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Akka/Scala example source code file (cluster-usage.rst)
The cluster-usage.rst Akka example source code.. _cluster_usage_scala: ####################### Cluster Usage ####################### For introduction to the Akka Cluster concepts please see :ref:`cluster`. Preparing Your Project for Clustering ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ The Akka cluster is a separate jar file. Make sure that you have the following dependency in your project:: "com.typesafe.akka" %% "akka-cluster" % "@version@" @crossString@ A Simple Cluster Example ^^^^^^^^^^^^^^^^^^^^^^^^ The following configuration enables the ``Cluster`` extension to be used. It joins the cluster and an actor subscribes to cluster membership events and logs them. The ``application.conf`` configuration looks like this: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/resources/application.conf To enable cluster capabilities in your Akka project you should, at a minimum, add the :ref:`remoting-scala` settings, but with ``akka.cluster.ClusterActorRefProvider``. The ``akka.cluster.seed-nodes`` should normally also be added to your ``application.conf`` file. The seed nodes are configured contact points for initial, automatic, join of the cluster. Note that if you are going to start the nodes on different machines you need to specify the ip-addresses or host names of the machines in ``application.conf`` instead of ``127.0.0.1`` An actor that uses the cluster extension may look like this: .. literalinclude:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/simple/SimpleClusterListener.scala :language: scala The actor registers itself as subscriber of certain cluster events. It receives events corresponding to the current state of the cluster when the subscription starts and then it receives events for changes that happen in the cluster. The easiest way to run this example yourself is to download `Typesafe Activator <http://www.typesafe.com/platform/getstarted>`_ and open the tutorial named `Akka Cluster Samples with Scala <http://www.typesafe.com/activator/template/akka-sample-cluster-scala>`_. It contains instructions of how to run the ``SimpleClusterApp``. Joining to Seed Nodes ^^^^^^^^^^^^^^^^^^^^^ You may decide if joining to the cluster should be done manually or automatically to configured initial contact points, so-called seed nodes. When a new node is started it sends a message to all seed nodes and then sends join command to the one that answers first. If no one of the seed nodes replied (might not be started yet) it retries this procedure until successful or shutdown. You define the seed nodes in the :ref:`cluster_configuration_scala` file (application.conf):: akka.cluster.seed-nodes = [ "akka.tcp://ClusterSystem@host1:2552", "akka.tcp://ClusterSystem@host2:2552"] This can also be defined as Java system properties when starting the JVM using the following syntax:: -Dakka.cluster.seed-nodes.0=akka.tcp://ClusterSystem@host1:2552 -Dakka.cluster.seed-nodes.1=akka.tcp://ClusterSystem@host2:2552 The seed nodes can be started in any order and it is not necessary to have all seed nodes running, but the node configured as the first element in the ``seed-nodes`` configuration list must be started when initially starting a cluster, otherwise the other seed-nodes will not become initialized and no other node can join the cluster. The reason for the special first seed node is to avoid forming separated islands when starting from an empty cluster. It is quickest to start all configured seed nodes at the same time (order doesn't matter), otherwise it can take up to the configured ``seed-node-timeout`` until the nodes can join. Once more than two seed nodes have been started it is no problem to shut down the first seed node. If the first seed node is restarted it will first try join the other seed nodes in the existing cluster. If you don't configure the seed nodes you need to join manually, using :ref:`cluster_jmx_scala` or :ref:`cluster_command_line_scala`. You can join to any node in the cluster. It doesn't have to be configured as a seed node. Joining can also be performed programatically with ``Cluster(system).join``. Note that you can only join to an existing cluster member, which means that for bootstrapping some node must join itself. You may also use ``Cluster(system).joinSeedNodes``, which is attractive when dynamically discovering other nodes at startup by using some external tool or API. When using ``joinSeedNodes`` you should not include the node itself except for the node that is supposed to be the first seed node, and that should be placed first in parameter to ``joinSeedNodes``. Unsuccessful join attempts are automatically retried after the time period defined in configuration property ``retry-unsuccessful-join-after``. When using ``seed-nodes`` this means that a new seed node is picked. When joining manually or programatically this means that the last join request is retried. Retries can be disabled by setting the property to ``off``. An actor system can only join a cluster once. Additional attempts will be ignored. When it has successfully joined it must be restarted to be able to join another cluster or to join the same cluster again. It can use the same host name and port after the restart, but it must have been removed from the cluster before