Address federation is like full multicast over the connected brokers, in that every message sent to address on Broker-A will be delivered to every queue on that broker, but like wise will be delivered to Broker-B and all attached queues there.

Address federation dynamically links to other addresses in upstream or downstream brokers. It automatically creates a queue on the remote address for itself, to which then it consumes, copying to the local address, as though they were published directly to it.

The upstream brokers do not need to be reconfigured or the address, simply permissions to the address need to be given to the address for the downstream broker. Similarly the same applies for downstream configurations.

federation address

Figure 1. Address Federation

1. Topology Patterns

1.1. Symmetric

federation address symetric

Figure 2. Address Federation - Symmetric

As seen above, a publisher and consumer are connected to each broker. Queues and thus consumers on those queues, can receive messages published by either publisher.

It is important in this setup to set max-hops=1 to so that messages are copied only one and avoid cyclic replication. If max-hops is not configured correctly, consumers will get multiple copies of the same message.

1.2. Full Mesh

federation address complete graph

Figure 3. Address Federation - Full Mesh

If not already spotted, the setup is identical to symmetric but simply where all brokers are symmetrically federating each other, creating a full mesh.

As illustrated, a publisher and consumer are connected to each broker. Queues and thus consumers on those queues, can receive messages published by either publisher.

As with symmetric setup, it is important in this setup to set max-hops=1 to so that messages are copied only one and avoid cyclic replication. If max-hops is not configured correctly, consumers will get multiple copies of the same message.

1.3. Ring

federation address ring

Figure 4. Address Federation - Ring

In a ring of brokers each federated address is upstream to just one other in the ring. To avoid the cyclic issue, it is important to set max-hops to n - 1 where n is the number of nodes in the ring. e.g. in the example above property is set to 5 so that every address in the ring sees the message exactly once.

Whilst this setup is cheap in regards to connections, it is brittle, in that if a single broker fails, the ring fails.

1.4. Fan out

federation address fan out

Figure 5. Address Federation - Fan Out

One main address (it would required no configuration) is linked to by a tree of downstream federated addresses, the tree can extend to any depth, and can be extended to without needing to re-configure existing brokers.

In this case messages published to the main address can be received by any consumer connected to any broker in the tree.

1.5. Divert Binding Support

Divert binding support can be added as part of the address policy configuration. This will allow the federation to respond to divert bindings to create demand. For example, let’s say there is one address called “test.federation.source” that is included as a match for the federated address and another address called “test.federation.target” that is not included. Normally when a queue is created on “test.federation.target” this would not cause a federated consumer to be created because the address is not part of the included matches. However, if we create a divert binding such that “test.federation.source” is the source address and “test.federation.target” is the forwarded address then demand will now be created. The source address still must be multicast but the target address can be multicast or anycast.

An example use case for this might be a divert that redirects JMS topics (multicast addresses) to a JMS queue (anycast addresses) to allow for load balancing of the messages on a topic for legacy consumers not supporting JMS 2.0 and shared subscriptions.

2. Configuring Address Federation

Federation is configured in broker.xml.

Sample Address Federation setup:

  1. <federations>
  2. <federation name="eu-north-1" user="federation_username" password="32a10275cf4ab4e9">
  3. <upstream name="eu-east-1">
  4. <static-connectors>
  5. <connector-ref>eu-east-connector1</connector-ref>
  6. <connector-ref>eu-east-connector1</connector-ref>
  7. </static-connectors>
  8. <policy ref="news-address-federation"/>
  9. </upstream>
  10. <upstream name="eu-west-1" >
  11. <static-connectors>
  12. <connector-ref>eu-west-connector1</connector-ref>
  13. <connector-ref>eu-west-connector1</connector-ref>
  14. </static-connectors>
  15. <policy ref="news-address-federation"/>
  16. </upstream>
  17. <address-policy name="news-address-federation" max-hops="1" auto-delete="true" auto-delete-delay="300000" auto-delete-message-count="-1" transformer-ref="federation-transformer-3">
  18. <include address-match="queue.bbc.new" />
  19. <include address-match="queue.usatoday" />
  20. <include address-match="queue.news.#" />
  21. <exclude address-match="queue.news.sport.#" />
  22. </address-policy>
  23. <transformer name="news-transformer">
  24. <class-name>org.foo.NewsTransformer</class-name>
  25. <property key="key1" value="value1"/>
  26. <property key="key2" value="value2"/>
  27. </transformer>
  28. </federation>
  29. </federations>

