C# Class Akka.Persistence.Journal.AsyncWriteJournal

Inheritance: Akka.Persistence.Journal.WriteJournalBase, IAsyncRecovery
ファイルを表示 Open project: rogeralsing/akka.net

Protected Properties

Property Type Description
CanPublish bool

Public Methods

Method Description
ReadHighestSequenceNrAsync ( string persistenceId, long fromSequenceNr ) : Task
ReplayMessagesAsync ( IActorContext context, string persistenceId, long fromSequenceNr, long toSequenceNr, long max, Action recoveryCallback ) : System.Threading.Tasks.Task

Protected Methods

Method Description
AsyncWriteJournal ( ) : System
DeleteMessagesToAsync ( string persistenceId, long toSequenceNr ) : System.Threading.Tasks.Task

Asynchronously deletes all persistent messages up to inclusive toSequenceNr bound.

Receive ( object message ) : bool
ReceivePluginInternal ( object message ) : bool

Allows plugin implementers to use PipeToSupport.PipeTo{T} ActorBase.Self and handle additional messages for implementing advanced features

ReceiveWriteJournal ( object message ) : bool
WriteMessagesAsync ( IEnumerable messages ) : Task>

Plugin API: asynchronously writes a batch of persistent messages to the journal. The batch is only for performance reasons, i.e. all messages don't have to be written atomically. Higher throughput can typically be achieved by using batch inserts of many records compared to inserting records one-by-one, but this aspect depends on the underlying data store and a journal implementation can implement it as efficient as possible. Journals should aim to persist events in-order for a given `persistenceId` as otherwise in case of a failure, the persistent state may be end up being inconsistent. Each AtomicWrite message contains the single Persistent that corresponds to the event that was passed to the PersistentActor.Persist{TEvent}(TEvent,Action{TEvent}) method of the PersistentActor, or it contains several Persistent that correspond to the events that were passed to the PersistentActor.PersistAll{TEvent}(IEnumerable{TEvent},Action{TEvent}) method of the PersistentActor. All Persistent of the AtomicWrite must be written to the data store atomically, i.e. all or none must be stored. If the journal (data store) cannot support atomic writes of multiple events it should reject such writes with a NotSupportedException describing the issue. This limitation should also be documented by the journal plugin. If there are failures when storing any of the messages in the batch the returned Task must be completed with failure. The Task must only be completed with success when all messages in the batch have been confirmed to be stored successfully, i.e. they will be readable, and visible, in a subsequent replay. If there is uncertainty about if the messages were stored or not the Task must be completed with failure. Data store connection problems must be signaled by completing the Task with failure. The journal can also signal that it rejects individual messages (AtomicWrite) by the returned Task. It is possible but not mandatory to reduce number of allocations by returning null for the happy path, i.e. when no messages are rejected. Otherwise the returned list must have as many elements as the input messages. Each result element signals if the corresponding AtomicWrite is rejected or not, with an exception describing the problem. Rejecting a message means it was not stored, i.e. it must not be included in a later replay. Rejecting a message is typically done before attempting to store it, e.g. because of serialization error. Data store connection problems must not be signaled as rejections. It is possible but not mandatory to reduce number of allocations by returning null for the happy path, i.e. when no messages are rejected. Calls to this method are serialized by the enclosing journal actor. If you spawn work in asyncronous tasks it is alright that they complete the futures in any order, but the actual writes for a specific persistenceId should be serialized to avoid issues such as events of a later write are visible to consumers (query side, or replay) before the events of an earlier write are visible. A PersistentActor will not send a new WriteMessages request before the previous one has been completed. Please not that the IPersistentRepresentation.Sender of the contained Persistent objects has been nulled out (i.e. set to ActorRefs.NoSender in order to not use space in the journal for a sender reference that will likely be obsolete during replay. Please also note that requests for the highest sequence number may be made concurrently to this call executing for the same `persistenceId`, in particular it is possible that a restarting actor tries to recover before its outstanding writes have completed. In the latter case it is highly desirable to defer reading the highest sequence number until all outstanding writes have completed, otherwise the PersistentActor may reuse sequence numbers. This call is protected with a circuit-breaker.