the join request is accepted. .. _automatic-vs-manual-downing-scala: Automatic vs. Manual Downing ^^^^^^^^^^^^^^^^^^^^^^^^^^^^ When a member is considered by the failure detector to be unreachable the leader is not allowed to perform its duties, such as changing status of new joining members to 'Up'. The node must first become reachable again, or the status of the unreachable member must be changed to 'Down'. Changing status to 'Down' can be performed automatically or manually. By default it must be done manually, using :ref:`cluster_jmx_scala` or :ref:`cluster_command_line_scala`. It can also be performed programatically with ``Cluster(system).down(address)``. You can enable automatic downing with configuration:: akka.cluster.auto-down-unreachable-after = 120s This means that the cluster leader member will change the ``unreachable`` node status to ``down`` automatically after the configured time of unreachability. Be aware of that using auto-down implies that two separate clusters will automatically be formed in case of network partition. That might be desired by some applications but not by others. .. note:: If you have *auto-down* enabled and the failure detector triggers, you can over time end up with a lot of single node clusters if you don't put measures in place to shut down nodes that have become ``unreachable``. This follows from the fact that the ``unreachable`` node will likely see the rest of the cluster as ``unreachable``, become its own leader and form its own cluster. Leaving ^^^^^^^ There are two ways to remove a member from the cluster. You can just stop the actor system (or the JVM process). It will be detected as unreachable and removed after the automatic or manual downing as described above. A more graceful exit can be performed if you tell the cluster that a node shall leave. This can be performed using :ref:`cluster_jmx_scala` or :ref:`cluster_command_line_scala`. It can also be performed programatically with ``Cluster(system).leave(address)``. Note that this command can be issued to any member in the cluster, not necessarily the one that is leaving. The cluster extension, but not the actor system or JVM, of the leaving member will be shutdown after the leader has changed status of the member to `Exiting`. Thereafter the member will be removed from the cluster. Normally this is handled automatically, but in case of network failures during this process it might still be necessary to set the node’s status to ``Down`` in order to complete the removal. .. _cluster_subscriber_scala: Subscribe to Cluster Events ^^^^^^^^^^^^^^^^^^^^^^^^^^^ You can subscribe to change notifications of the cluster membership by using ``Cluster(system).subscribe``. .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/simple/SimpleClusterListener2.scala#subscribe A snapshot of the full state, ``akka.cluster.ClusterEvent.CurrentClusterState``, is sent to the subscriber as the first message, followed by events for incremental updates. Note that you may receive an empty ``CurrentClusterState``, containing no members, if you start the subscription before the initial join procedure has completed. This is expected behavior. When the node has been accepted in the cluster you will receive ``MemberUp`` for that node, and other nodes. If you find it inconvenient to handle the ``CurrentClusterState`` you can use ``ClusterEvent.InitialStateAsEvents`` as parameter to ``subscribe``. That means that instead of receiving ``CurrentClusterState`` as the first message you will receive the events corresponding to the current state to mimic what you would have seen if you were listening to the events when they occurred in the past. Note that those initial events only correspond to the current state and it is not the full history of all changes that actually has occurred in the cluster. .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/simple/SimpleClusterListener.scala#subscribe The events to track the life-cycle of members are: * ``ClusterEvent.MemberUp`` - A new member has joined the cluster and its status has been changed to ``Up``. * ``ClusterEvent.MemberExited`` - A member is leaving the cluster and its status has been changed to ``Exiting`` Note that the node might already have been shutdown when this event is published on another node. * ``ClusterEvent.MemberRemoved`` - Member completely removed from the cluster. * ``ClusterEvent.UnreachableMember`` - A member is considered as unreachable, detected by the failure detector of at least one other node. * ``ClusterEvent.ReachableMember`` - A member is considered as reachable again, after having been unreachable. All nodes that previously detected it as unreachable has detected it as reachable again. There are more types of change events, consult the API documentation of classes that extends ``akka.cluster.ClusterEvent.ClusterDomainEvent`` for details about the events. Instead of subscribing to cluster events it can sometimes be convenient to only get the full membership state with ``Cluster(system).state``. Note that this state is not necessarily in sync with the events published to a cluster subscription. Worker Dial-in Example ---------------------- Let's take a look at an example that illustrates how workers, here named *backend*, can detect and register to new master nodes, here named *frontend*. The example application provides a service