In the above setup downstream broker eu-north-1 is configured to connect to two upstream brokers eu-east-1 and eu-east-2, the credentials used for both connections to both brokers in this sample are shared, you can set user and password at the upstream level should they be different per upstream.

Both upstreams are configured with the same address-policy news-address-federation, that is selecting addresses which match any of the include criteria, but will exclude anything that starts queue.news.sport.

It is important that federation name is globally unique.

Let’s take a look at all the address-policy parameters in turn, in order of priority.

name

All address-policies must have a unique name in the server.

include

The address-match pattern to include addresses. Multiple of these can be set. If none are set all addresses are matched.

exclude

The address-match pattern to exclude addresses. Multiple of these can be set.

max-hops

The number of hops that a message can have made for it to be federated, see Topology Patterns above for more details.

auto-delete

For address federation, the downstream dynamically creates a durable queue on the upstream address. This is used to mark if the upstream queue should be deleted once downstream disconnects, and the delay and message count params have been met. This is useful if you want to automate the clean up, though you may wish to disable this if you want messages to queued for the downstream when disconnect no matter what.

auto-delete-delay

The amount of time in milliseconds after the downstream broker has disconnected before the upstream queue can be eligable for auto-delete.

auto-delete-message-count

The amount number messages in the upstream queue that the message count must be equal or below before the downstream broker has disconnected before the upstream queue can be eligable for auto-delete.

transformer-ref

The ref name for a transformer (see transformer config) that you may wish to configure to transform the message on federation transfer.

enable-divert-bindings

Setting to true will enable divert bindings to be listened for demand. If there is a divert binding with an address that matches the included addresses for the stream, any queue bindings that match the forward address of the divert will create demand. Default is false.

address-policy and queue-policy elements can be defined in the same federation and be linked to the same upstream.

Now look at all the transformer parameters in turn, in order of priority:

name

This must be a unique name in the server, and is used to ref the transformer in address-policy and queue-policy

transformer-class-name

An optional transformer-class-name can be specified. This is the name of a user-defined class which implements the org.apache.activemq.artemis.core.server.transformer.Transformer interface.

If this is specified then the transformer’s transform() method will be invoked with the message before it is transferred. This gives you the opportunity to transform the message’s header or body before it is federated.

  • property holds key, value pairs that can be used to configure the transformer.

    Finally look at upstream, this is what defines the upstream broker connection and the policies to use against it.

  • name attribute. This must be a unique name in the server, and is used to ref the transformer in address-policy and queue-policy

user

This optional attribute determines the user name to use when creating the upstream connection to the remote server. If it is not specified the shared federation user and password will be used if set.

password

This optional attribute determines the password to use when creating the upstream connection to the remote server. If it is not specified the shared federation user and password will be used if set.

static-connectors

Either this or discovery-group-ref is used to connect the bridge to the target server.

The static-connectors is a list of connector-ref elements pointing to connector elements defined elsewhere. A connector encapsulates knowledge of what transport to use (TCP, SSL, HTTP etc) as well as the server connection parameters (host, port etc). For more information about what connectors are and how to configure them, please see Configuring the Transport.

discovery-group-ref

Either this or static-connectors is used to connect the bridge to the target server.

