nataren/asyncParallel

## asyncParallel
// Creating new threads
open System
open System.Threading

//What will execute on each thread
let threadBody() =
    for i in 1..5 do
        //Wait 1/10 of a second
        Thread.Sleep(100)
        printfn "[Thread %d] %d ..."
            Thread.CurrentThread.ManagedThreadId i

let spawnThread() =
    let thread = new Thread(threadBody)
    thread.Start()

// spawn a few of threads at once
spawnThread()
spawnThread()

// how to use .NET Thread Pool
open System.Threading

ThreadPool.QueueUserWorkItem(fun _ ->
                                for i=1 to 5 do printfn "[Thread %d] %d ..."
                                                    Thread.CurrentThread.ManagedThreadId i)

//Our thread pool task, note that the delegate's
//paramter is of type obj
let printNumbers (max: obj) =
    for i=1 to (max :?> int) do
        printfn "[Thread %d] %d ..."
            Thread.CurrentThread.ManagedThreadId i

ThreadPool.QueueUserWorkItem(new WaitCallback(printNumbers), box 5)

//Sharing data

//Run into race conditions
open System.Threading

let sumArray(arr : int[]) =
    //create reference value
    let total = ref 0

    //Add the first half
    let thread1Finished = ref false

    ThreadPool.QueueUserWorkItem(
        fun _ ->
            for i=0 to arr.Length/2-1 do
                total := arr.[i] + !total
            thread1Finished := true

        ) |> ignore

    // add second half
    let thread2Finished = ref false

    ThreadPool.QueueUserWorkItem(
        fun _ ->
            for i = arr.Length/2 to arr.Length - 1 do
                total := arr.[i] + !total
            thread2Finished := true
        ) |> ignore

    //Wait while the two threads finish their work
    while !thread1Finished = false || !thread2Finished = false do
        Thread.Sleep(0)

    !total

//create a million ones
let millionOnes = Array.create 1000000 1

#time

//right outcome is 1000000
sumArray millionOnes
sumArray millionOnes

// Array summing using lock
let sumArrayLocked (arr : int[]) =
    let total = ref 0

    //Add the first half
    let thread1Finished = ref false
    ThreadPool.QueueUserWorkItem(
        fun _ ->
            for i=0 to arr.Length/2-1 do
                lock(total) (fun () -> total := arr.[i] + !total)
            thread1Finished := true
        ) |> ignore

    //Add the second half
    let thread2Finished = ref false
    ThreadPool.QueueUserWorkItem(
        fun _ ->
            for i=arr.Length/2 to arr.Length-1 do
                lock(total) (fun () -> total := arr.[i] + !total)
            thread2Finished := true
        ) |> ignore

    //Wait while the two threads finished their work
    while !thread1Finished = false || !thread2Finished =false do
        Thread.Sleep(0)

    !total

#time

sumArray millionOnes
sumArrayLocked millionOnes //it's slower than unlock version

//Run into deadlock in F#
type BackAccount = {AccountID : int; OwnerName : string; mutable Balance : int}

//Transfer money between back accounts
let transferFunds amount (fromAcct : BackAccount) (toAcct : BackAccount) =
    printfn "Locking %s's account to deposit funds ..." toAcct.OwnerName
    lock fromAcct
        (fun () ->
            printfn "Locking %s's account to withdraw funds ..." fromAcct.OwnerName
            lock toAcct
                (fun () ->
                    fromAcct.Balance <- fromAcct.Balance - amount
                    toAcct.Balance <- toAcct.Balance + amount
                )
        )
    printfn "Final balance from %d to %d." fromAcct.Balance toAcct.Balance

let john = { AccountID = 1; OwnerName = "John Smith"; Balance = 1000}
let jane = { AccountID = 2; OwnerName = "Jane Doe"; Balance = 2000}

