Package akka.stream.javadsl

Class Source$

java.lang.Object

akka.stream.javadsl.Source$

public class Source$
extends java.lang.Object

Create a Source with no elements, i.e. an empty stream that is completed immediately for every connected Sink.

Field Summary

Fields

Modifier and Type	Field	Description
static Source$	MODULE$	Static reference to the singleton instance of this Scala object.

Constructor Summary

Constructors

Constructor	Description
Source$()

Method Summary

Modifier and Type	Method	Description
<T> Source<T,ActorRef>	actorPublisher(Props props)	Deprecated. Use akka.stream.stage.GraphStage and fromGraph instead, it allows for all operations an Actor would and is more type-safe as well as guaranteed to be ReactiveStreams compliant.
<T> Source<T,ActorRef>	actorRef(int bufferSize, OverflowStrategy overflowStrategy)	Creates a Source that is materialized as an ActorRef.
<T> Source<T,ActorRef>	actorRefWithAck(java.lang.Object ackMessage)	Creates a Source that is materialized as an ActorRef.
<T> Source<T,org.reactivestreams.Subscriber<T>>	asSubscriber()	Creates a Source that is materialized as a Subscriber
<T,U> Source<U,NotUsed>	combine(Source<T,?> first, Source<T,?> second, java.util.List<Source<T,?>> rest, Function<java.lang.Integer,? extends Graph<UniformFanInShape<T,U>,NotUsed>> strategy)	Combines several sources with fan-in strategy like Merge or Concat and returns Source.
<T,U,M1,M2,M> Source<U,M>	combineMat(Source<T,M1> first, Source<T,M2> second, Function<java.lang.Integer,? extends Graph<UniformFanInShape<T,U>,NotUsed>> strategy, Function2<M1,M2,M> combine)	Combines two sources with fan-in strategy like Merge or Concat and returns Source with a materialized value.
<O> Source<O,NotUsed>	cycle(Creator<java.util.Iterator<O>> f)	Helper to create 'cycled' Source from iterator provider.
<O> Source<O,NotUsed>	empty()
<T> Source<T,NotUsed>	empty(java.lang.Class<T> clazz)	Create a Source with no elements.
<T> Source<T,NotUsed>	failed(java.lang.Throwable cause)	Create a Source that immediately ends the stream with the cause failure to every connected Sink.
<O> Source<O,NotUsed>	from(java.lang.Iterable<O> iterable)	Helper to create Source from Iterable.
<O> Source<O,NotUsed>	fromCompletionStage(java.util.concurrent.CompletionStage<O> future)	Starts a new Source from the given CompletionStage.
<O> Source<O,NotUsed>	fromFuture(scala.concurrent.Future<O> future)	Start a new Source from the given Future.
<T,M> Source<T,scala.concurrent.Future<M>>	fromFutureSource(scala.concurrent.Future<? extends Graph<SourceShape<T>,M>> future)	Streams the elements of the given future source once it successfully completes.
<T,M> Source<T,M>	fromGraph(Graph<SourceShape<T>,M> g)	A graph with the shape of a source logically is a source, this method makes it so also in type.
<O> Source<O,NotUsed>	fromIterator(Creator<java.util.Iterator<O>> f)	Helper to create Source from Iterator.
<O> Source<O,NotUsed>	fromPublisher(org.reactivestreams.Publisher<O> publisher)	Helper to create Source from Publisher.
<T,M> Source<T,java.util.concurrent.CompletionStage<M>>	fromSourceCompletionStage(java.util.concurrent.CompletionStage<? extends Graph<SourceShape<T>,M>> completion)	Streams the elements of an asynchronous source once its given CompletionStage completes.
