1059 lines
47 KiB
Markdown
1059 lines
47 KiB
Markdown
# Clusters
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## Clusters Overview
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Apache ActiveMQ Artemis clusters allow groups of Apache ActiveMQ Artemis servers to be grouped
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together in order to share message processing load. Each active node in
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the cluster is an active Apache ActiveMQ Artemis server which manages its own messages
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and handles its own connections.
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The cluster is formed by each node declaring *cluster connections* to
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other nodes in the core configuration file `broker.xml`.
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When a node forms a cluster connection to another node, internally it
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creates a *core bridge* (as described in [Core Bridges](core-bridges.md)) connection between it and
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the other node, this is done transparently behind the scenes - you don't
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have to declare an explicit bridge for each node. These cluster
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connections allow messages to flow between the nodes of the cluster to
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balance load.
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Nodes can be connected together to form a cluster in many different
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topologies, we will discuss a couple of the more common topologies later
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in this chapter.
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We'll also discuss client side load balancing, where we can balance
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client connections across the nodes of the cluster, and we'll consider
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message redistribution where Apache ActiveMQ Artemis will redistribute messages between
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nodes to avoid starvation.
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Another important part of clustering is *server discovery* where servers
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can broadcast their connection details so clients or other servers can
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connect to them with the minimum of configuration.
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> **Warning**
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>
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> Once a cluster node has been configured it is common to simply copy
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> that configuration to other nodes to produce a symmetric cluster.
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> However, care must be taken when copying the Apache ActiveMQ Artemis files. Do not
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> copy the Apache ActiveMQ Artemis *data* (i.e. the `bindings`, `journal`, and
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> `large-messages` directories) from one node to another. When a node is
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> started for the first time and initializes its journal files it also
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> persists a special identifier to the `journal` directory. This id
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> *must* be unique among nodes in the cluster or the cluster will not
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> form properly.
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## Server discovery
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Server discovery is a mechanism by which servers can propagate their
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connection details to:
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- Messaging clients. A messaging client wants to be able to connect to
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the servers of the cluster without having specific knowledge of
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which servers in the cluster are up at any one time.
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- Other servers. Servers in a cluster want to be able to create
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cluster connections to each other without having prior knowledge of
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all the other servers in the cluster.
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This information, let's call it the Cluster Topology, is actually sent
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around normal Apache ActiveMQ Artemis connections to clients and to other servers over
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cluster connections. This being the case we need a way of establishing
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the initial first connection. This can be done using dynamic discovery
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techniques like
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[UDP](http://en.wikipedia.org/wiki/User_Datagram_Protocol) and
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[JGroups](http://www.jgroups.org/), or by providing a list of initial
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connectors.
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### Dynamic Discovery
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Server discovery uses
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[UDP](http://en.wikipedia.org/wiki/User_Datagram_Protocol) multicast or
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[JGroups](http://www.jgroups.org/) to broadcast server connection
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settings.
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#### Broadcast Groups
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A broadcast group is the means by which a server broadcasts connectors
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over the network. A connector defines a way in which a client (or other
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server) can make connections to the server. For more information on what
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a connector is, please see [Configuring the Transport](configuring-transports.md).
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The broadcast group takes a set of connector pairs, each connector pair
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contains connection settings for a live and backup server (if one
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exists) and broadcasts them on the network. Depending on which
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broadcasting technique you configure the cluster, it uses either UDP or
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JGroups to broadcast connector pairs information.
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Broadcast groups are defined in the server configuration file
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`broker.xml`. There can be many broadcast groups per
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Apache ActiveMQ Artemis server. All broadcast groups must be defined in a
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`broadcast-groups` element.
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Let's take a look at an example broadcast group from
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`broker.xml` that defines a UDP broadcast group:
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<broadcast-groups>
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<broadcast-group name="my-broadcast-group">
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<local-bind-address>172.16.9.3</local-bind-address>
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<local-bind-port>5432</local-bind-port>
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<group-address>231.7.7.7</group-address>
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<group-port>9876</group-port>
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<broadcast-period>2000</broadcast-period>
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<connector-ref connector-name="netty-connector"/>
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</broadcast-group>
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</broadcast-groups>
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Some of the broadcast group parameters are optional and you'll normally
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use the defaults, but we specify them all in the above example for
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clarity. Let's discuss each one in turn:
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- `name` attribute. Each broadcast group in the server must have a
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unique name.
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- `local-bind-address`. This is the local bind address that the
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datagram socket is bound to. If you have multiple network interfaces
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on your server, you would specify which one you wish to use for
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broadcasts by setting this property. If this property is not
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specified then the socket will be bound to the wildcard address, an
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IP address chosen by the kernel. This is a UDP specific attribute.
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- `local-bind-port`. If you want to specify a local port to which the
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datagram socket is bound you can specify it here. Normally you would
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just use the default value of `-1` which signifies that an anonymous
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port should be used. This parameter is always specified in
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conjunction with `local-bind-address`. This is a UDP specific
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attribute.
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- `group-address`. This is the multicast address to which the data
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will be broadcast. It is a class D IP address in the range
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`224.0.0.0` to `239.255.255.255`, inclusive. The address `224.0.0.0`
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is reserved and is not available for use. This parameter is
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mandatory. This is a UDP specific attribute.
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- `group-port`. This is the UDP port number used for broadcasting.
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This parameter is mandatory. This is a UDP specific attribute.
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- `broadcast-period`. This is the period in milliseconds between
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consecutive broadcasts. This parameter is optional, the default
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value is `2000` milliseconds.
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- `connector-ref`. This specifies the connector and optional backup
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connector that will be broadcasted (see [Configuring the Transport](configuring-transports.md) for more information on
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connectors). The connector to be broadcasted is specified by the
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`connector-name` attribute.
