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Overview of built-in stages and their semantics

Overview of Built-In Stages and Their Semantics

Source Stages

These built-in sources are available from akka.stream.scaladsl.Source:

FromEnumerator

Stream the values from an Enumerator, requesting the next value when there is demand. The enumerator will be created anew for each materialization, which is the reason the method takes a function rather than an enumerator directly.

If the enumerator perform blocking operations, make sure to run it on a separate dispatcher.

emits the next value returned from the enumerator

completes when the enumerator reaches its end

From

Stream the values of an IEnumerable<T>.

emits the next value of the enumerable

completes when the last element of the enumerable has been emitted

Never

A source which never emits any elements, never completes and never fails. Useful for tests.

emits never

completes never

Single

Stream a single object

emits the value once

completes when the single value has been emitted

Repeat

Stream a single object repeatedly

emits the same value repeatedly when there is demand

completes never

Cycle

Stream iterator in cycled manner. Internally new iterator is being created to cycle the one provided via argument meaning when original iterator runs out of elements process will start all over again from the beginning of the iterator provided by the evaluation of provided parameter. If method argument provides empty iterator stream will be terminated with exception.

emits the next value returned from cycled iterator

completes never

Tick

A periodical repetition of an arbitrary object. Delay of first tick is specified separately from interval of the following ticks.

emits periodically, if there is downstream backpressure ticks are skipped

completes never

FromTask

Send the single value of the Task when it completes and there is demand. If the task fails the stream is failed with that exception.

emits the task completes

completes after the task has completed

FromTaskSource

Streams the elements of the given Task source once it successfully completes. If the task fails the stream is failed.

emits the next value from the Task source, once it has completed

completes after the Task source completes

Unfold

Stream the result of a function as long as it returns not null, the value inside the option consists of a tuple where the first value is a state passed back into the next call to the function allowing to pass a state. The first invocation of the provided fold function will receive the zero state.

Can be used to implement many stateful sources without having to touch the more low level GraphStage API.

emits when there is demand and the unfold function over the previous state returns non null value

completes when the unfold function returns an null value

UnfoldAsync

Just like Unfold but the fold function returns a Task which will cause the source to complete or emit when it completes.

Can be used to implement many stateful sources without having to touch the more low level GraphStage API.

emits when there is demand and unfold state returned task completes with not null value

completes when the task returned by the unfold function completes with an null value

Empty

Complete right away without ever emitting any elements. Useful when you have to provide a source to an API but there are no elements to emit.

emits never

completes directly

Maybe

Materialize a TaskCompletionSource<T> that if completed with a T will emit that T and then complete the stream, or if completed with null complete the stream right away.

emits when the returned promise is completed with not null value

completes after emitting not null value, or directly if the promise is completed with null value

Failed

Fail directly with a user specified exception.

emits never

completes fails the stream directly with the given exception

Lazily

Defers creation and materialization of a Source until there is demand.

emits depends on the wrapped Source

completes depends on the wrapped Source

ActorPublisher

Wrap an actor extending ActorPublisher as a source.

emits depends on the actor implementation

completes when the actor stops

ActorRef

Materialize an IActorRef, sending messages to it will emit them on the stream. The actor contain a buffer but since communication is one way, there is no back pressure. Handling overflow is done by either dropping elements or failing the stream, the strategy is chosen by the user.

emits when there is demand and there are messages in the buffer or a message is sent to the actorref

completes when the actorref is sent Akka.Actor.Status.Success or PoisonPill

PreMaterialize

Materializes this Source, immediately returning (1) its materialized value, and (2) a new Source that can consume elements 'into' the pre-materialized one.

Useful for when you need a materialized value of a Source when handing it out to someone to materialize it for you.

Combine

Combine several sources, using a given strategy such as merge or concat, into one source.

emits when there is demand, but depending on the strategy

completes when all sources has completed

UnfoldResource

Wrap any resource that can be opened, queried for next element (in a blocking way) and closed using three distinct functions into a source.

emits when there is demand and read function returns value

completes when read function returns None

UnfoldResourceAsync

Wrap any resource that can be opened, queried for next element (in a blocking way) and closed using three distinct functions into a source. Functions return Task to achieve asynchronous processing

emits when there is demand and Task from read function returns value

completes when Task from read function returns None

Queue

Materialize a SourceQueue onto which elements can be pushed for emitting from the source. The queue contains a buffer, if elements are pushed onto the queue faster than the source is consumed the overflow will be handled with a strategy specified by the user. Functionality for tracking when an element has been emitted is available through SourceQueue.Offer.

emits when there is demand and the queue contains elements

completes when downstream completes

AsSubscriber

Integration with Reactive Streams, materializes into a Reactive.Streams.ISubscriber.