<T,M> Source<T,java.util.concurrent.CompletionStage<M>>	lazily(Creator<Source<T,M>> create)	Creates a Source that is not materialized until there is downstream demand, when the source gets materialized the materialized future is completed with its value, if downstream cancels or fails without any demand the create factory is never called and the materialized CompletionStage is failed.
<T> Source<T,scala.concurrent.Future<NotUsed>>	lazilyAsync(Creator<java.util.concurrent.CompletionStage<T>> create)	Creates a Source from supplied future factory that is not called until downstream demand.
<T> Source<T,java.util.concurrent.CompletableFuture<java.util.Optional<T>>>	maybe()	Create a Source which materializes a CompletableFuture which controls what element will be emitted by the Source.
<T> Source<T,SourceQueueWithComplete<T>>	queue(int bufferSize, OverflowStrategy overflowStrategy)	Creates a Source that is materialized as an SourceQueue.
Source<java.lang.Integer,NotUsed>	range(int start, int end)	Creates Source that represents integer values in range ''[start;end]'', step equals to 1.
Source<java.lang.Integer,NotUsed>	range(int start, int end, int step)	Creates Source that represents integer values in range ''[start;end]'', with the given step.
<T> Source<T,NotUsed>	repeat(T element)	Create a Source that will continually emit the given element.
<T,M> Source<T,java.util.concurrent.CompletionStage<M>>	setup(java.util.function.BiFunction<ActorMaterializer,Attributes,Source<T,M>> factory)	Defers the creation of a Source until materialization.
<T> Source<T,NotUsed>	single(T element)	Create a Source with one element.
<O> Source<O,Cancellable>	tick(java.time.Duration initialDelay, java.time.Duration interval, O tick)	Elements are emitted periodically with the specified interval.
<O> Source<O,Cancellable>	tick(scala.concurrent.duration.FiniteDuration initialDelay, scala.concurrent.duration.FiniteDuration interval, O tick)	Deprecated. Use the overloaded one which accepts java.time.Duration instead.
<S,E> Source<E,NotUsed>	unfold(S s, Function<S,java.util.Optional<Pair<S,E>>> f)	Create a Source that will unfold a value of type S into a pair of the next state S and output elements of type E.
<S,E> Source<E,NotUsed>	unfoldAsync(S s, Function<S,java.util.concurrent.CompletionStage<java.util.Optional<Pair<S,E>>>> f)	Same as <S,E>unfold(S,akka.japi.function.Function<S,java.util.Optional<akka.japi.Pair<S,E>>>), but uses an async function to generate the next state-element tuple.
<T,S> Source<T,NotUsed>	unfoldResource(Creator<S> create, Function<S,java.util.Optional<T>> read, Procedure<S> close)	Start a new Source from some resource which can be opened, read and closed.
<T,S> Source<T,NotUsed>	unfoldResourceAsync(Creator<java.util.concurrent.CompletionStage<S>> create, Function<S,java.util.concurrent.CompletionStage<java.util.Optional<T>>> read, Function<S,java.util.concurrent.CompletionStage<Done>> close)	Start a new Source from some resource which can be opened, read and closed.
<SuperOut,Out extends SuperOut,Mat> Source<SuperOut,Mat>	upcast(Source<Out,Mat> source)	Upcast a stream of elements to a stream of supertypes of that element.
<T> Source<java.util.List<T>,NotUsed>	zipN(java.util.List<Source<T,?>> sources)	Combine the elements of multiple streams into a stream of lists.
<T,O> Source<O,NotUsed>	zipWithN(Function<java.util.List<T>,O> zipper, java.util.List<Source<T,?>> sources)