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Here is another example broadcast group that defines a JGroups broadcast
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group:
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<broadcast-groups>
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<broadcast-group name="my-broadcast-group">
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<jgroups-file>test-jgroups-file_ping.xml</jgroups-file>
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<jgroups-channel>activemq_broadcast_channel</jgroups-channel>
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<broadcast-period>2000</broadcast-period>
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<connector-ref connector-name="netty-connector"/>
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</broadcast-group>
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</broadcast-groups>
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To be able to use JGroups to broadcast, one must specify two attributes,
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i.e. `jgroups-file` and `jgroups-channel`, as discussed in details as
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following:
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- `jgroups-file` attribute. This is the name of JGroups configuration
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file. It will be used to initialize JGroups channels. Make sure the
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file is in the java resource path so that Apache ActiveMQ Artemis can load it.
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- `jgroups-channel` attribute. The name that JGroups channels connect
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to for broadcasting.
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> **Note**
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>
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> The JGroups attributes (`jgroups-file` and `jgroups-channel`) and UDP
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> specific attributes described above are exclusive of each other. Only
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> one set can be specified in a broadcast group configuration. Don't mix
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> them!
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The following is an example of a JGroups file
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<config xmlns="urn:org:jgroups"
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xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
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xsi:schemaLocation="urn:org:jgroups http://www.jgroups.org/schema/JGroups-3.0.xsd">
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<TCP loopback="true"
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recv_buf_size="20000000"
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send_buf_size="640000"
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discard_incompatible_packets="true"
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max_bundle_size="64000"
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max_bundle_timeout="30"
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enable_bundling="true"
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use_send_queues="false"
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sock_conn_timeout="300"
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thread_pool.enabled="true"
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thread_pool.min_threads="1"
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thread_pool.max_threads="10"
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thread_pool.keep_alive_time="5000"
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thread_pool.queue_enabled="false"
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thread_pool.queue_max_size="100"
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thread_pool.rejection_policy="run"
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oob_thread_pool.enabled="true"
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oob_thread_pool.min_threads="1"
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oob_thread_pool.max_threads="8"
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oob_thread_pool.keep_alive_time="5000"
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oob_thread_pool.queue_enabled="false"
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oob_thread_pool.queue_max_size="100"
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oob_thread_pool.rejection_policy="run"/>
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<FILE_PING location="../file.ping.dir"/>
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<MERGE2 max_interval="30000"
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min_interval="10000"/>
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<FD_SOCK/>
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<FD timeout="10000" max_tries="5" />
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<VERIFY_SUSPECT timeout="1500" />
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<BARRIER />
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<pbcast.NAKACK
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use_mcast_xmit="false"
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retransmit_timeout="300,600,1200,2400,4800"
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discard_delivered_msgs="true"/>
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<UNICAST timeout="300,600,1200" />
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<pbcast.STABLE stability_delay="1000" desired_avg_gossip="50000"
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max_bytes="400000"/>
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<pbcast.GMS print_local_addr="true" join_timeout="3000"
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view_bundling="true"/>
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<FC max_credits="2000000"
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min_threshold="0.10"/>
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<FRAG2 frag_size="60000" />
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<pbcast.STATE_TRANSFER/>
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<pbcast.FLUSH timeout="0"/>
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</config>
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As it shows, the file content defines a jgroups protocol stacks. If you
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want Apache ActiveMQ Artemis to use this stacks for channel creation, you have to make
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sure the value of `jgroups-file` in your broadcast-group/discovery-group
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configuration to be the name of this jgroups configuration file. For
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example if the above stacks configuration is stored in a file named
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"jgroups-stacks.xml" then your `jgroups-file` should be like
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<jgroups-file>jgroups-stacks.xml</jgroups-file>
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#### Discovery Groups
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While the broadcast group defines how connector information is
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broadcasted from a server, a discovery group defines how connector
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information is received from a broadcast endpoint (a UDP multicast
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address or JGroup channel).
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A discovery group maintains a list of connector pairs - one for each
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broadcast by a different server. As it receives broadcasts on the
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broadcast endpoint from a particular server it updates its entry in the
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list for that server.
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If it has not received a broadcast from a particular server for a length
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of time it will remove that server's entry from its list.
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Discovery groups are used in two places in Apache ActiveMQ Artemis:
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- By cluster connections so they know how to obtain an initial
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connection to download the topology
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- By messaging clients so they know how to obtain an initial
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connection to download the topology
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Although a discovery group will always accept broadcasts, its current
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list of available live and backup servers is only ever used when an
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initial connection is made, from then server discovery is done over the
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normal Apache ActiveMQ Artemis connections.
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> **Note**
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>
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> Each discovery group must be configured with broadcast endpoint (UDP
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> or JGroups) that matches its broadcast group counterpart. For example,
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> if broadcast is configured using UDP, the discovery group must also
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> use UDP, and the same multicast address.
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#### Defining Discovery Groups on the Server
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For cluster connections, discovery groups are defined in the server side
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configuration file `broker.xml`. All discovery groups
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must be defined inside a `discovery-groups` element. There can be many
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discovery groups defined by Apache ActiveMQ Artemis server. Let's look at an example:
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<discovery-groups>
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<discovery-group name="my-discovery-group">
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<local-bind-address>172.16.9.7</local-bind-address>
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<group-address>231.7.7.7</group-address>
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<group-port>9876</group-port>
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<refresh-timeout>10000</refresh-timeout>
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</discovery-group>
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</discovery-groups>
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We'll consider each parameter of the discovery group:
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- `name` attribute. Each discovery group must have a unique name per
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server.
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- `local-bind-address`. If you are running with multiple network
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interfaces on the same machine, you may want to specify that the
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discovery group listens only only a specific interface. To do this
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you can specify the interface address with this parameter. This
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parameter is optional. This is a UDP specific attribute.
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- `group-address`. This is the multicast IP address of the group to
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listen on. It should match the `group-address` in the broadcast
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group that you wish to listen from. This parameter is mandatory.
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This is a UDP specific attribute.