FromPublisher

Integration with Reactive Streams, subscribes to a Reactive.Streams.IPublisher.

ZipN

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

emits when all of the inputs has an element available

completes when any upstream completes

ZipWithN

Combine the elements of multiple streams into a stream of sequences using a combiner function.

emits when all of the inputs has an element available

completes when any upstream completes

Sink Stages

These built-in sinks are available from Akka.Stream.DSL.Sink:

First

Materializes into a Task which completes with the first value arriving, after this the stream is canceled. If no element is emitted, the task is be failed.

cancels after receiving one element

backpressures never

FirstOrDefault

Materializes into a Task<T> which completes with the first value arriving, or a default(T) if the stream completes without any elements emitted.

cancels after receiving one element

backpressures never

Last

Materializes into a Task which will complete with the last value emitted when the stream completes. If the stream completes with no elements the task is failed.

cancels never

backpressures never

LastOrDefault

Materialize a Task<T> which completes with the last value emitted when the stream completes. if the stream completes with no elements the task is completed with default(T).

cancels never

backpressures never

Ignore

Consume all elements but discards them. Useful when a stream has to be consumed but there is no use to actually do anything with the elements.

cancels never

backpressures never

Cancelled

Immediately cancel the stream

cancels immediately

Seq

Collect values emitted from the stream into a collection, the collection is available through a Task or which completes when the stream completes. Note that the collection is bounded to int.MaxValue, if more element are emitted the sink will cancel the stream

cancels If too many values are collected

Foreach

Invoke a given procedure for each element received. Note that it is not safe to mutate shared state from the procedure.

The sink materializes into a Task which completes when the stream completes, or fails if the stream fails.

Note that it is not safe to mutate state from the procedure.

cancels never

backpressures when the previous procedure invocation has not yet completed

ForeachParallel

Like Foreach but allows up to parallellism procedure calls to happen in parallel.

cancels never

backpressures when the previous parallel procedure invocations has not yet completed

OnComplete

Invoke a callback when the stream has completed or failed.

cancels never

backpressures never

Aggregate

Fold over emitted element with a function, where each invocation will get the new element and the result from the previous fold invocation. The first invocation will be provided the zero value.

Materializes into a task that will complete with the last state when the stream has completed.

This stage allows combining values into a result without a global mutable state by instead passing the state along between invocations.

cancels never

backpressures when the previous fold function invocation has not yet completed

Sum

Apply a reduction function on the incoming elements and pass the result to the next invocation. The first invocation receives the two first elements of the flow.

Materializes into a task that will be completed by the last result of the reduction function.

cancels never

backpressures when the previous reduction function invocation has not yet completed

Combine

Combine several sinks into one using a user specified strategy

cancels depends on the strategy

backpressures depends on the strategy

ActorRef

Send the elements from the stream to an IActorRef. No backpressure so care must be taken to not overflow the inbox.

cancels when the actor terminates

backpressures never

ActorRefWithAck

Send the elements from the stream to an IActorRef which must then acknowledge reception after completing a message, to provide back pressure onto the sink.

cancels when the actor terminates

backpressures when the actor acknowledgment has not arrived.

PreMaterialize

Materializes this Sink, immediately returning (1) its materialized value, and (2) a new Sink that can consume elements 'into' the pre-materialized one.

Useful for when you need a materialized value of a Sink when handing it out to someone to materialize it for you.

ActorSubscriber

Create an actor from a Props upon materialization, where the actor implements ActorSubscriber, which will receive the elements from the stream.

Materializes into an IActorRef to the created actor.

cancels when the actor terminates

backpressures depends on the actor implementation

AsPublisher

Integration with Reactive Streams, materializes into a Reactive.Streams.IPublisher.