Methods inherited from class java.lang.Object

clone, equals, finalize, getClass, hashCode, notify, notifyAll, toString, wait, wait, wait

Field Detail

MODULE$

public static final Source$ MODULE$

Static reference to the singleton instance of this Scala object.

Constructor Detail

Source$

public Source$()

Method Detail

empty

public <O> Source<O,NotUsed> empty()

empty

public <T> Source<T,NotUsed> empty(java.lang.Class<T> clazz)

Create a Source with no elements. The result is the same as calling Source.empty()

Parameters:

clazz - (undocumented)

Returns:

(undocumented)

maybe

public <T> Source<T,java.util.concurrent.CompletableFuture<java.util.Optional<T>>> maybe()

Create a Source which materializes a CompletableFuture which controls what element will be emitted by the Source. If the materialized promise is completed with a filled Optional, that value will be produced downstream, followed by completion. If the materialized promise is completed with an empty Optional, no value will be produced downstream and completion will be signalled immediately. If the materialized promise is completed with a failure, then the returned source will terminate with that error. If the downstream of this source cancels before the promise has been completed, then the promise will be completed with an empty Optional.

Returns:

(undocumented)

fromPublisher

public <O> Source<O,NotUsed> fromPublisher(org.reactivestreams.Publisher<O> publisher)

Helper to create Source from Publisher.

Construct a transformation starting with given publisher. The transformation steps are executed by a series of Processor instances that mediate the flow of elements downstream and the propagation of back-pressure upstream.

Parameters:

publisher - (undocumented)

Returns:

(undocumented)

fromIterator

public <O> Source<O,NotUsed> fromIterator(Creator<java.util.Iterator<O>> f)

Helper to create Source from Iterator. Example usage:

 List<Integer> data = new ArrayList<Integer>();
 data.add(1);
 data.add(2);
 data.add(3);
 Source.from(() -> data.iterator());
 

Start a new Source from the given Iterator. The produced stream of elements will continue until the iterator runs empty or fails during evaluation of the next() method. Elements are pulled out of the iterator in accordance with the demand coming from the downstream transformation steps.

Parameters:

f - (undocumented)

Returns:

(undocumented)

cycle

public <O> Source<O,NotUsed> cycle(Creator<java.util.Iterator<O>> f)

Helper to create 'cycled' Source from iterator provider. Example usage:

 Source.cycle(() -> Arrays.asList(1, 2, 3).iterator());
 

Start a new 'cycled' Source from the given elements. The producer stream of elements will continue infinitely by repeating the sequence of elements provided by function parameter.

Parameters:

f - (undocumented)

Returns:

(undocumented)

from

public <O> Source<O,NotUsed> from(java.lang.Iterable<O> iterable)

Helper to create Source from Iterable. Example usage:

 List<Integer> data = new ArrayList<Integer>();
 data.add(1);
 data.add(2);
 data.add(3);
 Source.from(data);
 

Starts a new Source from the given Iterable. This is like starting from an Iterator, but every Subscriber directly attached to the Publisher of this stream will see an individual flow of elements (always starting from the beginning) regardless of when they subscribed.

Make sure that the Iterable is immutable or at least not modified after being used as a Source. Otherwise the stream may fail with ConcurrentModificationException or other more subtle errors may occur.

Parameters:

iterable - (undocumented)

Returns:

(undocumented)

range

public Source<java.lang.Integer,NotUsed> range(int start,
                                                     int end)

Creates Source that represents integer values in range ''[start;end]'', step equals to 1. It allows to create Source out of range as simply as on Scala Source(1 to N)

Uses {@link scala.collection.immutable.Range.inclusive(Int, Int)} internally

Parameters:

start - (undocumented)

end - (undocumented)

Returns:

(undocumented)

range

public Source<java.lang.Integer,NotUsed> range(int start,
                                                     int end,
                                                     int step)

Creates Source that represents integer values in range ''[start;end]'', with the given step. It allows to create Source out of range as simply as on Scala Source(1 to N)

Uses {@link scala.collection.immutable.Range.inclusive(Int, Int, Int)} internally

Parameters:

start - (undocumented)

end - (undocumented)

step - (undocumented)

Returns:

(undocumented)

fromFuture

public <O> Source<O,NotUsed> fromFuture(scala.concurrent.Future<O> future)

Start a new Source from the given Future. The stream will consist of one element when the Future is completed with a successful value, which may happen before or after materializing the Flow. The stream terminates with a failure if the Future is completed with a failure.

