients, it is possible to have the server send a "maximum packet size" value that will instruct the client it will not accept MQTT packets with size greater than value bytes. This applies to the full MQTT packet, not just the payload. Setting this option to a positive value will set the maximum packet size to that number of bytes. If a client sends a packet which is larger than this value, it will be disconnected. This applies to all clients regardless of the protocol version they are using, but v3.1.1 and earlier clients will of course not have received the maximum packet size information. Defaults to no limit.
This option applies to all clients, not just those using MQTT v5, but it is not possible to notify clients using MQTT v3.1.1 or MQTT v3.1 of the limit.
Setting below 20 bytes is forbidden because it is likely to interfere with normal client operation even with small payloads.
This option applies globally.
Reloaded on reload signal.
Incoming byte rate
max_inflight_bytes count
Outgoing QoS 1 and 2 messages will be allowed in flight until this byte limit is reached. This allows control of outgoing message rate based on message size rather than message count. If the limit is set to 100, messages of over 100 bytes are still allowed, but only a single message can be in flight at once. Defaults to 0. (No limit).
See also the max_inflight_messages
option.
This option applies globally.
Reloaded on reload signal.
max_queued_bytes count
The number of outgoing QoS 1 and 2 messages above those currently in-flight will be queued (per client) by the broker. Once this limit has been reached, subsequent messages will be silently dropped. This is an important option if you are sending messages at a high rate and/or have clients who are slow to respond or may be offline for extended periods of time. Defaults to 0. (No maximum).
See also the max_queued_messages
option. If both max_queued_messages
and max_queued_bytes
are specified, packets will be queued until the first limit is reached.
This option applies globally.
Reloaded on reload signal.
max_queued_messages count
The maximum number of QoS 1 or 2 messages to hold in the queue (per client) above those messages that are currently in flight. Defaults to 1000. Set to 0 for no maximum (not recommended). See also the queue_qos0_messages
and max_queued_bytes
options.
This option applies globally.
Reloaded on reload signal.
Plugin
plugin_opt_* value
Options to be passed to the most recent plugin defined in the configuration file. See the specific plugin instructions for details of what options are available.
Applies to the current plugin being configured.
This is also available as the auth_opt_
* option, but this use is deprecated and will be removed in a future version.
plugin file path
Specify an external module to use for authentication and access control. This allows custom username/password and access control functions to be created.
Can be specified multiple times to load multiple plugins. The plugins will be processed in the order that they are specified.
If password_file
, or acl_file
are used in the config file alongsize plugin, the plugin checks will run after the built in checks.
Not currently reloaded on reload signal.
See also [Security] (NEW_security.md).
This is also available as the auth_plugin option, but this use is deprecated and will be removed in a future version.