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I am new to Scala and Play; and I wrote a "do all" controller that contains both business and presentation logic. I want to refactor the business logic out of the controller.

Here's what my Scala/Play looks like. What is a good/idiomatic way to refactor out the business logic out of this controller, with a clean interface?

object NodeRender extends Controller {
...
def deleteNode(nodeId: Long) = Action { request =>
    //business logic
    val commitDocument = Json.toJson(
    Map(
        "delete" -> Seq( Map( "id" -> toJson( nodeId)))  
    ))
    val commitSend   = Json.stringify( commitDocument)
    val commitParams = Map( "commit" -> "true", "wt" -> "json")
    val headers = Map( "Content-type" -> "application/json")

    val sol = host( "127.0.0.1", 8080)
    val updateReq  = sol / "solr-store" / "collection1" / "update" / "json" <<?
        commitParams <:< headers << commitSend

    val commitResponse = Http( updateReq)()

    //presentation logic
    Redirect( routes.NodeRender.listNodes)
}

In Python/Django I write two classes XApiHandler and XBackend and use a clean interface between them.

xb = XBackend( user).do_stuff()
if not xb:
  return a_404_error
else:
  return the_right_stuff( xb.content) #please dont assume its a view!
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3 Answers

up vote 7 down vote accepted
+50

A few assumptions:

1) The HTTP call on your second last line blocks

2) You don't say whether the redirect needs to wait for the response from the Http call, but I assume it does.

Blocking call should be moved to another thread so that you aren't blocking threads that handle requests. Play docs are quite specific about this. The Akka.future function combined with Asynchelps.

Controller code:

1 def deleteNode(nodeId: Long) = Action { request =>
2     Async{
3         val response = Akka.future( BusinessService.businessLogic(nodeId) )
4 
5         response.map { result =>
6             result map {
7                 Redirect( routes.NodeRender.listNodes)
8             } recover {
9                 InternalServerError("Failed due to ...")
10            } get 
11        }
12    }
13}

This is a bit more than your PHP, but it is multi-threaded.

The code passed to Akka.future on line 3 will be called at some time in the future using a different thread. But the call to Akka.future returns immediately with a Future[Try] (see below for the return type of the business method). That means the variable response has the type Future[Try]. The call to the map method on line 5 doesn't call the code inside the map block, rather it registers that code (lines 6-10) as a callback. The thread doesn't block on line 5 and returns the Future to the Async block. The Async block returns a AsyncResult to Play and that tells Play to register itself for a callback when the future is completed.

In the mean time, some other thread will make the call to the BusinessService from line 3 and once the HTTP call that you make to the back end system returns, the response variable on line 3 is "completed" meaning that the callback on lines 6-10 gets called. result has the type Try which is abstract and has just two subclasses: Success and Failure. If result is a sucess, then the map method calls line 7 and wraps it in a new Success. If result is a failure, then the map method returns the failure. The recover method on line 8 does the opposite. If the result of the map method is a success, then it returns the success, otherwise it calls line 9 and wraps it in a Success (not a Failure!). The call to the get method on line 10 takes the redirect or the error out of the Success and that value is used to complete the AsyncResult which Play is holding on to. Play then gets a callback that the response is ready and can be rendered and sent.

Using this solution, no threads which service incoming requests get blocked. That's important because for example on a 4 core machine, Play only has 8 threads capable of handling incoming requests. It won't spawn any new ones, at least not when using the default configuration.

Here is the code from the Business Service object (pretty much copied your code):

def businessLogic(nodeId: Long): Future[Try] {

    val commitDocument = Json.toJson(
    Map(
       "delete" -> Seq( Map( "id" -> toJson( nodeId)))  
    ))
    val commitSend   = Json.stringify( commitDocument)
    val commitParams = Map( "commit" -> "true", "wt" -> "json")
    val headers = Map( "Content-type" -> "application/json")

    val sol = host( "127.0.0.1", 8080)
    val updateReq  = sol / "solr-store" / "collection1" / "update" / "json" <<?
        commitParams <:< headers << commitSend

    val commitResponse = Http( updateReq)()

    Success(commitResponse) //return the response or null, doesnt really matter so long as its wrapped in a successful Try 
}

The presentation logic and the business logic are now totally decoupled.