Parameters:

future - (undocumented)

Returns:

(undocumented)

fromCompletionStage

public <O> Source<O,NotUsed> fromCompletionStage(java.util.concurrent.CompletionStage<O> future)

Starts a new Source from the given CompletionStage. The stream will consist of one element when the CompletionStage is completed with a successful value, which may happen before or after materializing the Flow. The stream terminates with a failure if the CompletionStage is completed with a failure.

Parameters:

future - (undocumented)

Returns:

(undocumented)

fromFutureSource

public <T,M> Source<T,scala.concurrent.Future<M>> fromFutureSource(scala.concurrent.Future<? extends Graph<SourceShape<T>,M>> future)

Streams the elements of the given future source once it successfully completes. If the Future fails the stream is failed with the exception from the future. If downstream cancels before the stream completes the materialized Future will be failed with a StreamDetachedException.

Parameters:

future - (undocumented)

Returns:

(undocumented)

fromSourceCompletionStage

public <T,M> Source<T,java.util.concurrent.CompletionStage<M>> fromSourceCompletionStage(java.util.concurrent.CompletionStage<? extends Graph<SourceShape<T>,M>> completion)

Streams the elements of an asynchronous source once its given CompletionStage completes. If the CompletionStage fails the stream is failed with the exception from the future. If downstream cancels before the stream completes the materialized CompletionStage will be failed with a StreamDetachedException

Parameters:

completion - (undocumented)

Returns:

(undocumented)

tick

public <O> Source<O,Cancellable> tick(scala.concurrent.duration.FiniteDuration initialDelay,
                                            scala.concurrent.duration.FiniteDuration interval,
                                            O tick)

Deprecated.

Use the overloaded one which accepts java.time.Duration instead. Since 2.5.12.

Elements are emitted periodically with the specified interval. The tick element will be delivered to downstream consumers that has requested any elements. If a consumer has not requested any elements at the point in time when the tick element is produced it will not receive that tick element later. It will receive new tick elements as soon as it has requested more elements.

Parameters:

initialDelay - (undocumented)

interval - (undocumented)

tick - (undocumented)

Returns:

(undocumented)

tick

public <O> Source<O,Cancellable> tick(java.time.Duration initialDelay,
                                            java.time.Duration interval,
                                            O tick)

Elements are emitted periodically with the specified interval. The tick element will be delivered to downstream consumers that has requested any elements. If a consumer has not requested any elements at the point in time when the tick element is produced it will not receive that tick element later. It will receive new tick elements as soon as it has requested more elements.

Parameters:

initialDelay - (undocumented)

interval - (undocumented)

tick - (undocumented)

Returns:

(undocumented)

single

public <T> Source<T,NotUsed> single(T element)

Create a Source with one element. Every connected Sink of this stream will see an individual stream consisting of one element.

Parameters:

element - (undocumented)

Returns:

(undocumented)

repeat

public <T> Source<T,NotUsed> repeat(T element)

Create a Source that will continually emit the given element.

Parameters:

element - (undocumented)

Returns:

(undocumented)

unfold

public <S,E> Source<E,NotUsed> unfold(S s,
                                                  Function<S,java.util.Optional<Pair<S,E>>> f)

Create a Source that will unfold a value of type S into a pair of the next state S and output elements of type E.

Parameters:

s - (undocumented)

f - (undocumented)

Returns:

(undocumented)

unfoldAsync

public <S,E> Source<E,NotUsed> unfoldAsync(S s,
                                                       Function<S,java.util.concurrent.CompletionStage<java.util.Optional<Pair<S,E>>>> f)

Same as <S,E>unfold(S,akka.japi.function.Function<S,java.util.Optional<akka.japi.Pair<S,E>>>), but uses an async function to generate the next state-element tuple.