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- `group-port`. This is the UDP port of the multicast group. It should
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match the `group-port` in the broadcast group that you wish to
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listen from. This parameter is mandatory. This is a UDP specific
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attribute.
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- `refresh-timeout`. This is the period the discovery group waits
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after receiving the last broadcast from a particular server before
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removing that servers connector pair entry from its list. You would
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normally set this to a value significantly higher than the
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`broadcast-period` on the broadcast group otherwise servers might
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intermittently disappear from the list even though they are still
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broadcasting due to slight differences in timing. This parameter is
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optional, the default value is `10000` milliseconds (10 seconds).
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Here is another example that defines a JGroups discovery group:
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<discovery-groups>
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<discovery-group name="my-broadcast-group">
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<jgroups-file>test-jgroups-file_ping.xml</jgroups-file>
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<jgroups-channel>activemq_broadcast_channel</jgroups-channel>
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<refresh-timeout>10000</refresh-timeout>
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</discovery-group>
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</discovery-groups>
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To receive broadcast from JGroups channels, one must specify two
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attributes, `jgroups-file` and `jgroups-channel`, as discussed in
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details as following:
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- `jgroups-file` attribute. This is the name of JGroups configuration
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file. It will be used to initialize JGroups channels. Make sure the
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file is in the java resource path so that Apache ActiveMQ Artemis can load it.
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- `jgroups-channel` attribute. The name that JGroups channels connect
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to for receiving broadcasts.
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> **Note**
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>
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> The JGroups attributes (`jgroups-file` and `jgroups-channel`) and UDP
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> specific attributes described above are exclusive of each other. Only
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> one set can be specified in a discovery group configuration. Don't mix
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> them!
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#### Discovery Groups on the Client Side
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Let's discuss how to configure an Apache ActiveMQ Artemis client to use discovery to
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discover a list of servers to which it can connect. The way to do this
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differs depending on whether you're using JMS or the core API.
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##### Configuring client discovery using JMS
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If you're using JMS and you're using JNDI on the client to look up your
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JMS connection factory instances then you can specify these parameters
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in the JNDI context environment. e.g. in `jndi.properties`. Simply
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ensure the host:port combination matches the group-address and
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group-port from the corresponding `broadcast-group` on the server. Let's
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take a look at an example:
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java.naming.factory.initial = ActiveMQInitialContextFactory
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connectionFactory.myConnectionFactory=udp://231.7.7.7:9876
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The element `discovery-group-ref` specifies the name of a discovery
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group defined in `broker.xml`.
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When this connection factory is downloaded from JNDI by a client
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application and JMS connections are created from it, those connections
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will be load-balanced across the list of servers that the discovery
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group maintains by listening on the multicast address specified in the
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discovery group configuration.
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If you're using JMS, but you're not using JNDI to lookup a connection
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factory - you're instantiating the JMS connection factory directly then
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you can specify the discovery group parameters directly when creating
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the JMS connection factory. Here's an example:
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``` java
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final String groupAddress = "231.7.7.7";
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final int groupPort = 9876;
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ConnectionFactory jmsConnectionFactory =
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ActiveMQJMSClient.createConnectionFactory(new DiscoveryGroupConfiguration(groupAddress, groupPort,
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new UDPBroadcastGroupConfiguration(groupAddress, groupPort, null, -1)), JMSFactoryType.CF);
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Connection jmsConnection1 = jmsConnectionFactory.createConnection();
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Connection jmsConnection2 = jmsConnectionFactory.createConnection();
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```
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The `refresh-timeout` can be set directly on the
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DiscoveryGroupConfiguration by using the setter method
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`setDiscoveryRefreshTimeout()` if you want to change the default value.
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There is also a further parameter settable on the
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DiscoveryGroupConfiguration using the setter method
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`setDiscoveryInitialWaitTimeout()`. If the connection factory is used
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immediately after creation then it may not have had enough time to
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received broadcasts from all the nodes in the cluster. On first usage,
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the connection factory will make sure it waits this long since creation
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before creating the first connection. The default value for this
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parameter is `10000` milliseconds.
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##### Configuring client discovery using Core
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If you're using the core API to directly instantiate
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`ClientSessionFactory` instances, then you can specify the discovery
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group parameters directly when creating the session factory. Here's an
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example:
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``` java
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final String groupAddress = "231.7.7.7";
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final int groupPort = 9876;
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ServerLocator factory = ActiveMQClient.createServerLocatorWithHA(new DiscoveryGroupConfiguration(groupAddress, groupPort,
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new UDPBroadcastGroupConfiguration(groupAddress, groupPort, null, -1))));
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ClientSessionFactory factory = locator.createSessionFactory();
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ClientSession session1 = factory.createSession();
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ClientSession session2 = factory.createSession();
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```
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The `refresh-timeout` can be set directly on the
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DiscoveryGroupConfiguration by using the setter method
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`setDiscoveryRefreshTimeout()` if you want to change the default value.
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There is also a further parameter settable on the
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DiscoveryGroupConfiguration using the setter method
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`setDiscoveryInitialWaitTimeout()`. If the session factory is used
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immediately after creation then it may not have had enough time to
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received broadcasts from all the nodes in the cluster. On first usage,
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the session factory will make sure it waits this long since creation
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before creating the first session. The default value for this parameter
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is `10000` milliseconds.
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### Discovery using static Connectors
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Sometimes it may be impossible to use UDP on the network you are using.
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In this case its possible to configure a connection with an initial list
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if possible servers. This could be just one server that you know will
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always be available or a list of servers where at least one will be
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available.
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This doesn't mean that you have to know where all your servers are going
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to be hosted, you can configure these servers to use the reliable
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servers to connect to. Once they are connected there connection details
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will be propagated via the server it connects to
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#### Configuring a Cluster Connection
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For cluster connections there is no extra configuration needed, you just
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need to make sure that any connectors are defined in the usual manner,
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(see [Configuring the Transport](configuring-transports.md) for more information on connectors). These are then referenced by
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the cluster connection configuration.