The discovery-group-ref element has one attribute - discovery-group-name. This attribute points to a discovery-group defined elsewhere. For more information about what discovery-groups are and how to configure them, please see Discovery Groups.

ha

This optional parameter determines whether or not this bridge should support high availability. True means it will connect to any available server in a cluster and support failover. The default value is false.

circuit-breaker-timeout

When a connection issue occurs, as the single connection is shared by many federated queue and address consumers, to avoid each one trying to reconnect and possibly causing a thundering heard issue, the first one will try. If unsuccessful the circuit breaker will open, returning the same exception to all. This is the timeout until the circuit can be closed and connection retried. Measured in milliseconds.

share-connection

If there is a downstream and upstream connection configured for the same broker then the same connection will be shared as long as both stream configs set this flag to true. Default is false.

check-period

The period (in milliseconds) used to check if the federation connection has failed to receive pings from another server. Default is 30000.

connection-ttl

This is how long a federation connection should stay alive if it stops receiving messages from the remote broker. Default is 60000.

call-timeout

When a packet is sent via a federation 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.

call-failover-timeout

Similar to call-timeout but used when a call is made during a failover attempt. Default is -1 (no timeout).

retry-interval

This optional parameter determines the period in milliseconds between subsequent reconnection attempts, if the connection to the target server has failed. The 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 to the remote broker in the federation. If the max-retry is achieved this broker will be considered permanently down and the system will not route messages to this broker. Default is -1 (infinite retries).

reconnect-attempts

The number of times the system will try to reconnect to the remote broker in the federation. If the max-retry is achieved this broker will be considered permanently down and the system will stop routing messages to this broker. Default is -1 (infinite retries).

3. Configuring Downstream Federation

Similarly to upstream configuration, a downstream configuration can be configured. This works by sending a command to the downstream broker to have it create an upstream connection back to the downstream broker. The benefit of this is being able to configure everything for federation on one broker in some cases to make it easier, such as a hub and spoke topology

All of the same configuration options apply to downstream as does upstream with the exception of one extra configuration flag that needs to be set:

The upstream-connector-ref is an element pointing to a connector elements defined elsewhere. This ref is used to tell the downstream broker what connector to use to create a new upstream connection back to the downstream broker.

A connector encapsulates knowledge of what transport to use (TCP, SSL, HTTP etc) as well as the server connection parameters (host, port etc). For more information about what connectors are and how to configure them, please see Configuring the Transport.

Sample Downstream Address Federation setup:

  1. <!--Other config Here -->
  2. <connectors>
  3. <connector name="netty-connector">tcp://localhost:61616</connector>
  4. <connector name="eu-west-1-connector">tcp://localhost:61616</connector>
  5. <connector name="eu-east-1-connector">tcp://localhost:61617</connector>
  6. </connectors>
  7. <acceptors>
  8. <acceptor name="netty-acceptor">tcp://localhost:61616</acceptor>
  9. </acceptors>
  10. <!--Other config Here -->
  11. <federations>
  12. <federation name="eu-north-1" user="federation_username" password="32a10275cf4ab4e9">
  13. <downstream name="eu-east-1">
  14. <static-connectors>
  15. <connector-ref>eu-east-connector1</connector-ref>
  16. </static-connectors>
  17. <upstream-connector-ref>netty-connector</upstream-connector-ref>
  18. <policy ref="news-address-federation"/>
  19. </downstream>
  20. <downstream name="eu-west-1" >
  21. <static-connectors>
  22. <connector-ref>eu-west-connector1</connector-ref>
  23. </static-connectors>
  24. <upstream-connector-ref>netty-connector</upstream-connector-ref>
  25. <policy ref="news-address-federation"/>
  26. </downstream>
  27. <address-policy name="news-address-federation" max-hops="1" auto-delete="true" auto-delete-delay="300000" auto-delete-message-count="-1" transformer-ref="federation-transformer-3">
  28. <include address-match="queue.bbc.new" />
  29. <include address-match="queue.usatoday" />
  30. <include address-match="queue.news.#" />
  31. <exclude address-match="queue.news.sport.#" />
  32. </address-policy>
  33. <transformer name="news-transformer">
  34. <class-name>org.foo.NewsTransformer</class-name>
  35. <property key="key1" value="value1"/>
  36. <property key="key2" value="value2"/>
  37. </transformer>
  38. </federation>
  39. </federations>