Parameters:

s - (undocumented)

f - (undocumented)

Returns:

(undocumented)

failed

public <T> Source<T,NotUsed> failed(java.lang.Throwable cause)

Create a Source that immediately ends the stream with the cause failure to every connected Sink.

Parameters:

cause - (undocumented)

Returns:

(undocumented)

lazily

public <T,M> Source<T,java.util.concurrent.CompletionStage<M>> lazily(Creator<Source<T,M>> create)

Creates a Source that is not materialized until there is downstream demand, when the source gets materialized the materialized future is completed with its value, if downstream cancels or fails without any demand the create factory is never called and the materialized CompletionStage is failed.

Parameters:

create - (undocumented)

Returns:

(undocumented)

lazilyAsync

public <T> Source<T,scala.concurrent.Future<NotUsed>> lazilyAsync(Creator<java.util.concurrent.CompletionStage<T>> create)

Creates a Source from supplied future factory that is not called until downstream demand. When source gets materialized the materialized future is completed with the value from the factory. If downstream cancels or fails without any demand the create factory is never called and the materialized Future is failed.

Parameters:

create - (undocumented)

Returns:

(undocumented)

See Also:

Source.lazily

asSubscriber

public <T> Source<T,org.reactivestreams.Subscriber<T>> asSubscriber()

Creates a Source that is materialized as a Subscriber

Returns:

(undocumented)

actorPublisher

public <T> Source<T,ActorRef> actorPublisher(Props props)

Deprecated.

Use akka.stream.stage.GraphStage and fromGraph instead, it allows for all operations an Actor would and is more type-safe as well as guaranteed to be ReactiveStreams compliant.

Creates a Source that is materialized to an ActorRef which points to an Actor created according to the passed in Props. Actor created by the props should be ActorPublisher.

Parameters:

props - (undocumented)

Returns:

(undocumented)

actorRef

public <T> Source<T,ActorRef> actorRef(int bufferSize,
                                             OverflowStrategy overflowStrategy)

Creates a Source that is materialized as an ActorRef. Messages sent to this actor will be emitted to the stream if there is demand from downstream, otherwise they will be buffered until request for demand is received.

Depending on the defined OverflowStrategy it might drop elements if there is no space available in the buffer.

The strategy akka.stream.OverflowStrategy.backpressure is not supported, and an IllegalArgument("Backpressure overflowStrategy not supported") will be thrown if it is passed as argument.

The buffer can be disabled by using bufferSize of 0 and then received messages are dropped if there is no demand from downstream. When bufferSize is 0 the overflowStrategy does not matter. An async boundary is added after this Source; as such, it is never safe to assume the downstream will always generate demand.

The stream can be completed successfully by sending the actor reference a Status.Success (whose content will be ignored) in which case already buffered elements will be signaled before signaling completion.

The stream can be completed successfully by sending the actor reference a Status.Success. If the content is akka.stream.CompletionStrategy.immediately the completion will be signaled immidiately, otherwise if the content is akka.stream.CompletionStrategy.draining (or anything else) already buffered elements will be signaled before siganling completion. Sending PoisonPill will signal completion immediately but this behavior is deprecated and scheduled to be removed.

The stream can be completed with failure by sending a Status.Failure to the actor reference. In case the Actor is still draining its internal buffer (after having received a Status.Success) before signaling completion and it receives a Status.Failure, the failure will be signaled downstream immediately (instead of the completion signal).

Note that terminating the actor without first completing it, either with a success or a failure, will prevent the actor triggering downstream completion and the stream will continue to run even though the source actor is dead. Therefore you should **not** attempt to manually terminate the actor such as with a PoisonPill.

The actor will be stopped when the stream is completed, failed or canceled from downstream, i.e. you can watch it to get notified when that happens.

See also akka.stream.javadsl.Source.queue.