ThreadPool.QueueUserWorkItem(fun _ -> transferFunds 100 john jane)
ThreadPool.QueueUserWorkItem(fun _ -> transferFunds 100 jane john)


//Asynchronous file I/O using F# asycn workflows
open System
open System.IO

let asyncProcessFile (filePath : string) (processBytes : byte[] -> byte[]) =
    async {
        printfn "Processing file [%s]" (Path.GetFileName(filePath))

        use fileStream = new FileStream(filePath, FileMode.Open)
        let bytesToRead = int fileStream.Length

        let! data = fileStream.AsyncRead(bytesToRead)

        printfn "Opened [%s], read [%d] bytes"
            (Path.GetFileName(filePath)) data.Length

        let data' = processBytes data

        use resultFile = new FileStream(filePath + ".results", FileMode.Create)
        do! resultFile.AsyncWrite(data', 0, data'.Length)

        printfn "Finished processing file [%s]" <| Path.GetFileName(filePath)
    } |> Async.Start

//apply with identity function
asyncProcessFile @"C:\Test\ba-soft-skills-20140403.png" id

//Async tasks
open System.IO
open System.Net

let getHtml (url :string) =
    async {
        let req = WebRequest.Create(url)
        let! rsp = req.AsyncGetResponse()

        use stream = rsp.GetResponseStream()
        use reader = new StreamReader(stream)

        return reader.ReadToEndAsync().Result
    }

let html =
    getHtml "http://www.bing.com"
    |> Async.RunSynchronously

//execute more tasks
let webPages : string[] =
    ["http://www.bing.com" ; "http://www.yahoo.com"; "http://www.google.com"]
    |> List.map getHtml
    |> Async.Parallel
    |> Async.RunSynchronously

webPages

//Cancellation async operation
open System
open System.Threading

let cancelableTask =
    async {
        printfn "Waiting 10 seconds ..."
        for i = 1 to 10 do
            printfn "%d ..." i
            do! Async.Sleep(1000)
        printfn "Finished ..."
    }

//Callback used when the operation is canceled
let cancelHandler (ex: OperationCanceledException) =
    printfn "The task has been cancelled."

Async.TryCancelled(cancelableTask, cancelHandler) |> Async.Start

//this cancel just last asynchronous workflow
Async.CancelDefaultToken()

let computation = Async.TryCancelled(cancelableTask, cancelHandler)
let cancellationSource = new CancellationTokenSource()

Async.Start(computation, cancellationSource.Token)

//cancel by reference
cancellationSource.Cancel()

//Create async primitives
open System
open System.IO

type System.IO.Directory with
    //Retrieve all files under a path asynchronously
    static member AsyncGetFiles(path : string, searchPattern : string) =
        let dele = new Func<string * string, string[]>(Directory.GetFiles)
        Async.FromBeginEnd(
            (path, searchPattern),
            dele.BeginInvoke,
            dele.EndInvoke)

type System.IO.File with
    //Copy a file asynchronously
    static member AsyncCopy(source : string, dest : string) =
        let dele = new Func<string * string, unit>(File.Copy)
        Async.FromBeginEnd(
            (source, dest),
            dele.BeginInvoke,
            dele.EndInvoke)

let asyncBackup path searchPattern destPath =
    async {
        let! files = Directory.AsyncGetFiles(path, searchPattern)

        for file in files do
            let filename = Path.GetFileName(file)
            do! File.AsyncCopy(file, Path.Combine(destPath, filename))
    }

//backing up my files :)
asyncBackup @"C:\Test" "*.*" @"C:\Backup" |> Async.RunSynchronously

//Parallel Programming with TPL

//Parallel.For
open System
open System.Threading.Tasks

//Multiply two matricies using the TPL
let matrixMultiply (a : float[,]) (b:float[,]) =
    let aRow, aCol = Array2D.length1 a, Array2D.length2 b
    let bRow, bCol = Array2D.length1 a, Array2D.length2 b
    if aCol <> bRow then failwith "Array dimension mismatch"