FromSubscriber

Integration with Reactive Streams, wraps a Reactive.Streams.ISubscriber as a sink

Additional Sink and Source Converters

Sources and sinks for integrating with System.IO.Stream can be found on StreamConverters. As they are blocking APIs the implementations of these stages are run on a separate dispatcher configured through the akka.stream.blocking-io-dispatcher.

FromOutputStream

Create a sink that wraps an Stream. Takes a function that produces an Stream, when the sink is materialized the function will be called and bytes sent to the sink will be written to the returned Stream.

Materializes into a Task which will complete with a IOResult when the stream completes.

Note that a flow can be materialized multiple times, so the function producing the Stream must be able to handle multiple invocations.

The Stream will be closed when the stream that flows into the Sink is completed, and the Sink will cancel its inflow when the Stream is no longer writable.

AsInputStream

Create a sink which materializes into an Stream that can be read to trigger demand through the sink. Bytes emitted through the stream will be available for reading through the Stream

The Stream will be ended when the stream flowing into this Sink completes, and the closing the Stream will cancel the inflow of this Sink.

FromInputStream

Create a source that wraps an Stream. Takes a function that produces an Stream, when the source is materialized the function will be called and bytes from the Stream will be emitted into the stream.

Materializes into a Task which will complete with a IOResult when the stream completes.

Note that a flow can be materialized multiple times, so the function producing the Stream must be able to handle multiple invocations.

The Stream will be closed when the Source is canceled from its downstream, and reaching the end of the Stream will complete the Source.

AsOutputStream

Create a source that materializes into an Stream. When bytes are written to the Stream they are emitted from the source

The Stream will no longer be writable when the Source has been canceled from its downstream, and closing the Stream will complete the Source.

LazyInitAsync

Creates a real Sink upon receiving the first element. Internal sink will not be created if there are no elements, because of completion or error.

  • If upstream completes before an element was received then the Task is completed with None.
  • If upstream fails before an element was received, sinkFactory throws an exception, or materialization of the internal sink fails then the Task is completed with the exception.
  • Otherwise the Task is completed with the materialized value of the internal sink.

cancels never

backpressures when initialized and when created sink backpressures

File IO Sinks and Sources

Sources and sinks for reading and writing files can be found on FileIO.

FromFile

Emit the contents of a file, as ByteString s, materializes into a Task which will be completed with a IOResult upon reaching the end of the file or if there is a failure.

ToFile

Create a sink which will write incoming ByteString s to a given file.

Flow Stages

All flows by default backpressure if the computation they encapsulate is not fast enough to keep up with the rate of incoming elements from the preceding stage. There are differences though how the different stages handle when some of their downstream stages backpressure them.

Most stages stop and propagate the failure downstream as soon as any of their upstreams emit a failure. This happens to ensure reliable teardown of streams and cleanup when failures happen. Failures are meant to be to model unrecoverable conditions, therefore they are always eagerly propagated. For in-band error handling of normal errors (dropping elements if a map fails for example) you should use the supervision support, or explicitly wrap your element types in a proper container that can express error or success states (for example try in C#).

Simple Processing Stages

These stages can transform the rate of incoming elements since there are stages that emit multiple elements for a single input (e.g. ConcatMany) or consume multiple elements before emitting one output (e.g. Where). However, these rate transformations are data-driven, i.e. it is the incoming elements that define how the rate is affected. This is in contrast with Backpressure aware stages which can change their processing behavior depending on being backpressured by downstream or not.

AlsoTo

Attaches the given Sink to this Flow, meaning that elements that passes through will also be sent to the Sink.

emits when an element is available and demand exists both from the Sink and the downstream

backpressures when downstream or Sink backpressures

completes when upstream completes

Select

Transform each element in the stream by calling a mapping function with it and passing the returned value downstream.

emits when the mapping function returns an element

backpressures when downstream backpressures

completes when upstream completes

SelectMany

Transform each element into zero or more elements that are individually passed downstream.

emits when the mapping function returns an element or there are still remaining elements from the previously calculated collection

backpressures when downstream backpressures or there are still available elements from the previously calculated collection

completes when upstream completes and all remaining elements has been emitted

StatefulSelectMany

Transform each element into zero or more elements that are individually passed downstream. The difference to SelectMany is that the transformation function is created from a factory for every materialization of the flow.