Parameters:

bufferSize - The size of the buffer in element count

overflowStrategy - Strategy that is used when incoming elements cannot fit inside the buffer

Returns:

(undocumented)

actorRefWithAck

public <T> Source<T,ActorRef> actorRefWithAck(java.lang.Object ackMessage)

Creates a Source that is materialized as an ActorRef. Messages sent to this actor will be emitted to the stream if there is demand from downstream, and a new message will only be accepted after the previous messages has been consumed and acknowledged back. The stream will complete with failure if a message is sent before the acknowledgement has been replied back.

The stream can be completed successfully by sending the actor reference a Status.Success. If the content is akka.stream.CompletionStrategy.immediately the completion will be signaled immidiately, otherwise if the content is akka.stream.CompletionStrategy.draining (or anything else) already buffered element will be signaled before siganling completion.

The stream can be completed with failure by sending a Status.Failure to the actor reference. In case the Actor is still draining its internal buffer (after having received a Status.Success) before signaling completion and it receives a Status.Failure, the failure will be signaled downstream immediately (instead of the completion signal).

The actor will be stopped when the stream is completed, failed or canceled from downstream, i.e. you can watch it to get notified when that happens.

Parameters:

ackMessage - (undocumented)

Returns:

(undocumented)

fromGraph

public <T,M> Source<T,M> fromGraph(Graph<SourceShape<T>,M> g)

A graph with the shape of a source logically is a source, this method makes it so also in type.

Parameters:

g - (undocumented)

Returns:

(undocumented)

setup

public <T,M> Source<T,java.util.concurrent.CompletionStage<M>> setup(java.util.function.BiFunction<ActorMaterializer,Attributes,Source<T,M>> factory)

Defers the creation of a Source until materialization. The factory function exposes ActorMaterializer which is going to be used during materialization and Attributes of the Source returned by this method.

Parameters:

factory - (undocumented)

Returns:

(undocumented)

combine

public <T,U> Source<U,NotUsed> combine(Source<T,?> first,
                                                   Source<T,?> second,
                                                   java.util.List<Source<T,?>> rest,
                                                   Function<java.lang.Integer,? extends Graph<UniformFanInShape<T,U>,NotUsed>> strategy)

Combines several sources with fan-in strategy like Merge or Concat and returns Source.

Parameters:

first - (undocumented)

second - (undocumented)

rest - (undocumented)

strategy - (undocumented)

Returns:

(undocumented)

combineMat

public <T,U,M1,M2,M> Source<U,M> combineMat(Source<T,M1> first,
                                                                          Source<T,M2> second,
                                                                          Function<java.lang.Integer,? extends Graph<UniformFanInShape<T,U>,NotUsed>> strategy,
                                                                          Function2<M1,M2,M> combine)

Combines two sources with fan-in strategy like Merge or Concat and returns Source with a materialized value.

Parameters:

first - (undocumented)

second - (undocumented)

strategy - (undocumented)

combine - (undocumented)

Returns:

(undocumented)

zipN

public <T> Source<java.util.List<T>,NotUsed> zipN(java.util.List<Source<T,?>> sources)

Combine the elements of multiple streams into a stream of lists.

Parameters:

sources - (undocumented)

Returns:

(undocumented)

zipWithN

public <T,O> Source<O,NotUsed> zipWithN(Function<java.util.List<T>,O> zipper,
                                                    java.util.List<Source<T,?>> sources)

queue

public <T> Source<T,SourceQueueWithComplete<T>> queue(int bufferSize,
                                                            OverflowStrategy overflowStrategy)

Creates a Source that is materialized as an SourceQueue. You can push elements to the queue and they will be emitted to the stream if there is demand from downstream, otherwise they will be buffered until request for demand is received. Elements in the buffer will be discarded if downstream is terminated.

Depending on the defined OverflowStrategy it might drop elements if there is no space available in the buffer.

Acknowledgement mechanism is available. akka.stream.javadsl.SourceQueue.offer returns CompletionStage which completes with QueueOfferResult.enqueued if element was added to buffer or sent downstream. It completes with QueueOfferResult.dropped if element was dropped. Can also complete with QueueOfferResult.Failure - when stream failed or QueueOfferResult.QueueClosed when downstream is completed.