    // Allocate space for the resulting matrix
    let c = Array2D.create aCol bRow 0.0
    let cRow, cCol = aCol, bRow

    //Compute each row of the resulting matrix
    let rowTask rowIdx =
        for colIdx=0 to cCol-1 do
            for x=0 to aRow-1 do
                c.[colIdx, rowIdx] <-
                    c.[colIdx, rowIdx] + a.[x,colIdx] * b.[rowIdx, x]
        ()
    let _ = Parallel.For(0, cRow, new Action<int>(rowTask))
    c // return the computed matrix


let x = Array2D.create 10 10 2.0
let y = Array2D.create 10 10 8.0
let result = matrixMultiply x y

//Using the Array.Parallel library
open System.IO

let getSecretData keyword =
    let secretFiles = Directory.GetFiles(@"C:\Test", "*.png")

    Array.Parallel.iter File.Decrypt secretFiles

    let secretData =
        Directory.GetFiles(@"C:\Test", "*.png")
        |> Array.Parallel.map (fun filePath -> File.ReadAllText(filePath))
        |> Array.Parallel.choose (fun contents ->
                if contents.Contains(keyword)
                then Some(contents)
                else None)

    Array.Parallel.iter File.Encrypt secretFiles

    secretData

//Using parallel primitoves
//using Tasks.WaitAll to wait for taks to complete
open System
open System.IO
open System.Drawing
open System.Drawing.Imaging
open System.Drawing.Drawing2D
open System.Threading.Tasks

//Resize images to a new width, height
let resizeImage (newWidth : int, newHeight : int) (filePath : string) =
    let originalImage = Bitmap.FromFile(filePath)

    let resizedImage = new Bitmap(newWidth, newHeight)
    use g = Graphics.FromImage(resizedImage)
    g.InterpolationMode <- InterpolationMode.HighQualityBicubic
    g.DrawImage(originalImage, 0, 0, newWidth, newHeight)

    let fileName = Path.GetFileNameWithoutExtension(filePath)
    let fileFolder = Path.GetDirectoryName(filePath)
    resizedImage.Save(
        Path.Combine(fileFolder, fileName+".resized.png"),
        ImageFormat.Png)

//Spawns a new TPL task to resize an image
let spawnTask filePath =
    let taskBody = new Action(fun () -> resizeImage (640, 480) filePath)
    Task.Factory.StartNew(taskBody)

let imageFiles = Directory.GetFiles(@"C:\Test\", "*.png")

//Spawning resize tasks
let resizeTasks = imageFiles |> Array.map spawnTask

//Wait for all tasks
Task.WaitAll(resizeTasks)

//Concurrent dictionary
open System
open System.IO
open System.Collections.Concurrent

//Queue of files to process
let filesToProcess =
    Directory.GetFiles(@"C:\Test", "*.txt")
    |> (fun files -> new ConcurrentQueue<_>(files))

//Dictionary to store the occurence of particular words
let wordUsage = new ConcurrentDictionary<string, int>()

let processFile filePath =
    let text = File.ReadAllText(filePath)
    let words =
        text.Split([| ' '; '\r'; '\n' |], StringSplitOptions.RemoveEmptyEntries)
        |> Array.map (fun word -> word.Trim())

    //Add the word to our lookup table. Inserts value '1', or if the key
    //is already present updates it to be 'count + 1'
    Array.Parallel.iter(fun word ->
        wordUsage.AddOrUpdate(word, (fun _ -> 1), (fun _ count -> count + 1))
        |> ignore
    ) words

//Begins updating the word Usage dictionary
let fillDictionary() =
    let mutable continueWorking = true

    while continueWorking do

        let dequeueSuccessful, filePath = filesToProcess.TryDequeue()
        if not dequeueSuccessful then
            //If the queue is empty, then we are done working
            if filesToProcess.IsEmpty then
                continueWorking <- false
            // ... otherwise, two tasks tried to dequeue
            // at the same time. Try again!
            else
                continueWorking <- true

        else
            //Process the file
            processFile filePath

fillDictionary()
fillDictionary()
fillDictionary()