emits when the mapping function returns an element or there are still remaining elements from the previously calculated collection

backpressures when downstream backpressures or there are still available elements from the previously calculated collection

completes when upstream completes and all remaining elements has been emitted

Where

Filter the incoming elements using a predicate. If the predicate returns true the element is passed downstream, if it returns false the element is discarded.

emits when the given predicate returns true for the element

backpressures when the given predicate returns true for the element and downstream backpressures

completes when upstream completes

Collect

Apply a partial function to each incoming element, if the partial function is defined for a value the returned value is passed downstream. Can often replace Where followed by Select to achieve the same in one single stage.

emits when the provided partial function is defined for the element

backpressures the partial function is defined for the element and downstream backpressures

completes when upstream completes

Grouped

Accumulate incoming events until the specified number of elements have been accumulated and then pass the collection of elements downstream.

emits when the specified number of elements has been accumulated or upstream completed

backpressures when a group has been assembled and downstream backpressures

completes when upstream completes

Sliding

Provide a sliding window over the incoming stream and pass the windows as groups of elements downstream.

Note: the last window might be smaller than the requested size due to end of stream.

emits the specified number of elements has been accumulated or upstream completed

backpressures when a group has been assembled and downstream backpressures

completes when upstream completes

Scan

Emit its current value which starts at zero and then applies the current and next value to the given function emitting the next current value.

Note that this means that scan emits one element downstream before and upstream elements will not be requested until the second element is required from downstream.

emits when the function scanning the element returns a new element

backpressures when downstream backpressures

completes when upstream completes

ScanAsync

Just like Scan but receiving a function that results in a Task to the next value.

emits when the Task resulting from the function scanning the element resolves to the next value

backpressures when downstream backpressures

completes when upstream completes and the last Task is resolved

Aggregate

Start with current value zero and then apply the current and next value to the given function, when upstream complete the current value is emitted downstream.

emits when upstream completes

backpressures when downstream backpressures

completes when upstream completes

AggregateAsync

Just like Aggregate but receiving a function that results in a Task to the next value.

emits when upstream completes and the last Task is resolved

backpressures when downstream backpressures

completes when upstream completes and the last Task is resolved

Skip

Skip n elements and then pass any subsequent element downstream.

emits when the specified number of elements has been skipped already

backpressures when the specified number of elements has been skipped and downstream backpressures

completes when upstream completes

Take

Pass n incoming elements downstream and then complete

emits while the specified number of elements to take has not yet been reached

backpressures when downstream backpressures

completes when the defined number of elements has been taken or upstream completes

TakeWhile

Pass elements downstream as long as a predicate function return true for the element include the element when the predicate first return false and then complete.

emits while the predicate is true and until the first false result

backpressures when downstream backpressures

completes when predicate returned false or upstream completes

SkipWhile

Skip elements as long as a predicate function return true for the element

emits when the predicate returned false and for all following stream elements

backpressures predicate returned false and downstream backpressures

completes when upstream completes

Recover

Allow sending of one last element downstream when a failure has happened upstream.

Throwing an exception inside Recover will be logged on ERROR level automatically.

emits when the element is available from the upstream or upstream is failed and pf returns an element

backpressures when downstream backpressures, not when failure happened

completes when upstream completes or upstream failed with exception pf can handle

RecoverWith

Allow switching to alternative Source when a failure has happened upstream.

Throwing an exception inside RecoverWith will be logged on ERROR level automatically.

emits the element is available from the upstream or upstream is failed and pf returns alternative Source

backpressures downstream backpressures, after failure happened it backpressures to alternative Source

completes upstream completes or upstream failed with exception pf can handle

RecoverWithRetries

RecoverWithRetries allows to switch to alternative Source on flow failure. It will stay in effect after a failure has been recovered up to attempts number of times so that each time there is a failure it is fed into the function and a new Source may be materialized. Note that if you pass in 0, this won't attempt to recover at all. Passing -1 will behave exactly the same as RecoverWith.

Since the underlying failure signal OnError arrives out-of-band, it might jump over existing elements. This stage can recover the failure signal, but not the skipped elements, which will be dropped.

emits when element is available from the upstream or upstream is failed and element is available from alternative Source

backpressures when downstream backpressures

completes when upstream completes or upstream failed with exception function can handle

SelectError

While similar to Recover this stage can be used to transform an error signal to a different one without logging it as an error in the process. So in that sense it is NOT exactly equivalent to Recover(e -> throw e2) since recover would log the e2 error.