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#### Configuring a Client Connection
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A static list of possible servers can also be used by a normal client.
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##### Configuring client discovery using JMS
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If you're using JMS and you're using JNDI on the client to look up your
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JMS connection factory instances then you can specify these parameters
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in the JNDI context environment in, e.g. `jndi.properties`:
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java.naming.factory.initial=org.apache.activemq.artemis.jndi.ActiveMQInitialContextFactory
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connectionFactory.myConnectionFactory=(tcp://myhost:61616,tcp://myhost2:61616)
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The `connectionFactory.myConnectionFactory` contains a list of servers to use for the
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connection factory. When this connection factory used client application
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and JMS connections are created from it, those connections will be
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load-balanced across the list of servers defined within the brackets `()`.
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The brackets are expanded so the same query cab be appended after the last bracket for ease.
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If you're using JMS, but you're not using JNDI to lookup a connection
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factory - you're instantiating the JMS connection factory directly then
|
|
you can specify the connector list directly when creating the JMS
|
|
connection factory. Here's an example:
|
|
|
|
``` java
|
|
HashMap<String, Object> map = new HashMap<String, Object>();
|
|
map.put("host", "myhost");
|
|
map.put("port", "61616");
|
|
TransportConfiguration server1 = new TransportConfiguration(NettyConnectorFactory.class.getName(), map);
|
|
HashMap<String, Object> map2 = new HashMap<String, Object>();
|
|
map2.put("host", "myhost2");
|
|
map2.put("port", "61617");
|
|
TransportConfiguration server2 = new TransportConfiguration(NettyConnectorFactory.class.getName(), map2);
|
|
|
|
ActiveMQConnectionFactory cf = ActiveMQJMSClient.createConnectionFactoryWithHA(JMSFactoryType.CF, server1, server2);
|
|
```
|
|
|
|
##### Configuring client discovery using Core
|
|
|
|
If you are using the core API then the same can be done as follows:
|
|
|
|
``` java
|
|
HashMap<String, Object> map = new HashMap<String, Object>();
|
|
map.put("host", "myhost");
|
|
map.put("port", "61616");
|
|
TransportConfiguration server1 = new TransportConfiguration(NettyConnectorFactory.class.getName(), map);
|
|
HashMap<String, Object> map2 = new HashMap<String, Object>();
|
|
map2.put("host", "myhost2");
|
|
map2.put("port", "61617");
|
|
TransportConfiguration server2 = new TransportConfiguration(NettyConnectorFactory.class.getName(), map2);
|
|
|
|
ServerLocator locator = ActiveMQClient.createServerLocatorWithHA(server1, server2);
|
|
ClientSessionFactory factory = locator.createSessionFactory();
|
|
ClientSession session = factory.createSession();
|
|
```
|
|
|
|
## Server-Side Message Load Balancing
|
|
|
|
If cluster connections are defined between nodes of a cluster, then
|
|
Apache ActiveMQ Artemis will load balance messages arriving at a particular node from a
|
|
client.
|
|
|
|
Let's take a simple example of a cluster of four nodes A, B, C, and D
|
|
arranged in a *symmetric cluster* (described in Symmetrical Clusters section). We have a queue
|
|
called `OrderQueue` deployed on each node of the cluster.
|
|
|
|
We have client Ca connected to node A, sending orders to the server. We
|
|
have also have order processor clients Pa, Pb, Pc, and Pd connected to
|
|
each of the nodes A, B, C, D. If no cluster connection was defined on
|
|
node A, then as order messages arrive on node A they will all end up in
|
|
the `OrderQueue` on node A, so will only get consumed by the order
|
|
processor client attached to node A, Pa.
|
|
|
|
If we define a cluster connection on node A, then as ordered messages
|
|
arrive on node A instead of all of them going into the local
|
|
`OrderQueue` instance, they are distributed in a round-robin fashion
|
|
between all the nodes of the cluster. The messages are forwarded from
|
|
the receiving node to other nodes of the cluster. This is all done on
|
|
the server side, the client maintains a single connection to node A.
|
|
|
|
For example, messages arriving on node A might be distributed in the
|
|
following order between the nodes: B, D, C, A, B, D, C, A, B, D. The
|
|
exact order depends on the order the nodes started up, but the algorithm
|
|
used is round robin.
|
|
|
|
Apache ActiveMQ Artemis cluster connections can be configured to always blindly load
|
|
balance messages in a round robin fashion irrespective of whether there
|
|
are any matching consumers on other nodes, but they can be a bit
|
|
cleverer than that and also be configured to only distribute to other
|
|
nodes if they have matching consumers. We'll look at both these cases in
|
|
turn with some examples, but first we'll discuss configuring cluster
|
|
connections in general.
|
|
|
|
### Configuring Cluster Connections
|
|
|
|
Cluster connections group servers into clusters so that messages can be
|
|
load balanced between the nodes of the cluster. Let's take a look at a
|
|
typical cluster connection. Cluster connections are always defined in
|
|
`broker.xml` inside a `cluster-connection` element.
|
|
There can be zero or more cluster connections defined per Apache ActiveMQ Artemis
|
|
server.
