/**
 * Copyright (C) 2009-2011 Scalable Solutions AB <http://scalablesolutions.se>
 */

package akka.tutorial.scala.first

import akka.actor.{Actor, PoisonPill}
import Actor._
import akka.routing.{Routing, CyclicIterator}
import Routing._

import System.{currentTimeMillis => now}
import java.util.concurrent.CountDownLatch

/**
 * First part in Akka tutorial.
 * <p/>
 * Calculates Pi.
 * <p/>
 * Run on command line:
 * <pre>
 *   $ cd akka-1.1
 *   $ export AKKA_HOME=`pwd`
 *   $ scalac -cp dist/akka-actor-1.1-SNAPSHOT.jar Pi.scala
 *   $ java -cp dist/akka-actor-1.1-SNAPSHOT.jar:scala-library.jar:. akka.tutorial.scala.first.Pi
 *   $ ...
 * </pre>
 * <p/>
 * Run it in SBT:
 * <pre>
 *   $ sbt
 *   > update
 *   > console
 *   > akka.tutorial.scala.first.Pi.calculate(nrOfWorkers = 4, nrOfElements = 10000, nrOfMessages = 10000)
 *   > ...
 *   > :quit
 * </pre>
 *
 * @author <a href="http://jonasboner.com">Jonas Bon&#233;r</a>
 */
object Pi extends App {

  calculate(nrOfWorkers = 4, nrOfElements = 10000, nrOfMessages = 10000)

  // ====================
  // ===== Messages =====
  // ====================
  sealed trait PiMessage
  case object Calculate extends PiMessage
  case class Work(start: Int, nrOfElements: Int) extends PiMessage
  case class Result(value: Double) extends PiMessage

  // ==================
  // ===== Worker =====
  // ==================
  class Worker extends Actor {

    // define the work
    def calculatePiFor(start: Int, nrOfElements: Int): Double = {
      var acc = 0.0
      for (i <- start until (start + nrOfElements))
        acc += 4 * math.pow(-1, i) / (2 * i + 1)
      acc
    }

    def receive = {
      case Work(start, nrOfElements) =>
        self reply Result(calculatePiFor(start, nrOfElements)) // perform the work
    }
  }

  // ==================
  // ===== Master =====
  // ==================
  class Master(nrOfWorkers: Int, nrOfMessages: Int, nrOfElements: Int, latch: CountDownLatch)
    extends Actor {

    var pi: Double = _
    var nrOfResults: Int = _
    var start: Long = _

    // create the workers
    val workers = Vector.fill(nrOfWorkers)(actorOf[Worker].start)

    // wrap them with a load-balancing router
    val router = Routing.loadBalancerActor(CyclicIterator(workers)).start

    // message handler
    def receive = {
      case Calculate =>
        // schedule work
        //for (arg <- 0 until nrOfMessages) router ! Work(arg, nrOfElements)
        for (i <- 0 until nrOfMessages) router ! Work(i * nrOfElements, nrOfElements)

        // send a PoisonPill to all workers telling them to shut down themselves
        router ! Broadcast(PoisonPill)

        // send a PoisonPill to the router, telling him to shut himself down
        router ! PoisonPill

      case Result(value) =>
        // handle result from the worker
        pi += value
        nrOfResults += 1
        if (nrOfResults == nrOfMessages) self.stop()
    }

    override def preStart {
      start = now
    }

    override def postStop {
      // tell the world that the calculation is complete
      println("\n\tPi estimate: \t\t%s\n\tCalculation time: \t%s millis".format(pi, (now - start)))
      latch.countDown()
    }
  }

  // ==================
  // ===== Run it =====
  // ==================
  def calculate(nrOfWorkers: Int, nrOfElements: Int, nrOfMessages: Int) {

    // this latch is only plumbing to know when the calculation is completed
    val latch = new CountDownLatch(1)

    // create the master
    val master = actorOf(new Master(nrOfWorkers, nrOfMessages, nrOfElements, latch)).start

    // start the calculation
    master ! Calculate

    // wait for master to shut down
    latch.await()
  }
}