Since the underlying failure signal OnError arrives out-of-band, it might jump over existing elements. This stage can recover the failure signal, but not the skipped elements, which will be dropped.

Similarly to Recover throwing an exception inside SelectError will be logged on ERROR level automatically.

emits when element is available from the upstream or upstream is failed and function returns an element

backpressures when downstream backpressures

completes when upstream completes or upstream failed with exception function can handle

Detach

Detach upstream demand from downstream demand without detaching the stream rates.

emits when the upstream stage has emitted and there is demand

backpressures when downstream backpressures

completes when upstream completes

Throttle

Limit the throughput to a specific number of elements per time unit, or a specific total cost per time unit, where a function has to be provided to calculate the individual cost of each element.

emits when upstream emits an element and configured time per each element elapsed

backpressures when downstream backpressures

completes when upstream completes

DivertTo

Each upstream element will either be diverted to the given sink, or the downstream consumer according to the predicate function applied to the element.

emits when the chosen output stops backpressuring and there is an input element available

backpressures when the chosen output backpressures

completes when upstream completes and no output is pending

WireTap

Attaches the given Sink to this Flow as a wire tap, meaning that elements that pass through will also be sent to the wire-tap Sink, without the latter affecting the mainline flow.

If the wire-tap Sink backpressures, elements that would've been sent to it will be dropped instead.

emits when element is available and demand exists from the downstream; the element will also be sent to the wire-tap Sink if there is demand.

backpressures when downstream backpressures

completes when upstream completes

cancels when downstream cancels

LazyInitAsync

Creates a real Flow upon receiving the first element by calling relevant flowFactory given as an argument. Internal flow will not be created if there are no elements, because of completion or error. The materialized value of the Flow will be the materialized value of the created internal flow.

The materialized value of the Flow is a Task<Option<TMat>> that is completed with TMat when the internal flow gets materialized or with None when there where no elements. If the flow materialization (including the call of the flowFactory) fails then the future is completed with a failure.

Adheres to the ActorAttributes.SupervisionStrategy attribute.

emits when the internal flow is successfully created and it emits

backpressures when the internal flow is successfully created and it backpressures

completes when upstream completes and all elements have been emitted from the internal flow

completes when upstream completes and all futures have been completed and all elements have been emitted

Asynchronous Processing Stages

These stages encapsulate an asynchronous computation, properly handling backpressure while taking care of the asynchronous operation at the same time (usually handling the completion of a Task).

SelectAsync

Pass incoming elements to a function that return a Task result. When the task arrives the result is passed downstream. Up to n elements can be processed concurrently, but regardless of their completion time the incoming order will be kept when results complete. For use cases where order does not matter SelectAsyncUnordered can be used.

If a Task fails, the stream also fails (unless a different supervision strategy is applied)

emits when the Task returned by the provided function finishes for the next element in sequence

backpressures when the number of tasks reaches the configured parallelism and the downstream backpressures

completes when upstream completes and all tasks has been completed and all elements has been emitted

SelectAsyncUnordered

Like SelectAsync but Task results are passed downstream as they arrive regardless of the order of the elements that triggered them.

If a Task fails, the stream also fails (unless a different supervision strategy is applied)

emits any of the tasks returned by the provided function complete

backpressures when the number of tasks reaches the configured parallelism and the downstream backpressures

completes upstream completes and all tasks has been completed and all elements has been emitted

Timer Driven Stages

These stages process elements using timers, delaying, dropping or grouping elements for certain time durations.

TakeWithin

Pass elements downstream within a timeout and then complete.

emits when an upstream element arrives

backpressures downstream backpressures

completes upstream completes or timer fires

SkipWithin

Skip elements until a timeout has fired

emits after the timer fired and a new upstream element arrives

backpressures when downstream backpressures

completes upstream completes

GroupedWithin

Chunk up the stream into groups of elements received within a time window, or limited by the given number of elements, whichever happens first.

emits when the configured time elapses since the last group has been emitted

backpressures when the group has been assembled (the duration elapsed) and downstream backpressures

completes when upstream completes

InitialDelay

Delay the initial element by a user specified duration from stream materialization.

emits upstream emits an element if the initial delay already elapsed

backpressures downstream backpressures or initial delay not yet elapsed

completes when upstream completes

Delay

Delay every element passed through with a specific duration.

emits there is a pending element in the buffer and configured time for this element elapsed

backpressures differs, depends on OverflowStrategy set

completes when upstream completes and buffered elements has been drained

Backpressure Aware Stages

These stages are aware of the backpressure provided by their downstreams and able to adapt their behavior to that signal.