Private Methods

Method Description
HandleDeleteMessagesTo ( DeleteMessagesTo message ) : void
HandleReadHighestSequenceNr ( ReadHighestSequenceNr message ) : void
HandleReplayMessages ( ReplayMessages message ) : void
HandleWriteMessages ( WriteMessages message ) : void
TryUnwrapException ( Exception e ) : Exception

Method Details

AsyncWriteJournal() protected method

protected AsyncWriteJournal ( ) : System
return System

DeleteMessagesToAsync() protected abstract method

Asynchronously deletes all persistent messages up to inclusive toSequenceNr bound.
protected abstract DeleteMessagesToAsync ( string persistenceId, long toSequenceNr ) : System.Threading.Tasks.Task
persistenceId string
toSequenceNr long
return System.Threading.Tasks.Task

ReadHighestSequenceNrAsync() public abstract method

public abstract ReadHighestSequenceNrAsync ( string persistenceId, long fromSequenceNr ) : Task
persistenceId string
fromSequenceNr long
return Task

Receive() protected final method

protected final Receive ( object message ) : bool
message object
return bool

ReceivePluginInternal() protected method

Allows plugin implementers to use PipeToSupport.PipeTo{T} ActorBase.Self and handle additional messages for implementing advanced features
protected ReceivePluginInternal ( object message ) : bool
message object
return bool

ReceiveWriteJournal() protected method

protected ReceiveWriteJournal ( object message ) : bool
message object
return bool

ReplayMessagesAsync() public abstract method

public abstract ReplayMessagesAsync ( IActorContext context, string persistenceId, long fromSequenceNr, long toSequenceNr, long max, Action recoveryCallback ) : System.Threading.Tasks.Task
context IActorContext
persistenceId string
fromSequenceNr long
toSequenceNr long
max long
recoveryCallback Action
return System.Threading.Tasks.Task

WriteMessagesAsync() protected abstract method

Plugin API: asynchronously writes a batch of persistent messages to the journal. The batch is only for performance reasons, i.e. all messages don't have to be written atomically. Higher throughput can typically be achieved by using batch inserts of many records compared to inserting records one-by-one, but this aspect depends on the underlying data store and a journal implementation can implement it as efficient as possible. Journals should aim to persist events in-order for a given `persistenceId` as otherwise in case of a failure, the persistent state may be end up being inconsistent. Each AtomicWrite message contains the single Persistent that corresponds to the event that was passed to the PersistentActor.Persist{TEvent}(TEvent,Action{TEvent}) method of the PersistentActor, or it contains several Persistent that correspond to the events that were passed to the PersistentActor.PersistAll{TEvent}(IEnumerable{TEvent},Action{TEvent}) method of the PersistentActor. All Persistent of the AtomicWrite must be written to the data store atomically, i.e. all or none must be stored. If the journal (data store) cannot support atomic writes of multiple events it should reject such writes with a NotSupportedException describing the issue. This limitation should also be documented by the journal plugin. If there are failures when storing any of the messages in the batch the returned Task must be completed with failure. The Task must only be completed with success when all messages in the batch have been confirmed to be stored successfully, i.e. they will be readable, and visible, in a subsequent replay. If there is uncertainty about if the messages were stored or not the Task must be completed with failure. Data store connection problems must be signaled by completing the Task with failure. The journal can also signal that it rejects individual messages (AtomicWrite) by the returned Task. It is possible but not mandatory to reduce number of allocations by returning null for the happy path, i.e. when no messages are rejected. Otherwise the returned list must have as many elements as the input messages. Each result element signals if the corresponding AtomicWrite is rejected or not, with an exception describing the problem. Rejecting a message means it was not stored, i.e. it must not be included in a later replay. Rejecting a message is typically done before attempting to store it, e.g. because of serialization error. Data store connection problems must not be signaled as rejections. It is possible but not mandatory to reduce number of allocations by returning null for the happy path, i.e. when no messages are rejected. Calls to this method are serialized by the enclosing journal actor. If you spawn work in asyncronous tasks it is alright that they complete the futures in any order, but the actual writes for a specific persistenceId should be serialized to avoid issues such as events of a later write are visible to consumers (query side, or replay) before the events of an earlier write are visible. A PersistentActor will not send a new WriteMessages request before the previous one has been completed. Please not that the IPersistentRepresentation.Sender of the contained Persistent objects has been nulled out (i.e. set to ActorRefs.NoSender in order to not use space in the journal for a sender reference that will likely be obsolete during replay. Please also note that requests for the highest sequence number may be made concurrently to this call executing for the same `persistenceId`, in particular it is possible that a restarting actor tries to recover before its outstanding writes have completed. In the latter case it is highly desirable to defer reading the highest sequence number until all outstanding writes have completed, otherwise the PersistentActor may reuse sequence numbers. This call is protected with a circuit-breaker.
protected abstract WriteMessagesAsync ( IEnumerable messages ) : Task>
messages IEnumerable
return Task>

Property Details

CanPublish protected_oe property

protected bool CanPublish
return bool