|
|
|
|
<cluster-connections>
|
|
<cluster-connection name="my-cluster">
|
|
<address>jms</address>
|
|
<connector-ref>netty-connector</connector-ref>
|
|
<check-period>1000</check-period>
|
|
<connection-ttl>5000</connection-ttl>
|
|
<min-large-message-size>50000</min-large-message-size>
|
|
<call-timeout>5000</call-timeout>
|
|
<retry-interval>500</retry-interval>
|
|
<retry-interval-multiplier>1.0</retry-interval-multiplier>
|
|
<max-retry-interval>5000</max-retry-interval>
|
|
<initial-connect-attempts>-1</initial-connect-attempts>
|
|
<reconnect-attempts>-1</reconnect-attempts>
|
|
<use-duplicate-detection>true</use-duplicate-detection>
|
|
<message-load-balancing>ON_DEMAND</message-load-balancing>
|
|
<max-hops>1</max-hops>
|
|
<confirmation-window-size>32000</confirmation-window-size>
|
|
<call-failover-timeout>30000</call-failover-timeout>
|
|
<notification-interval>1000</notification-interval>
|
|
<notification-attempts>2</notification-attempts>
|
|
<discovery-group-ref discovery-group-name="my-discovery-group"/>
|
|
</cluster-connection>
|
|
</cluster-connections>
|
|
|
|
In the above cluster connection all parameters have been explicitly
|
|
specified. The following shows all the available configuration options
|
|
|
|
- `address` Each cluster connection only applies to addresses that
|
|
match the specified address field. An address is matched on the
|
|
cluster connection when it begins with the string specified in this
|
|
field. The address field on a cluster connection also supports comma
|
|
separated lists and an exclude syntax '!'. To prevent an address
|
|
from being matched on this cluster connection, prepend a cluster
|
|
connection address string with '!'.
|
|
|
|
In the case shown above the cluster connection will load balance
|
|
messages sent to addresses that start with `jms`. This cluster
|
|
connection, will, in effect apply to all JMS queues and topics since
|
|
they map to core queues that start with the substring "jms".
|
|
|
|
The address can be any value and you can have many cluster
|
|
connections with different values of `address`, simultaneously
|
|
balancing messages for those addresses, potentially to different
|
|
clusters of servers. By having multiple cluster connections on
|
|
different addresses a single Apache ActiveMQ Artemis Server can effectively take
|
|
part in multiple clusters simultaneously.
|
|
|
|
Be careful not to have multiple cluster connections with overlapping
|
|
values of `address`, e.g. "europe" and "europe.news" since this
|
|
could result in the same messages being distributed between more
|
|
than one cluster connection, possibly resulting in duplicate
|
|
deliveries.
|
|
|
|
Examples:
|
|
|
|
- 'jms.eu'
|
|
matches all addresses starting with 'jms.eu'
|
|
- '!jms.eu'
|
|
matches all address except for those starting with 'jms.eu'
|
|
- 'jms.eu.uk,jms.eu.de'
|
|
matches all addresses starting with either 'jms.eu.uk' or
|
|
'jms.eu.de'
|
|
- 'jms.eu,!jms.eu.uk'
|
|
matches all addresses starting with 'jms.eu' but not those
|
|
starting with 'jms.eu.uk'
|
|
|
|
Notes:
|
|
|
|
- Address exclusion will always takes precedence over address
|
|
inclusion.
|
|
- Address matching on cluster connections does not support
|
|
wild-card matching.
|
|
|
|
This parameter is mandatory.
|
|
|
|
- `connector-ref`. This is the connector which will be sent to other
|
|
nodes in the cluster so they have the correct cluster topology.
|
|
|
|
This parameter is mandatory.
|
|
|
|
- `check-period`. The period (in milliseconds) used to check if the
|
|
cluster connection has failed to receive pings from another server.
|
|
Default is 30000.
|
|
|
|
- `connection-ttl`. This is how long a cluster connection should stay
|
|
alive if it stops receiving messages from a specific node in the
|
|
cluster. Default is 60000.
|
|
|
|
- `min-large-message-size`. If the message size (in bytes) is larger
|
|
than this value then it will be split into multiple segments when
|
|
sent over the network to other cluster members. Default is 102400.
|
|
|
|
- `call-timeout`. When a packet is sent via a cluster connection and
|
|
is a blocking call, i.e. for acknowledgements, this is how long it
|
|
will wait (in milliseconds) for the reply before throwing an
|
|
exception. Default is 30000.
|
|
|
|
- `retry-interval`. We mentioned before that, internally, cluster
|
|
connections cause bridges to be created between the nodes of the
|
|
cluster. If the cluster connection is created and the target node
|
|
has not been started, or say, is being rebooted, then the cluster
|
|
connections from other nodes will retry connecting to the target
|
|
until it comes back up, in the same way as a bridge does.
|
|
|
|
This parameter determines the interval in milliseconds between retry
|
|
attempts. It has the same meaning as the `retry-interval` on a
|
|
bridge (as described in [Core Bridges](core-bridges.md)).
|
|
|
|
This parameter is optional and its default value is `500`
|
|
milliseconds.
|
|
|
|
- `retry-interval-multiplier`. This is a multiplier used to increase
|
|
the `retry-interval` after each reconnect attempt, default is 1.
|
|
|
|
- `max-retry-interval`. The maximum delay (in milliseconds) for
|
|
retries. Default is 2000.
|
|
|
|
- `initial-connect-attempts`. The number of times the system will try
|
|
to connect a node in the cluster initially. If the max-retry is
|
|
achieved this node will be considered permanently down and the
|
|
system will not route messages to this node. Default is -1 (infinite
|
|
retries).
|
|
|
|
- `reconnect-attempts`. The number of times the system will try to
|
|
reconnect to a node in the cluster. If the max-retry is achieved
|
|
this node will be considered permanently down and the system will
|
|
stop routing messages to this node. Default is -1 (infinite
|
|
retries).
|
|
|
|
- `use-duplicate-detection`. Internally cluster connections use
|
|
bridges to link the nodes, and bridges can be configured to add a
|
|
duplicate id property in each message that is forwarded. If the
|
|
target node of the bridge crashes and then recovers, messages might
|
|
be resent from the source node. By enabling duplicate detection any
|
|
duplicate messages will be filtered out and ignored on receipt at
|
|
the target node.
|
|
|
|
This parameter has the same meaning as `use-duplicate-detection` on
|
|
a bridge. For more information on duplicate detection, please see [Duplicate Detection](duplicate-detection.md).
|
|
Default is true.