Conflate

Allow for a slower downstream by passing incoming elements and a summary into an aggregate function as long as there is backpressure. The summary value must be of the same type as the incoming elements, for example the sum or average of incoming numbers, if aggregation should lead to a different type ConflateWithSeed can be used:

emits when downstream stops backpressuring and there is a conflated element available

backpressures when the aggregate function cannot keep up with incoming elements

completes when upstream completes

ConflateWithSeed

Allow for a slower downstream by passing incoming elements and a summary into an aggregate function as long as there is backpressure. When backpressure starts or there is no backpressure element is passed into a seed function to transform it to the summary type.

emits when downstream stops backpressuring and there is a conflated element available

backpressures when the aggregate or seed functions cannot keep up with incoming elements

completes when upstream completes

Batch

Allow for a slower downstream by passing incoming elements and a summary into an aggregate function as long as there is backpressure and a maximum number of batched elements is not yet reached. When the maximum number is reached and downstream still backpressures batch will also backpressure.

When backpressure starts or there is no backpressure element is passed into a seed function to transform it to the summary type.

Will eagerly pull elements, this behavior may result in a single pending (i.e. buffered) element which cannot be aggregated to the batched value.

emits when downstream stops backpressuring and there is a batched element available

backpressures when batched elements reached the max limit of allowed batched elements & downstream backpressures

completes when upstream completes and a "possibly pending" element was drained

BatchWeighted

Allow for a slower downstream by passing incoming elements and a summary into an aggregate function as long as there is backpressure and a maximum weight batched elements is not yet reached. The weight of each element is determined by applying costFunction. When the maximum total weight is reached and downstream still backpressures batch will also backpressure.

Will eagerly pull elements, this behavior may result in a single pending (i.e. buffered) element which cannot be aggregated to the batched value.

emits downstream stops backpressuring and there is a batched element available

backpressures batched elements reached the max weight limit of allowed batched elements & downstream backpressures

completes upstream completes and a "possibly pending" element was drained

Expand

Allow for a faster downstream by expanding the last incoming element to an Enumerator

emits when downstream stops backpressuring

backpressures when downstream backpressures

completes when upstream completes

Buffer (Backpressure)

Allow for a temporarily faster upstream events by buffering size elements. When the buffer is full backpressure is applied.

emits when downstream stops backpressuring and there is a pending element in the buffer

backpressures when buffer is full

completes when upstream completes and buffered elements has been drained

Buffer (Drop)

Allow for a temporarily faster upstream events by buffering size elements. When the buffer is full elements are dropped according to the specified OverflowStrategy:

  • dropHead drops the oldest element in the buffer to make space for the new element
  • dropTail drops the youngest element in the buffer to make space for the new element
  • dropBuffer drops the entire buffer and buffers the new element
  • dropNew drops the new element

emits when downstream stops backpressuring and there is a pending element in the buffer

backpressures never (when dropping cannot keep up with incoming elements)

completes upstream completes and buffered elements has been drained

Buffer (Fail)

Allow for a temporarily faster upstream events by buffering size elements. When the buffer is full the stage fails the flow with a BufferOverflowException.

emits when downstream stops backpressuring and there is a pending element in the buffer

backpressures never, fails the stream instead of backpressuring when buffer is full

completes when upstream completes and buffered elements has been drained

Nesting and Flattening Stages

These stages either take a stream and turn it into a stream of streams (nesting) or they take a stream that contains nested streams and turn them into a stream of elements instead (flattening).

PrefixAndTail

Take up to n elements from the stream (less than n only if the upstream completes before emitting n elements) and returns a pair containing a strict sequence of the taken element and a stream representing the remaining elements.

emits when the configured number of prefix elements are available. Emits this prefix, and the rest as a substream

backpressures when downstream backpressures or substream backpressures

completes when prefix elements has been consumed and substream has been consumed

GroupBy

This operation demultiplexes the incoming stream into separate output streams, one for each element key. The key is computed for each element using the given function. When a new key is encountered for the first time a new substream is opened and subsequently fed with all elements belonging to that key.