to transform text. When some text is sent to one of the frontend services, it will be delegated to one of the backend workers, which performs the transformation job, and sends the result back to the original client. New backend nodes, as well as new frontend nodes, can be added or removed to the cluster dynamically. Messages: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/transformation/TransformationMessages.scala#messages The backend worker that performs the transformation job: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/transformation/TransformationBackend.scala#backend Note that the ``TransformationBackend`` actor subscribes to cluster events to detect new, potential, frontend nodes, and send them a registration message so that they know that they can use the backend worker. The frontend that receives user jobs and delegates to one of the registered backend workers: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/transformation/TransformationFrontend.scala#frontend Note that the ``TransformationFrontend`` actor watch the registered backend to be able to remove it from its list of available backend workers. Death watch uses the cluster failure detector for nodes in the cluster, i.e. it detects network failures and JVM crashes, in addition to graceful termination of watched actor. Death watch generates the ``Terminated`` message to the watching actor when the unreachable cluster node has been downed and removed. The `Typesafe Activator <http://www.typesafe.com/platform/getstarted>`_ tutorial named `Akka Cluster Samples with Scala <http://www.typesafe.com/activator/template/akka-sample-cluster-scala>`_. contains the full source code and instructions of how to run the **Worker Dial-in Example**. Node Roles ^^^^^^^^^^ Not all nodes of a cluster need to perform the same function: there might be one sub-set which runs the web front-end, one which runs the data access layer and one for the number-crunching. Deployment of actors—for example by cluster-aware routers—can take node roles into account to achieve this distribution of responsibilities. The roles of a node is defined in the configuration property named ``akka.cluster.roles`` and it is typically defined in the start script as a system property or environment variable. The roles of the nodes is part of the membership information in ``MemberEvent`` that you can subscribe to. How To Startup when Cluster Size Reached ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ A common use case is to start actors after the cluster has been initialized, members have joined, and the cluster has reached a certain size. With a configuration option you can define required number of members before the leader changes member status of 'Joining' members to 'Up'. .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/resources/factorial.conf#min-nr-of-members In a similar way you can define required number of members of a certain role before the leader changes member status of 'Joining' members to 'Up'. .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/resources/factorial.conf#role-min-nr-of-members You can start the actors in a ``registerOnMemberUp`` callback, which will be invoked when the current member status is changed tp 'Up', i.e. the cluster has at least the defined number of members. .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/factorial/FactorialFrontend.scala#registerOnUp This callback can be used for other things than starting actors. Cluster Singleton ^^^^^^^^^^^^^^^^^ For some use cases it is convenient and sometimes also mandatory to ensure that you have exactly one actor of a certain type running somewhere in the cluster. This can be implemented by subscribing to member events, but there are several corner cases to consider. Therefore, this specific use case is made easily accessible by the :ref:`cluster-singleton` in the contrib module. Cluster Sharding ^^^^^^^^^^^^^^^^ Distributes actors across several nodes in the cluster and supports interaction with the actors using their logical identifier, but without having to care about their physical location in the cluster. See :ref:`cluster-sharding` in the contrib module. Distributed Publish Subscribe ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Publish-subscribe messaging between actors in the cluster, and point-to-point messaging using the logical path of the actors, i.e. the sender does not have to know on which node the destination actor is running. See :ref:`distributed-pub-sub` in the contrib module. Cluster Client ^^^^^^^^^^^^^^ Communication from an actor system that is not part of the cluster to actors running somewhere in the cluster. The client does not have to know on which node the destination actor is running. See :ref:`cluster-client` in the contrib module. Failure Detector ^^^^^^^^^^^^^^^^ In a cluster each node is monitored by a few (default maximum 5) other nodes, and when any of these detects the node as ``unreachable`` that information will spread to the rest of the cluster through the gossip. In other words, only one node needs to mark a node ``unreachable`` to have the rest of the cluster mark that node ``unreachable``. The failure detector will also detect if the node becomes ``reachable`` again. When all nodes that monitored the ``unreachable`` node detects it as ``reachable`` again the cluster, after gossip