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In the ticker example, the Feeder and the Enricher both use state replication. We'll focus on the Enricher class to demonstrate how to setup state replication in an X application. The Enricher's functionality is pretty straightforward. It receives tick updates from the Feeder on the Tick channel, stores the received updates in a queue which it uses to determine the symbol's historical trend, and then enriches the received Tick messages with its calculated trend info and sends it off on the EnhancedTicks channel where the receiver is listening. The key point here is that the Enricher is operating using the ApplicationState that we modeled in the previous sections, and the platform is transparently handling replication under the covers. In the event of an application failure (such as the one that the Sample Induces), processing can resume where it left off: the application state and in doubt state of any messages are transparently and atomically resolved on the backup.

The following sections walk through the code of the Enricher sample, discussing the steps for configuring the engine.

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Step 1: Register Object Factories

In this sample, the same factory class is used for both messages and state. An instance of the object factory has to be registered with both the MessageViewFactoryRegistry and the StoreObjectFactoryRegistry. The latter registry allows the underlying state replication machinery to deserialize replicated state objects based on the ids encoded in the replication stream, while the former registry is used for deserializing replicated messages. In the sample, this is done in a Common superclass used by all the applications since this step is common to all of them:.

// for messaging
MessageViewFactoryRegistry.getInstance().registerMessageViewFactory(new ObjectFactory()); 
// for state replication:
StoreObjectFactoryRegistry.getInstance(). 
registerObjectFactory(new ObjectFactory());

Step 2: Set up the Store

The object store is what handles state replication. The native store implementation forms clusters with other stores of the same name using a discovery protocol and it elects a Primary based on a peer election algorithm. In the snippet below we create a store cluster called "Enricher" (NAME), and save it to the configuration repository.

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The snippet below shows the configuration of the Enricher's engine descriptor. We create a new descriptor and set the HAPolicy to use StateReplication. When using you use state replicaton replication, you must also use a MessageSendPolicy of ReplicateBeforeSend which indicates that state must be replicated before outbound messages are sent. This ensures that messages and state are replicated to backups prior to sending messages downstream. This is crucial in state replication because it ensure ensures that inbound messages receipt and mutations to state are stabilized prior to committing the send of outbound messages that result from those mutations.

Finally, we specify a ReplicationPolicy of Pipelined to ensure that replicated state is acknowledged by our backup prior to sending the enriched message on to the Receiver to ensure . This ensures that we don't produce duplicates.

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An AEPEngine is application state agnostic: it deals with state only abstractly as a replicated graph of object graph node updates using the underlying store. As such, it needs to be able to create new application state during the processing of messages. To facilitate this, an engine's constructor takes a IApplicationStateFactory parameter as shown from the Enricher snippet below.

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The table below lists the configuration options we have discussed so far:.

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1. By a primary engine when it receives the first message of a flow, in which case it utilizes the application provided IApplicationStateFactory.
2. By a backup engine when application state is replicated from a primary.
3. Explicitly by an application on an AepMessagingPrestartEvent handler.

There are two Two constraints that need to be met when the state is created explicitly by the application.

1. For performance reasons, the state creation is not thread safe. Thus, the state must be created before the engine's messaging has been started.
2. The state needs to be created after the engine has bound to the applications's ODS store. This needs to be done so that the created state is attached to the opened store.

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The below snippet comes from the Enricher message handler. From with With a message handler, application state should be retrieved using the Engine's getApplicationState(MessageView) accessor, which retrieves the state associated with the message's flow. In the Ticker sample, the flow is defined by the hashCode of the symbol and is set by the Feeder. Flows define the order in which messages are processed in the system. Flows essentially partition traffic into ordered parallel processed streams and, therefore, enable parallelized, concurrent message processing.
Under the covers, the Engine ensures that both messages and state are replicated to the backup to prevent loss or duplication in the event of a failure.

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The Feeder operates slightly differently. Because it is the origin point of the traffic, it can't retrieve its state from the Engine using a MessageView, but as mentioned previously, Creation of State can only be done from an engine thread. It must therefore create its state from within an AepMessagingPrestartEvent handler. If the Feeder were to operate with multiple flows (and consequently multiple application state instances, it would need to create them all here.

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The sample application is simple and operates with a single flow based on the symbol. For simplicity, we use the hashcode of the symbol name to map this to an integer id representing the flow. The sender creates the state and stores it in a private variable _state for use during runtime. The created state is not threadsafe, so in this context in , it can only be used by the feeder's thread will sending its messages.

Limitations and Upcoming Enhancements

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