Note

If allowClosedSubstreamRecreation is set to true substream completion and incoming elements are subject to race-conditions. If elements arrive for a stream that is in the process of closing these elements might get lost.

Warning

If allowClosedSubstreamRecreation is set to false (default behavior) the stage keeps track of all keys of streams that have already been closed. If you expect an infinite number of keys this can cause memory issues. Elements belonging to those keys are drained directly and not send to the substream.

emits an element for which the grouping function returns a group that has not yet been created. Emits the new group there is an element pending for a group whose substream backpressures

completes when upstream completes (Until the end of stream it is not possible to know whether new substreams will be needed or not)

SplitWhen

Split off elements into a new substream whenever a predicate function return true.

emits an element for which the provided predicate is true, opening and emitting a new substream for subsequent elements

backpressures when there is an element pending for the next substream, but the previous is not fully consumed yet, or the substream backpressures

completes when upstream completes (Until the end of stream it is not possible to know whether new substreams will be needed or not)

SplitAfter

End the current substream whenever a predicate returns true, starting a new substream for the next element.

emits when an element passes through. When the provided predicate is true it emits the element * and opens a new substream for subsequent element

backpressures when there is an element pending for the next substream, but the previous is not fully consumed yet, or the substream backpressures

completes when upstream completes (Until the end of stream it is not possible to know whether new substreams will be needed or not)

ConcatMany

Transform each input element into a Source whose elements are then flattened into the output stream through concatenation. This means each source is fully consumed before consumption of the next source starts.

emits when the current consumed substream has an element available

backpressures when downstream backpressures

completes when upstream completes and all consumed substreams complete

MergeMany

Transform each input element into a Source whose elements are then flattened into the output stream through merging. The maximum number of merged sources has to be specified.

emits when one of the currently consumed substreams has an element available

backpressures when downstream backpressures

completes when upstream completes and all consumed substreams complete

Time Aware Stages

Those stages operate taking time into consideration.

InitialTimeout

If the first element has not passed through this stage before the provided timeout, the stream is failed with a TimeoutException.

emits when upstream emits an element

backpressures when downstream backpressures

completes when upstream completes or fails if timeout elapses before first element arrives

cancels when downstream cancels

CompletionTimeout

If the completion of the stream does not happen until the provided timeout, the stream is failed with a TimeoutException.

emits when upstream emits an element

backpressures when downstream backpressures

completes when upstream completes or fails if timeout elapses before upstream completes

cancels when downstream cancels

IdleTimeout

If the time between two processed elements exceeds the provided timeout, the stream is failed with a TimeoutException. The timeout is checked periodically, so the resolution of the check is one period (equals to timeout value).

emits when upstream emits an element

backpressures when downstream backpressures

completes when upstream completes or fails if timeout elapses between two emitted elements

cancels when downstream cancels

BackpressureTimeout

If the time between the emission of an element and the following downstream demand exceeds the provided timeout, the stream is failed with a TimeoutException. The timeout is checked periodically, so the resolution of the check is one period (equals to timeout value).

emits when upstream emits an element

backpressures when downstream backpressures

completes when upstream completes or fails if timeout elapses between element emission and downstream demand.

cancels when downstream cancels

KeepAlive

Injects additional (configured) elements if upstream does not emit for a configured amount of time.

emits when upstream emits an element or if the upstream was idle for the configured period

backpressures when downstream backpressures

completes when upstream completes

cancels when downstream cancels

InitialDelay

Delays the initial element by the specified duration.

emits when upstream emits an element if the initial delay is already elapsed

backpressures when downstream backpressures or initial delay is not yet elapsed

completes when upstream completes

cancels when downstream cancels

Fan-In Stages

These stages take multiple streams as their input and provide a single output combining the elements from all of the inputs in different ways.

Merge

Merge multiple sources. Picks elements randomly if all sources has elements ready.

emits when one of the inputs has an element available

backpressures when downstream backpressures

completes when all upstreams complete (This behavior is changeable to completing when any upstream completes by setting eagerComplete=true.)