See https://speakerdeck.com/heathermiller/futures-and-promises-in-scala-2-dot-10 and http://docs.scala-lang.org/overviews/core/futures.html for more information.

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How would you test the deleteNode action? –  EECOLOR Mar 10 '13 at 12:18
    
Good question! I guess "BusinessService" shouldn't be an object, then it can be mocked and you can do a test for a positive and a negative result. See playframework.com/documentation/2.1.0/ScalaTest for more details. Or do you mean specifically that different parts run in different threads? –  Ant Kutschera Mar 10 '13 at 16:52
    
Also, Akka.future relies on an instance of the Play application, which can be stubbed for unit testing like this: implicit val application = Application(new File("."), this.getClass.getClassloader, None, Play.Mode.Dev) –  Ant Kutschera Mar 10 '13 at 17:13
    
How would you inject a mock instance into the deleteNode action? –  EECOLOR Mar 10 '13 at 18:38
    
FakeApplication is a bit easier to use for mocking the Application –  EECOLOR Mar 10 '13 at 18:39
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I would probably do it like this

object NodeRenderer extends Controller {

  def listNodes = Action { request =>
    Ok("list")
  }

  def deleteNode(nodeId: Long)(
    implicit nodeService: NodeService = NodeService) = Action { request =>

    Async {
      Future {
        val response = nodeService.deleteNode(nodeId)

        response.apply.fold(
          error => BadRequest(error.message),
          success => Redirect(routes.NodeRenderer.listNodes))
      }
    }
  }
}

The node service file would look something like this

trait NodeService {
  def deleteNode(nodeId: Long): Promise[Either[Error, Success]]
}

object NodeService extends NodeService {

  val deleteDocument =
    (__ \ "delete").write(
      Writes.seq(
        (__ \ "id").write[Long]))

  val commitParams = Map("commit" -> "true", "wt" -> "json")
  val headers = Map("Content-type" -> "application/json")

  def sol = host("127.0.0.1", 8080)
  def baseReq = sol / "solr-store" / "collection1" / "update" / "json" <<?
    commitParams <:< headers

  def deleteNode(nodeId: Long): Promise[Either[Error, Success]] = {

    //business logic
    val commitDocument =
      deleteDocument
        .writes(Seq(nodeId))
        .toString

    val updateReq = baseReq << commitDocument

    Http(updateReq).either.map(
      _.left.map(e => Error(e.getMessage))
        .right.map(r => Success))
  }
}

Where I defined Error and Success like this

case class Error(message: String)
trait Success
case object Success extends Success

This separates your http part and business logic, allowing you to create other types of front-ends for the same service. At the same time it allows you to test your http handling while supplying a mock of the NodeService.

If you need to have different types of NodeService bound to the same controller you might convert the NodeRenderer to a class and pass it in using the constructor. This example shows you how to do that.

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I only added some stuff to make it useful. I moved the static parts to the service so they can be reused by other methods. I added some extra code to give the OP more options for his implementation. I also have the habit of spreading things over more lines to make things more readable. –  EECOLOR Mar 11 '13 at 10:00
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I'm not an expert but I'm pretty happy with factoring out coherent logic blocks into mix-in traits.

abstract class CommonBase {
    def deleteNode(): Unit
}


trait Logic extends CommonBase{
  this: NodeRender =>

  override def deleteNode(): Unit = {
    println("Logic Here")
    println(CoolString)
    }
}

class NodeRender extends CommonBase
    with Logic
{
    val CoolString = "Hello World"

}



object test {
    def main(args: Array[String]) {
      println("starting ...")
      (new NodeRender()).deleteNode()
    }
}

prints

starting ...
Logic Here
Hello World
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