|
|
|
|
- `message-load-balancing`. This parameter determines if/how
|
|
messages will be distributed between other nodes of the cluster.
|
|
It can be one of three values - `OFF`, `STRICT`, or `ON_DEMAND`
|
|
(default). This parameter replaces the deprecated
|
|
`forward-when-no-consumers` parameter.
|
|
|
|
If this is set to `OFF` then messages will never be forwarded to
|
|
another node in the cluster
|
|
|
|
If this is set to `STRICT` then each incoming message will be round
|
|
robin'd even though the same queues on the other nodes of the
|
|
cluster may have no consumers at all, or they may have consumers
|
|
that have non matching message filters (selectors). Note that
|
|
Apache ActiveMQ Artemis will *not* forward messages to other nodes
|
|
if there are no *queues* of the same name on the other nodes, even
|
|
if this parameter is set to `STRICT`. Using `STRICT` is like setting
|
|
the legacy `forward-when-no-consumers` parameter to `true`.
|
|
|
|
If this is set to `ON_DEMAND` then Apache ActiveMQ Artemis will only
|
|
forward messages to other nodes of the cluster if the address to which
|
|
they are being forwarded has queues which have consumers, and if those
|
|
consumers have message filters (selectors) at least one of those
|
|
selectors must match the message. Using `ON_DEMAND` is like setting
|
|
the legacy `forward-when-no-consumers` parameter to `false`.
|
|
|
|
Default is `ON_DEMAND`.
|
|
|
|
- `max-hops`. When a cluster connection decides the set of nodes to
|
|
which it might load balance a message, those nodes do not have to be
|
|
directly connected to it via a cluster connection. Apache ActiveMQ Artemis can be
|
|
configured to also load balance messages to nodes which might be
|
|
connected to it only indirectly with other Apache ActiveMQ Artemis servers as
|
|
intermediates in a chain.
|
|
|
|
This allows Apache ActiveMQ Artemis to be configured in more complex topologies and
|
|
still provide message load balancing. We'll discuss this more later
|
|
in this chapter.
|
|
|
|
The default value for this parameter is `1`, which means messages
|
|
are only load balanced to other Apache ActiveMQ Artemis serves which are directly
|
|
connected to this server. This parameter is optional.
|
|
|
|
- `confirmation-window-size`. The size (in bytes) of the window used
|
|
for sending confirmations from the server connected to. So once the
|
|
server has received `confirmation-window-size` bytes it notifies its
|
|
client, default is 1048576. A value of -1 means no window.
|
|
|
|
- `producer-window-size`. The size for producer flow control over cluster connection.
|
|
it's by default disabled through the cluster connection bridge but you may want
|
|
to set a value if you are using really large messages in cluster. A value of -1 means no window.
|
|
|
|
- `call-failover-timeout`. Similar to `call-timeout` but used when a
|
|
call is made during a failover attempt. Default is -1 (no timeout).
|
|
|
|
- `notification-interval`. How often (in milliseconds) the cluster
|
|
connection should broadcast itself when attaching to the cluster.
|
|
Default is 1000.
|
|
|
|
- `notification-attempts`. How many times the cluster connection
|
|
should broadcast itself when connecting to the cluster. Default is
|
|
2.
|
|
|
|
- `discovery-group-ref`. This parameter determines which discovery
|
|
group is used to obtain the list of other servers in the cluster
|
|
that this cluster connection will make connections to.
|
|
|
|
Alternatively if you would like your cluster connections to use a static
|
|
list of servers for discovery then you can do it like this.
|
|
|
|
<cluster-connection name="my-cluster">
|
|
...
|
|
<static-connectors>
|
|
<connector-ref>server0-connector</connector-ref>
|
|
<connector-ref>server1-connector</connector-ref>
|
|
</static-connectors>
|
|
</cluster-connection>
|
|
|
|
Here we have defined 2 servers that we know for sure will that at least
|
|
one will be available. There may be many more servers in the cluster but
|
|
these will; be discovered via one of these connectors once an initial
|
|
connection has been made.
|
|
|
|
### Cluster User Credentials
|
|
|
|
When creating connections between nodes of a cluster to form a cluster
|
|
connection, Apache ActiveMQ Artemis uses a cluster user and cluster password which is
|
|
defined in `broker.xml`:
|
|
|
|
<cluster-user>ACTIVEMQ.CLUSTER.ADMIN.USER</cluster-user>
|
|
<cluster-password>CHANGE ME!!</cluster-password>
|
|
|
|
> **Warning**
|
|
>
|
|
> It is imperative that these values are changed from their default, or
|
|
> remote clients will be able to make connections to the server using
|
|
> the default values. If they are not changed from the default, Apache ActiveMQ Artemis
|
|
> will detect this and pester you with a warning on every start-up.
|
|
|
|
## Client-Side Load balancing
|
|
|
|
With Apache ActiveMQ Artemis client-side load balancing, subsequent sessions created
|
|
using a single session factory can be connected to different nodes of
|
|
the cluster. This allows sessions to spread smoothly across the nodes of
|
|
a cluster and not be "clumped" on any particular node.
|
|
|
|
The load balancing policy to be used by the client factory is
|
|
configurable. Apache ActiveMQ Artemis provides four out-of-the-box load balancing
|
|
policies, and you can also implement your own and use that.
|
|
|
|
The out-of-the-box policies are
|
|
|
|
- Round Robin. With this policy the first node is chosen randomly then
|
|
each subsequent node is chosen sequentially in the same order.
|
|
|
|
For example nodes might be chosen in the order B, C, D, A, B, C, D,
|
|
A, B or D, A, B, C, D, A, B, C, D or C, D, A, B, C, D, A, B, C.
|
|
|
|
Use
|
|
`org.apache.activemq.artemis.api.core.client.loadbalance.RoundRobinConnectionLoadBalancingPolicy`
|
|
as the `<connection-load-balancing-policy-class-name>`.