The strategy akka.stream.OverflowStrategy.backpressure will not complete last offer():CompletionStage call when buffer is full.

You can watch accessibility of stream with akka.stream.javadsl.SourceQueue.watchCompletion. It returns a future that completes with success when this operator is completed or fails when stream is failed.

The buffer can be disabled by using bufferSize of 0 and then received message will wait for downstream demand unless there is another message waiting for downstream demand, in that case offer result will be completed according to the overflow strategy.

SourceQueue that current source is materialized to is for single thread usage only.

Parameters:

bufferSize - size of buffer in element count

overflowStrategy - Strategy that is used when incoming elements cannot fit inside the buffer

Returns:

(undocumented)

unfoldResource

public <T,S> Source<T,NotUsed> unfoldResource(Creator<S> create,
                                                          Function<S,java.util.Optional<T>> read,
                                                          Procedure<S> close)

Start a new Source from some resource which can be opened, read and closed. Interaction with resource happens in a blocking way.

Example:

 Source.unfoldResource(
   () -> new BufferedReader(new FileReader("...")),
   reader -> reader.readLine(),
   reader -> reader.close())
 

You can use the supervision strategy to handle exceptions for read function. All exceptions thrown by create or close will fail the stream.

Restart supervision strategy will close and create blocking IO again. Default strategy is Stop which means that stream will be terminated on error in read function by default.

You can configure the default dispatcher for this Source by changing the akka.stream.materializer.blocking-io-dispatcher or set it for a given Source by using ActorAttributes.

Adheres to the ActorAttributes.SupervisionStrategy attribute.

Parameters:

create - - function that is called on stream start and creates/opens resource.

read - - function that reads data from opened resource. It is called each time backpressure signal is received. Stream calls close and completes when read returns None.

close - - function that closes resource

Returns:

(undocumented)

unfoldResourceAsync

public <T,S> Source<T,NotUsed> unfoldResourceAsync(Creator<java.util.concurrent.CompletionStage<S>> create,
                                                               Function<S,java.util.concurrent.CompletionStage<java.util.Optional<T>>> read,
                                                               Function<S,java.util.concurrent.CompletionStage<Done>> close)

Start a new Source from some resource which can be opened, read and closed. It's similar to unfoldResource but takes functions that return CompletionStage instead of plain values.

You can use the supervision strategy to handle exceptions for read function or failures of produced Futures. All exceptions thrown by create or close as well as fails of returned futures will fail the stream.

Restart supervision strategy will close and create resource. Default strategy is Stop which means that stream will be terminated on error in read function (or future) by default.

You can configure the default dispatcher for this Source by changing the akka.stream.materializer.blocking-io-dispatcher or set it for a given Source by using ActorAttributes.

Adheres to the ActorAttributes.SupervisionStrategy attribute.

Parameters:

create - - function that is called on stream start and creates/opens resource.

read - - function that reads data from opened resource. It is called each time backpressure signal is received. Stream calls close and completes when CompletionStage from read function returns None.

close - - function that closes resource

Returns:

(undocumented)

upcast

public <SuperOut,Out extends SuperOut,Mat> Source<SuperOut,Mat> upcast(Source<Out,Mat> source)

Upcast a stream of elements to a stream of supertypes of that element. Useful in combination with fan-in operators where you do not want to pay the cost of casting each element in a map.

Example:

 Source<Apple, NotUsed> apples = Source.single(new Apple());
 Source<Orange, NotUsed> oranges = Source.single(new Orange());
 Source<Fruit, NotUsed> appleFruits = Source.upcast(apples);
 Source<Fruit, NotUsed> orangeFruits = Source.upcast(oranges);

 Source<Fruit, NotUsed> fruits = appleFruits.merge(orangeFruits);
 

Parameters:

source - (undocumented)

Returns:

A source with the supertype as elements