dissemination, will consider it as ``reachable``. If system messages cannot be delivered to a node it will be quarantined and then it cannot come back from ``unreachable``. This can happen if the there are too many unacknowledged system messages (e.g. watch, Terminated, remote actor deployment, failures of actors supervised by remote parent). Then the node needs to be moved to the ``down`` or ``removed`` states and the actor system must be restarted before it can join the cluster again. The nodes in the cluster monitor each other by sending heartbeats to detect if a node is unreachable from the rest of the cluster. The heartbeat arrival times is interpreted by an implementation of `The Phi Accrual Failure Detector <http://ddg.jaist.ac.jp/pub/HDY+04.pdf>`_. The suspicion level of failure is given by a value called *phi*. The basic idea of the phi failure detector is to express the value of *phi* on a scale that is dynamically adjusted to reflect current network conditions. The value of *phi* is calculated as:: phi = -log10(1 - F(timeSinceLastHeartbeat)) where F is the cumulative distribution function of a normal distribution with mean and standard deviation estimated from historical heartbeat inter-arrival times. In the :ref:`cluster_configuration_scala` you can adjust the ``akka.cluster.failure-detector.threshold`` to define when a *phi* value is considered to be a failure. A low ``threshold`` is prone to generate many false positives but ensures a quick detection in the event of a real crash. Conversely, a high ``threshold`` generates fewer mistakes but needs more time to detect actual crashes. The default ``threshold`` is 8 and is appropriate for most situations. However in cloud environments, such as Amazon EC2, the value could be increased to 12 in order to account for network issues that sometimes occur on such platforms. The following chart illustrates how *phi* increase with increasing time since the previous heartbeat. .. image:: ../images/phi1.png Phi is calculated from the mean and standard deviation of historical inter arrival times. The previous chart is an example for standard deviation of 200 ms. If the heartbeats arrive with less deviation the curve becomes steeper, i.e. it is possible to determine failure more quickly. The curve looks like this for a standard deviation of 100 ms. .. image:: ../images/phi2.png To be able to survive sudden abnormalities, such as garbage collection pauses and transient network failures the failure detector is configured with a margin, ``akka.cluster.failure-detector.acceptable-heartbeat-pause``. You may want to adjust the :ref:`cluster_configuration_scala` of this depending on you environment. This is how the curve looks like for ``acceptable-heartbeat-pause`` configured to 3 seconds. .. image:: ../images/phi3.png Death watch uses the cluster failure detector for nodes in the cluster, i.e. it detects network failures and JVM crashes, in addition to graceful termination of watched actor. Death watch generates the ``Terminated`` message to the watching actor when the unreachable cluster node has been downed and removed. If you encounter suspicious false positives when the system is under load you should define a separate dispatcher for the cluster actors as described in :ref:`cluster_dispatcher_scala`. .. _cluster_aware_routers_scala: Cluster Aware Routers ^^^^^^^^^^^^^^^^^^^^^ All :ref:`routers <routing-scala>` can be made aware of member nodes in the cluster, i.e. deploying new routees or looking up routees on nodes in the cluster. When a node becomes unreachable or leaves the cluster the routees of that node are automatically unregistered from the router. When new nodes join the cluster, additional routees are added to the router, according to the configuration. Routees are also added when a node becomes reachable again, after having been unreachable. There are two distinct types of routers. * **Group - router that sends messages to the specified path using actor selection** The routees can be shared among routers running on different nodes in the cluster. One example of a use case for this type of router is a service running on some backend nodes in the cluster and used by routers running on front-end nodes in the cluster. * **Pool - router that creates routees as child actors and deploys them on remote nodes.** Each router will have its own routee instances. For example, if you start a router on 3 nodes in a 10-node cluster, you will have 30 routees in total if the router is configured to use one instance per node. The routees created by the different routers will not be shared among the routers. One example of a use case for this type of router is a single master that coordinates jobs and delegates the actual work to routees running on other nodes in the cluster. Router with Group of Routees ---------------------------- When using a ``Group`` you must start the routee actors on the cluster member nodes. That is not done by the router. The configuration for a group looks like this: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/multi-jvm/scala/sample/cluster/stats/StatsSampleSpec.scala#router-lookup-config .. note:: The routee actors should be started as early as possible when starting the actor system, because the router will try to use them as soon as the member status is changed to 'Up'. If it is not available at that point