|
|
|
|
- Random. With this policy each node is chosen randomly.
|
|
|
|
Use
|
|
`org.apache.activemq.artemis.api.core.client.loadbalance.RandomConnectionLoadBalancingPolicy`
|
|
as the `<connection-load-balancing-policy-class-name>`.
|
|
|
|
- Random Sticky. With this policy the first node is chosen randomly
|
|
and then re-used for subsequent connections.
|
|
|
|
Use
|
|
`org.apache.activemq.artemis.api.core.client.loadbalance.RandomStickyConnectionLoadBalancingPolicy`
|
|
as the `<connection-load-balancing-policy-class-name>`.
|
|
|
|
- First Element. With this policy the "first" (i.e. 0th) node is
|
|
always returned.
|
|
|
|
Use
|
|
`org.apache.activemq.artemis.api.core.client.loadbalance.FirstElementConnectionLoadBalancingPolicy`
|
|
as the `<connection-load-balancing-policy-class-name>`.
|
|
|
|
You can also implement your own policy by implementing the interface
|
|
`org.apache.activemq.artemis.api.core.client.loadbalance.ConnectionLoadBalancingPolicy`
|
|
|
|
Specifying which load balancing policy to use differs whether you are
|
|
using JMS or the core API. If you don't specify a policy then the
|
|
default will be used which is
|
|
`org.apache.activemq.artemis.api.core.client.loadbalance.RoundRobinConnectionLoadBalancingPolicy`.
|
|
|
|
If you're using JMS and you're using JNDI on the client to look up your
|
|
JMS connection factory instances then you can specify these parameters
|
|
in the JNDI context environment in, e.g. `jndi.properties`, to specify
|
|
the load balancing policy directly:
|
|
|
|
java.naming.factory.initial=org.apache.activemq.artemis.jndi.ActiveMQInitialContextFactory
|
|
connection.myConnectionFactory=tcp://localhost:61616?loadBalancingPolicyClassName=org.apache.activemq.artemis.api.core.client.loadbalance.RandomConnectionLoadBalancingPolicy
|
|
|
|
The above example would instantiate a JMS connection factory that uses
|
|
the random connection load balancing policy.
|
|
|
|
If you're using JMS but you're instantiating your connection factory
|
|
directly on the client side then you can set the load balancing policy
|
|
using the setter on the `ActiveMQConnectionFactory` before using it:
|
|
|
|
``` java
|
|
ConnectionFactory jmsConnectionFactory = ActiveMQJMSClient.createConnectionFactory(...);
|
|
jmsConnectionFactory.setLoadBalancingPolicyClassName("com.acme.MyLoadBalancingPolicy");
|
|
```
|
|
|
|
If you're using the core API, you can set the load balancing policy
|
|
directly on the `ServerLocator` instance you are using:
|
|
|
|
``` java
|
|
ServerLocator locator = ActiveMQClient.createServerLocatorWithHA(server1, server2);
|
|
locator.setLoadBalancingPolicyClassName("com.acme.MyLoadBalancingPolicy");
|
|
```
|
|
|
|
The set of servers over which the factory load balances can be
|
|
determined in one of two ways:
|
|
|
|
- Specifying servers explicitly
|
|
|
|
- Using discovery.
|
|
|
|
## Specifying Members of a Cluster Explicitly
|
|
|
|
Sometimes you want to explicitly define a cluster more explicitly, that
|
|
is control which server connect to each other in the cluster. This is
|
|
typically used to form non symmetrical clusters such as chain cluster or
|
|
ring clusters. This can only be done using a static list of connectors
|
|
and is configured as follows:
|
|
|
|
<cluster-connection name="my-cluster">
|
|
<address>jms</address>
|
|
<connector-ref>netty-connector</connector-ref>
|
|
<retry-interval>500</retry-interval>
|
|
<use-duplicate-detection>true</use-duplicate-detection>
|
|
<message-load-balancing>STRICT</message-load-balancing>
|
|
<max-hops>1</max-hops>
|
|
<static-connectors allow-direct-connections-only="true">
|
|
<connector-ref>server1-connector</connector-ref>
|
|
</static-connectors>
|
|
</cluster-connection>
|
|
|
|
In this example we have set the attribute
|
|
`allow-direct-connections-only` which means that the only server that
|
|
this server can create a cluster connection to is server1-connector.
|
|
This means you can explicitly create any cluster topology you want.
|
|
|
|
## Message Redistribution
|
|
|
|
Another important part of clustering is message redistribution. Earlier
|
|
we learned how server side message load balancing round robins messages
|
|
across the cluster. If `message-load-balancing` is `OFF` or `ON_DEMAND`
|
|
then messages won't be forwarded to nodes which don't have matching
|
|
consumers. This is great and ensures that messages aren't moved to a
|
|
queue which has no consumers to consume them. However, there is a
|
|
situation it doesn't solve: What happens if the consumers on a queue
|
|
close after the messages have been sent to the node? If there are no
|
|
consumers on the queue the message won't get consumed and we have a
|
|
*starvation* situation.
|
|
|
|
This is where message redistribution comes in. With message
|
|
redistribution Apache ActiveMQ Artemis can be configured to automatically
|
|
*redistribute* messages from queues which have no consumers back to
|
|
other nodes in the cluster which do have matching consumers. To enable
|
|
this functionality `message-load-balancing` must be `ON_DEMAND`.
|
|
|
|
Message redistribution can be configured to kick in immediately after
|
|
the last consumer on a queue is closed, or to wait a configurable delay
|
|
after the last consumer on a queue is closed before redistributing. By
|
|
default message redistribution is disabled.
|
|
|
|
Message redistribution can be configured on a per address basis, by
|
|
specifying the redistribution delay in the address settings, for more
|
|
information on configuring address settings, please see [Queue Attributes](queue-attributes.md).
