package docs import java.io.File import akka.http.scaladsl.model.Uri import akka.stream.scaladsl._ import akka.stream._ import akka.stream.stage.{ OutHandler, InHandler, GraphStageLogic, GraphStage } import akka.stream.testkit.AkkaSpec import scala.concurrent.{ Future, ExecutionContext, Promise } import scala.concurrent.duration._ import scala.util.{ Failure, Success, Try } class MigrationsScala extends AkkaSpec { "Examples in migration guide" must { "compile" in { val flow1 = Flow[Int] val flow2 = Flow[Int] def inlet: Inlet[Int] = ??? def outlet: Outlet[Int] = ??? def inlet1: Inlet[Int] = ??? def outlet1: Outlet[Int] = ??? def inlet2: Inlet[Int] = ??? def outlet2: Outlet[Int] = ??? lazy val dontExecuteMe = { //#flow-wrap val graphSource: Graph[SourceShape[Int], Unit] = ??? val source: Source[Int, Unit] = Source.fromGraph(graphSource) val graphSink: Graph[SinkShape[Int], Unit] = ??? val sink: Sink[Int, Unit] = Sink.fromGraph(graphSink) val graphFlow: Graph[FlowShape[Int, Int], Unit] = ??? val flow: Flow[Int, Int, Unit] = Flow.fromGraph(graphFlow) Flow.fromSinkAndSource(Sink.head[Int], Source.single(0)) //#flow-wrap //#bidiflow-wrap val bidiGraph: Graph[BidiShape[Int, Int, Int, Int], Unit] = ??? val bidi: BidiFlow[Int, Int, Int, Int, Unit] = BidiFlow.fromGraph(bidiGraph) BidiFlow.fromFlows(flow1, flow2) BidiFlow.fromFunctions((x: Int) => x + 1, (y: Int) => y * 3) //#bidiflow-wrap //#graph-create // Replaces FlowGraph.closed() FlowGraph.create() { builder => //... ClosedShape } // Replaces FlowGraph.partial() FlowGraph.create() { builder => //... FlowShape(inlet, outlet) } //#graph-create //#graph-create-2 Source.fromGraph( FlowGraph.create() { builder => //... SourceShape(outlet) }) Sink.fromGraph( FlowGraph.create() { builder => //... SinkShape(inlet) }) Flow.fromGraph( FlowGraph.create() { builder => //... FlowShape(inlet, outlet) }) BidiFlow.fromGraph( FlowGraph.create() { builder => //... BidiShape(inlet1, outlet1, inlet2, outlet2) }) //#graph-create-2 //#graph-edges RunnableGraph.fromGraph( FlowGraph.create() { implicit builder => import FlowGraph.Implicits._ outlet ~> inlet outlet ~> flow ~> inlet //... ClosedShape }) //#graph-edges val promise = Promise[Unit]() //#source-creators val src: Source[Int, Promise[Option[Int]]] = Source.maybe[Int] //... // This finishes the stream without emitting anything, just like Source.lazyEmpty did promise.trySuccess(Some(())) val ticks = Source.tick(1.second, 3.seconds, "tick") //#source-creators //#flatMapConcat Flow[Source[Int, Any]].flatMapConcat(identity) //#flatMapConcat //#port-async class MapAsyncOne[In, Out](f: In ⇒ Future[Out])(implicit ec: ExecutionContext) extends GraphStage[FlowShape[In, Out]] { val in: Inlet[In] = Inlet("MapAsyncOne.in") val out: Outlet[Out] = Outlet("MapAsyncOne.out") override val shape: FlowShape[In, Out] = FlowShape(in, out) // The actual logic is encapsulated in a GraphStageLogic now override def createLogic(inheritedAttributes: Attributes): GraphStageLogic = new GraphStageLogic(shape) { // All of the state *must* be encapsulated in the GraphStageLogic, // not in the GraphStage private var elemInFlight: Out = _ val callback = getAsyncCallback(onAsyncInput) var holdingUpstream = false // All upstream related events now are handled in an InHandler instance setHandler(in, new InHandler { // No context or element parameter for onPush override def onPush(): Unit = { // The element is not passed as an argument but needs to be dequeued explicitly val elem = grab(in) val future = f(elem) future.onComplete(callback.invoke) // ctx.holdUpstream is no longer needed, but we need to track the state holdingUpstream = true } // No context parameter override def onUpstreamFinish(): Unit = { if (holdingUpstream) absorbTermination() else completeStage() // ctx.finish turns into completeStage() } }) setHandler(out, new OutHandler { override def onPull(): Unit = { if (elemInFlight != null) { val e = elemInFlight elemInFlight = null.asInstanceOf[Out] pushIt(e) } // holdDownstream is no longer needed } }) // absorbTermination turns into the code below. // This emulates the behavior of the AsyncStage stage. private def absorbTermination(): Unit = if (isAvailable(shape.outlet)) getHandler(out).onPull() // The line below emulates the behavior of the AsyncStage holdingDownstream private def holdingDownstream(): Boolean = !(isClosed(in) || hasBeenPulled(in)) // Any method can be used as a callback, we chose the previous name for // easier comparison with the original code private def onAsyncInput(input: Try[Out]) = input match { case Failure(ex) ⇒ failStage(ex) case Success(e) if holdingDownstream() ⇒ pushIt(e) case Success(e) ⇒ elemInFlight = e // ctx.ignore is no longer needed } private def pushIt(elem: Out): Unit = { // ctx.isFinishing turns into isClosed(in) if (isClosed(in)) { // pushAndFinish is now two actions push(out, elem) completeStage() } else { // pushAndPull is now two actions push(out, elem) pull(in) holdingUpstream = false } } } } //#port-async val uri: Uri = ??? //#raw-query val queryPart: Option[String] = uri.rawQueryString //#raw-query //#query-param val param: Option[String] = uri.query().get("a") //#query-param //#file-source-sink val fileSrc = Source.file(new File(".")) val otherFileSrc = Source.file(new File("."), 1024) val someFileSink = Sink.file(new File(".")) //#file-source-sink } } } }