MergeSorted

Merge multiple sources. Waits for one element to be ready from each input stream and emits the smallest element.

emits when all of the inputs have an element available

backpressures when downstream backpressures

completes when all upstreams complete

MergePreferred

Merge multiple sources. Prefer one source if all sources has elements ready.

emits when one of the inputs has an element available, preferring a defined input if multiple have elements available

backpressures when downstream backpressures

completes when all upstreams complete (This behavior is changeable to completing when any upstream completes by setting eagerComplete=true.)

MergePrioritized

Merge multiple sources. Prefer sources depending on priorities if all sources has elements ready. If a subset of all sources has elements ready the relative priorities for those sources are used to prioritize.

emits when one of the inputs has an element available, preferring inputs based on their priorities if multiple have elements available

backpressures when downstream backpressures

completes when all upstreams complete (This behavior is changeable to completing when any upstream completes by setting eagerComplete=true.)

Zip

Combines elements from each of multiple sources into tuples and passes the tuples downstream.

emits when all of the inputs have an element available

backpressures when downstream backpressures

completes when any upstream completes

ZipWith

Combines elements from multiple sources through a combine function and passes the returned value downstream.

emits when all of the inputs have an element available

backpressures when downstream backpressures

completes when any upstream completes

ZipWithIndex

Zips elements of current flow with its indices.

emits when upstream emits an element and is paired with their index

backpressures when downstream backpressures

completes when any upstream completes

Concat

After completion of the original upstream the elements of the given source will be emitted.

emits when the current stream has an element available; if the current input completes, it tries the next one

backpressures when downstream backpressures

completes when all upstreams complete

Prepend

Prepends the given source to the flow, consuming it until completion before the original source is consumed.

If materialized values needs to be collected prependMat is available.

emits when the given stream has an element available; if the given input completes, it tries the current one

backpressures when downstream backpressures

completes when all upstreams complete

OrElse

If the primary source completes without emitting any elements, the elements from the secondary source are emitted. If the primary source emits any elements the secondary source is cancelled.

Note that both sources are materialized directly and the secondary source is backpressured until it becomes the source of elements or is cancelled.

Signal errors downstream, regardless which of the two sources emitted the error.

emits when an element is available from first stream or first stream closed without emitting any elements and an element is available from the second stream

backpressures when downstream backpressures

completes the primary stream completes after emitting at least one element, when the primary stream completes without emitting and the secondary stream already has completed or when the secondary stream completes

Interleave

Emits a specifiable number of elements from the original source, then from the provided source and repeats. If one source completes the rest of the other stream will be emitted.

emits when element is available from the currently consumed upstream

backpressures when upstream backpressures

completes when both upstreams have completed

Fan-Out Stages

These have one input and multiple outputs. They might route the elements between different outputs, or emit elements on multiple outputs at the same time.

Unzip

Takes a stream of two element tuples and unzips the two elements into two different downstreams.

emits when all of the outputs stops backpressuring and there is an input element available

backpressures when any of the outputs backpressures

completes when upstream completes

UnzipWith

Splits each element of input into multiple downstreams using a function

emits when all of the outputs stops backpressuring and there is an input element available

backpressures when any of the outputs backpressures

completes when upstream completes

Broadcast

Emit each incoming element each of n outputs.

emits when all of the outputs stops backpressuring and there is an input element available

backpressures when any of the outputs backpressures

completes when upstream completes

Balance

Fan-out the stream to several streams. Each upstream element is emitted to the first available downstream consumer.

emits when any of the outputs stops backpressuring; emits the element to the first available output

backpressures when all of the outputs backpressure

completes when upstream completes

Partition

Fan-out the stream to several streams. emitting an incoming upstream element to one downstream consumer according to the partitioner function applied to the element

emits when an element is available from the input and the chosen output has demand

backpressures when the currently chosen output back-pressures

completes when upstream completes and no output is pending

cancels when when all downstreams cancel

Watching Status Stages

WatchTermination

Materializes to a Task that will be completed with Done or failed depending whether the upstream of the stage has been completed or failed. The stage otherwise passes through elements unchanged.

emits when input has an element available

backpressures when output backpressures

completes when upstream completes

Monitor

Materializes to a FlowMonitor that monitors messages flowing through or completion of the stage. The stage otherwise passes through elements unchanged. Note that the FlowMonitor inserts a memory barrier every time it processes an event, and may therefore affect performance.

emits when upstream emits an element

backpressures when downstream backpressures

completes when upstream completes