|
|
|
|
Here's an address settings snippet from `broker.xml`
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|
showing how message redistribution is enabled for a set of queues:
|
|
|
|
<address-settings>
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|
<address-setting match="jms.#">
|
|
<redistribution-delay>0</redistribution-delay>
|
|
</address-setting>
|
|
</address-settings>
|
|
|
|
The above `address-settings` block would set a `redistribution-delay` of
|
|
`0` for any queue which is bound to an address that starts with "jms.".
|
|
All JMS queues and topic subscriptions are bound to addresses that start
|
|
with "jms.", so the above would enable instant (no delay) redistribution
|
|
for all JMS queues and topic subscriptions.
|
|
|
|
The attribute `match` can be an exact match or it can be a string that
|
|
conforms to the Apache ActiveMQ Artemis wildcard syntax (described in [Wildcard Syntax](wildcard-syntax.md)).
|
|
|
|
The element `redistribution-delay` defines the delay in milliseconds
|
|
after the last consumer is closed on a queue before redistributing
|
|
messages from that queue to other nodes of the cluster which do have
|
|
matching consumers. A delay of zero means the messages will be
|
|
immediately redistributed. A value of `-1` signifies that messages will
|
|
never be redistributed. The default value is `-1`.
|
|
|
|
It often makes sense to introduce a delay before redistributing as it's
|
|
a common case that a consumer closes but another one quickly is created
|
|
on the same queue, in such a case you probably don't want to
|
|
redistribute immediately since the new consumer will arrive shortly.
|
|
|
|
## Cluster topologies
|
|
|
|
Apache ActiveMQ Artemis clusters can be connected together in many different
|
|
topologies, let's consider the two most common ones here
|
|
|
|
### Symmetric cluster
|
|
|
|
A symmetric cluster is probably the most common cluster topology.
|
|
|
|
With a symmetric cluster every node in the cluster is connected to every
|
|
other node in the cluster. In other words every node in the cluster is
|
|
no more than one hop away from every other node.
|
|
|
|
To form a symmetric cluster every node in the cluster defines a cluster
|
|
connection with the attribute `max-hops` set to `1`. Typically the
|
|
cluster connection will use server discovery in order to know what other
|
|
servers in the cluster it should connect to, although it is possible to
|
|
explicitly define each target server too in the cluster connection if,
|
|
for example, UDP is not available on your network.
|
|
|
|
With a symmetric cluster each node knows about all the queues that exist
|
|
on all the other nodes and what consumers they have. With this knowledge
|
|
it can determine how to load balance and redistribute messages around
|
|
the nodes.
|
|
|
|
Don't forget [this warning](#copy-warning) when creating a symmetric
|
|
cluster.
|
|
|
|
### Chain cluster
|
|
|
|
With a chain cluster, each node in the cluster is not connected to every
|
|
node in the cluster directly, instead the nodes form a chain with a node
|
|
on each end of the chain and all other nodes just connecting to the
|
|
previous and next nodes in the chain.
|
|
|
|
An example of this would be a three node chain consisting of nodes A, B
|
|
and C. Node A is hosted in one network and has many producer clients
|
|
connected to it sending order messages. Due to corporate policy, the
|
|
order consumer clients need to be hosted in a different network, and
|
|
that network is only accessible via a third network. In this setup node
|
|
B acts as a mediator with no producers or consumers on it. Any messages
|
|
arriving on node A will be forwarded to node B, which will in turn
|
|
forward them to node C where they can get consumed. Node A does not need
|
|
to directly connect to C, but all the nodes can still act as a part of
|
|
the cluster.
|
|
|
|
To set up a cluster in this way, node A would define a cluster
|
|
connection that connects to node B, and node B would define a cluster
|
|
connection that connects to node C. In this case we only want cluster
|
|
connections in one direction since we're only moving messages from node
|
|
A-\>B-\>C and never from C-\>B-\>A.
|
|
|
|
For this topology we would set `max-hops` to `2`. With a value of `2`
|
|
the knowledge of what queues and consumers that exist on node C would be
|
|
propagated from node C to node B to node A. Node A would then know to
|
|
distribute messages to node B when they arrive, even though node B has
|
|
no consumers itself, it would know that a further hop away is node C
|
|
which does have consumers.
|
|
|
|
### Scaling Down
|
|
|
|
Apache ActiveMQ Artemis supports scaling down a cluster with no message loss (even for
|
|
non-durable messages). This is especially useful in certain environments
|
|
(e.g. the cloud) where the size of a cluster may change relatively
|
|
frequently. When scaling up a cluster (i.e. adding nodes) there is no
|
|
risk of message loss, but when scaling down a cluster (i.e. removing
|
|
nodes) the messages on those nodes would be lost unless the broker sent
|
|
them to another node in the cluster. Apache ActiveMQ Artemis can be configured to do
|
|
just that.
|
|
|
|
The simplest way to enable this behavior is to set `scale-down` to
|
|
`true`. If the server is clustered and `scale-down` is `true` then when
|
|
the server is shutdown gracefully (i.e. stopped without crashing) it
|
|
will find another node in the cluster and send *all* of its messages
|
|
(both durable and non-durable) to that node. The messages are processed
|
|
in order and go to the *back* of the respective queues on the other node
|
|
(just as if the messages were sent from an external client for the first
|
|
time).
|
|
|
|
If more control over where the messages go is required then specify
|
|
`scale-down-group-name`. Messages will only be sent to another node in
|
|
the cluster that uses the same `scale-down-group-name` as the server
|
|
being shutdown.
|
|
|
|
> **Warning**
|
|
>
|
|
> If cluster nodes are grouped together with different
|
|
> `scale-down-group-name` values beware. If all the nodes in a single
|
|
> group are shut down then the messages from that node/group will be
|
|
> lost.
|
|
|
|
If the server is using multiple `cluster-connection` then use
|
|
`scale-down-clustername` to identify the name of the
|
|
`cluster-connection` which should be used for scaling down.
|