it will be removed from the router and it will only re-try when the cluster members are changed. It is the relative actor paths defined in ``routees.paths`` that identify what actor to lookup. It is possible to limit the lookup of routees to member nodes tagged with a certain role by specifying ``use-role``. ``nr-of-instances`` defines total number of routees in the cluster. Setting ``nr-of-instances`` to a high value will result in new routees added to the router when nodes join the cluster. The same type of router could also have been defined in code: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/stats/Extra.scala#router-lookup-in-code See :ref:`cluster_configuration_scala` section for further descriptions of the settings. Router Example with Group of Routees ------------------------------------ Let's take a look at how to use a cluster aware router with a group of routees, i.e. router sending to the paths of the routees. The example application provides a service to calculate statistics for a text. When some text is sent to the service it splits it into words, and delegates the task to count number of characters in each word to a separate worker, a routee of a router. The character count for each word is sent back to an aggregator that calculates the average number of characters per word when all results have been collected. Messages: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/stats/StatsMessages.scala#messages The worker that counts number of characters in each word: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/stats/StatsWorker.scala#worker The service that receives text from users and splits it up into words, delegates to workers and aggregates: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/stats/StatsService.scala#service Note, nothing cluster specific so far, just plain actors. All nodes start ``StatsService`` and ``StatsWorker`` actors. Remember, routees are the workers in this case. The router is configured with ``routees.paths``: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/resources/stats1.conf#config-router-lookup This means that user requests can be sent to ``StatsService`` on any node and it will use ``StatsWorker`` on all nodes. The `Typesafe Activator <http://www.typesafe.com/platform/getstarted>`_ tutorial named `Akka Cluster Samples with Scala <http://www.typesafe.com/activator/template/akka-sample-cluster-scala>`_. contains the full source code and instructions of how to run the **Router Example with Group of Routees**. Router with Pool of Remote Deployed Routees ------------------------------------------- When using a ``Pool`` with routees created and deployed on the cluster member nodes the configuration for a router looks like this: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/multi-jvm/scala/sample/cluster/stats/StatsSampleSingleMasterSpec.scala#router-deploy-config It is possible to limit the deployment of routees to member nodes tagged with a certain role by specifying ``use-role``. ``nr-of-instances`` defines total number of routees in the cluster, but the number of routees per node, ``max-nr-of-instances-per-node``, will not be exceeded. Setting ``nr-of-instances`` to a high value will result in creating and deploying additional routees when new nodes join the cluster. The same type of router could also have been defined in code: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/stats/Extra.scala#router-deploy-in-code See :ref:`cluster_configuration_scala` section for further descriptions of the settings. Router Example with Pool of Remote Deployed Routees --------------------------------------------------- Let's take a look at how to use a cluster aware router on single master node that creates and deploys workers. To keep track of a single master we use the :ref:`cluster-singleton` in the contrib module. The ``ClusterSingletonManager`` is started on each node. .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/stats/StatsSampleOneMaster.scala#create-singleton-manager We also need an actor on each node that keeps track of where current single master exists and delegates jobs to the ``StatsService``. That is provided by the ``ClusterSingletonProxy``. .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/stats/StatsSampleOneMaster.scala#singleton-proxy The ``ClusterSingletonProxy`` receives text from users and delegates to the current ``StatsService``, the single master. It listens to cluster events to lookup the ``StatsService`` on the oldest node. All nodes start ``ClusterSingletonProxy`` and the ``ClusterSingletonManager``. The router is now configured like this: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/resources/stats2.conf#config-router-deploy The `Typesafe Activator <http://www.typesafe.com/platform/getstarted>`_ tutorial named `Akka Cluster Samples with Scala <http://www.typesafe.com/activator/template/akka-sample-cluster-scala>`_. contains the full source code and instructions of how to run the **Router Example with Pool of Remote Deployed Routees**. Cluster Metrics ^^^^^^^^^^^^^^^ The member nodes of the cluster collects system health metrics and publishes that to other nodes and to registered subscribers. This information is primarily used for load-balancing routers. Hyperic Sigar ------------- The built-in metrics is gathered from JMX MBeans, and optionally you can use `Hyperic Sigar <http://www.hyperic.com/products/sigar>`_ for a wider and more accurate range of metrics compared to what can be retrieved from ordinary MBeans. Sigar is using a native OS library. To enable usage of Sigar you need to add the directory of the native library to ``-Djava.libarary.path=<path_of_sigar_libs>`` add the following dependency:: "org.fusesource" % "sigar" % "@sigarVersion@" Download the native Sigar libraries from `Maven Central <http://repo1.maven.org/maven2/org/fusesource/sigar/@sigarVersion@/>`_ Adaptive Load Balancing ----------------------- The ``AdaptiveLoadBalancingPool`` / ``AdaptiveLoadBalancingGroup`` performs load balancing of messages to cluster nodes based on the cluster metrics data. It uses random selection of routees with probabilities derived from the remaining capacity of the corresponding node. It can be configured to use a specific MetricsSelector to produce the probabilities, a.k.a. weights: * ``heap`` / ``HeapMetricsSelector`` - Used and max JVM heap memory. Weights based on remaining heap capacity; (max - used) / max * ``load`` / ``SystemLoadAverageMetricsSelector`` - System load average for the past 1 minute, corresponding value can be found in ``top`` of Linux systems. The system is possibly nearing a bottleneck if the system load average is nearing number of cpus/cores. Weights based on remaining load capacity; 1 - (load / processors) * ``cpu`` / ``CpuMetricsSelector`` - CPU utilization in percentage, sum of User + Sys + Nice + Wait. Weights based on remaining cpu capacity; 1 - utilization * ``mix`` / ``MixMetricsSelector`` - Combines heap, cpu and load. Weights based on mean of remaining capacity of the combined selectors. * Any custom implementation of ``akka.cluster.routing.MetricsSelector`` The collected metrics values are smoothed with `exponential weighted moving average <http://en.wikipedia.org/wiki/Moving_average#Exponential_moving_average>`_. In the :ref:`cluster_configuration_scala` you can adjust how quickly past data is decayed compared to new data. Let's take a look at this router in action. What can be more demanding than calculating factorials? The backend worker that performs the factorial calculation: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/factorial/FactorialBackend.scala#backend The frontend that receives user jobs and delegates to the backends via the router: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/factorial/FactorialFrontend.scala#frontend As you can see, the router is defined in the same way as other routers, and in this case it is configured as follows: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/resources/factorial.conf#adaptive-router It is only router type ``adaptive`` and the ``metrics-selector`` that is specific to this router, other things work in the same way as other routers. The same type of router could also have been defined in code: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/factorial/Extra.scala#router-lookup-in-code .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/factorial/Extra.scala#router-deploy-in-code The `Typesafe Activator <http://www.typesafe.com/platform/getstarted>`_ tutorial named `Akka Cluster Samples with Scala <http://www.typesafe.com/activator/template/akka-sample-cluster-scala>`_. contains the full source code and instructions of how to run the **Adaptive Load Balancing** sample. Subscribe to Metrics Events --------------------------- It is possible to subscribe to the metrics events directly to implement other functionality. .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/main/scala/sample/cluster/factorial/MetricsListener.scala#metrics-listener Custom Metrics Collector ------------------------ You can plug-in your own metrics collector instead of ``akka.cluster.SigarMetricsCollector`` or ``akka.cluster.JmxMetricsCollector``. Look at those two implementations for inspiration. The implementation class can be defined in the :ref:`cluster_configuration_scala`. How to Test ^^^^^^^^^^^ :ref:`multi-node-testing` is useful for testing cluster applications. Set up your project according to the instructions in :ref:`multi-node-testing` and :ref:`multi-jvm-testing`, i.e. add the ``sbt-multi-jvm`` plugin and the dependency to ``akka-multi-node-testkit``. First, as described in :ref:`multi-node-testing`, we need some scaffolding to configure the ``MultiNodeSpec``. Define the participating roles and their :ref:`cluster_configuration_scala` in an object extending ``MultiNodeConfig``: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/multi-jvm/scala/sample/cluster/stats/StatsSampleSpec.scala :include: MultiNodeConfig :exclude: router-lookup-config Define one concrete test class for each role/node. These will be instantiated on the different nodes (JVMs). They can be implemented differently, but often they are the same and extend an abstract test class, as illustrated here. .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/multi-jvm/scala/sample/cluster/stats/StatsSampleSpec.scala#concrete-tests Note the naming convention of these classes. The name of the classes must end with ``MultiJvmNode1``, ``MultiJvmNode2`` and so on. It is possible to define another suffix to be used by the ``sbt-multi-jvm``, but the default should be fine in most cases. Then the abstract ``MultiNodeSpec``, which takes the ``MultiNodeConfig`` as constructor parameter. .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/multi-jvm/scala/sample/cluster/stats/StatsSampleSpec.scala#abstract-test Most of this can of course be extracted to a separate trait to avoid repeating this in all your tests. Typically you begin your test by starting up the cluster and let the members join, and create some actors. That can be done like this: .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/multi-jvm/scala/sample/cluster/stats/StatsSampleSpec.scala#startup-cluster From the test you interact with the cluster using the ``Cluster`` extension, e.g. ``join``. .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/multi-jvm/scala/sample/cluster/stats/StatsSampleSpec.scala#join Notice how the `testActor` from :ref:`testkit <akka-testkit>` is added as :ref:`subscriber <cluster_subscriber_scala>` to cluster changes and then waiting for certain events, such as in this case all members becoming 'Up'. The above code was running for all roles (JVMs). ``runOn`` is a convenient utility to declare that a certain block of code should only run for a specific role. .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/multi-jvm/scala/sample/cluster/stats/StatsSampleSpec.scala#test-statsService Once again we take advantage of the facilities in :ref:`testkit <akka-testkit>` to verify expected behavior. Here using ``testActor`` as sender (via ``ImplicitSender``) and verifing the reply with ``expectMsgPF``. In the above code you can see ``node(third)``, which is useful facility to get the root actor reference of the actor system for a specific role. This can also be used to grab the ``akka.actor.Address`` of that node. .. includecode:: ../../../akka-samples/akka-sample-cluster-scala/src/multi-jvm/scala/sample/cluster/stats/StatsSampleSpec.scala#addresses .. _cluster_jmx_scala: JMX ^^^ Information and management of the cluster is available as JMX MBeans with the root name ``akka.Cluster``. The JMX information can be displayed with an ordinary JMX console such as JConsole or JVisualVM. From JMX you can: * see what members that are part of the cluster * see status of this node * join this node to another node in cluster * mark any node in the cluster as down * tell any node in the cluster to leave Member nodes are identified by their address, in format `akka.<protocol>://<actor-system-name>@<hostname>:<port>`. .. _cluster_command_line_scala: Command Line Management ^^^^^^^^^^^^^^^^^^^^^^^ The cluster can be managed with the script `bin/akka-cluster` provided in the Akka distribution. Run it without parameters to see instructions about how to use the script:: Usage: bin/akka-cluster <node-hostname> <jmx-port> <command> ... Supported commands are: join <node-url> - Sends request a JOIN node with the specified URL leave <node-url> - Sends a request for node with URL to LEAVE the cluster down <node-url> - Sends a request for marking node with URL as DOWN member-status - Asks the member node for its current status members - Asks the cluster for addresses of current members unreachable - Asks the cluster for addresses of unreachable members cluster-status - Asks the cluster for its current status (member ring, unavailable nodes, meta data etc.) leader - Asks the cluster who the current leader is is-singleton - Checks if the cluster is a singleton cluster (single node cluster) is-available - Checks if the member node is available Where the <node-url> should be on the format of 'akka.<protocol>://<actor-system-name>@<hostname>:<port>' Examples: bin/akka-cluster localhost 9999 is-available bin/akka-cluster localhost 9999 join akka.tcp://MySystem@darkstar:2552 bin/akka-cluster localhost 9999 cluster-status To be able to use the script you must enable remote monitoring and management when starting the JVMs of the cluster nodes, as described in `Monitoring and Management Using JMX Technology <http://docs.oracle.com/javase/6/docs/technotes/guides/management/agent.html>`_ Example of system properties to enable remote monitoring and management:: java -Dcom.sun.management.jmxremote.port=9999 \ -Dcom.sun.management.jmxremote.authenticate=false \ -Dcom.sun.management.jmxremote.ssl=false .. _cluster_configuration_scala: Configuration ^^^^^^^^^^^^^ There are several configuration properties for the cluster. We refer to the :ref:`reference configuration <config-akka-cluster>` for more information. Cluster Info Logging -------------------- You can silence the logging of cluster events at info level with configuration property:: akka.cluster.log-info = off .. _cluster_dispatcher_scala: Cluster Dispatcher ------------------ Under the hood the cluster extension is implemented with actors and it can be necessary to create a bulkhead for those actors to avoid disturbance from other actors. Especially the heartbeating actors that is used for failure detection can generate false positives if they are not given a chance to run at regular intervals. For this purpose you can define a separate dispatcher to be used for the cluster actors:: akka.cluster.use-dispatcher = cluster-dispatcher cluster-dispatcher { type = "Dispatcher" executor = "fork-join-executor" fork-join-executor { parallelism-min = 2 parallelism-max = 4 } } Other Akka source code examplesHere is a short list of links related to this Akka cluster-usage.rst source code file: |
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