//Using the concurrent bag class to store parallel results
open System
open System.Threading.Tasks
open System.Collections.Concurrent
open System.Collections.Generic

// Check if a member is prime
let isPrime x =
    let rec primeCheck count =
        //If the counter has reached x, then we know x is prime
        if count = x then true
        //If x is divisible by the counter, we know x isn't prime
        elif x % count = 0 then false
        else primeCheck (count + 1)
    //Special case
    if x = 1 then true
    else primeCheck 2

let computePrimes tasksToSpawn maxValue =
    let range = maxValue / tasksToSpawn
    let primes = new ConcurrentBag<int>()

    //Spawn several tasks at once, adding any primes they find
    // to the ConcurrentBag
    let tasks =
        [|
            for i in 0 .. tasksToSpawn - 1 do
                yield Task.Factory.StartNew(
                    Action(fun () ->
                        for x=i * range to (i+1)*range-1 do
                            if isPrime x then primes.Add(x)
                    )
                )
        |]
    Task.WaitAll(tasks)
    new HashSet<_>(primes :> seq<int>)

#time
computePrimes 10 100000
computePrimes 2 100000
	// Creating new threads
	open System
	open System.Threading

	//What will execute on each thread
	let threadBody() =
	for i in 1..5 do
	//Wait 1/10 of a second
	Thread.Sleep(100)
	printfn "[Thread %d] %d ..."
	Thread.CurrentThread.ManagedThreadId i

	let spawnThread() =
	let thread = new Thread(threadBody)
	thread.Start()

	// spawn a few of threads at once
	spawnThread()
	spawnThread()

	// how to use .NET Thread Pool
	open System.Threading

	ThreadPool.QueueUserWorkItem(fun _ ->
	for i=1 to 5 do printfn "[Thread %d] %d ..."
	Thread.CurrentThread.ManagedThreadId i)

	//Our thread pool task, note that the delegate's
	//paramter is of type obj
	let printNumbers (max: obj) =
	for i=1 to (max :?> int) do
	printfn "[Thread %d] %d ..."
	Thread.CurrentThread.ManagedThreadId i

	ThreadPool.QueueUserWorkItem(new WaitCallback(printNumbers), box 5)

	//Sharing data

	//Run into race conditions
	open System.Threading

	let sumArray(arr : int[]) =
	//create reference value
	let total = ref 0

	//Add the first half
	let thread1Finished = ref false

	ThreadPool.QueueUserWorkItem(
	fun _ ->
	for i=0 to arr.Length/2-1 do
	total := arr.[i] + !total
	thread1Finished := true

	) \|> ignore

	// add second half
	let thread2Finished = ref false

	ThreadPool.QueueUserWorkItem(
	fun _ ->
	for i = arr.Length/2 to arr.Length - 1 do
	total := arr.[i] + !total
	thread2Finished := true
	) \|> ignore

	//Wait while the two threads finish their work
	while !thread1Finished = false \|\| !thread2Finished = false do
	Thread.Sleep(0)

	!total

	//create a million ones
	let millionOnes = Array.create 1000000 1

	#time

	//right outcome is 1000000
	sumArray millionOnes
	sumArray millionOnes

	// Array summing using lock
	let sumArrayLocked (arr : int[]) =
	let total = ref 0

	//Add the first half
	let thread1Finished = ref false
	ThreadPool.QueueUserWorkItem(
	fun _ ->
	for i=0 to arr.Length/2-1 do
	lock(total) (fun () -> total := arr.[i] + !total)
	thread1Finished := true
	) \|> ignore

	//Add the second half
	let thread2Finished = ref false
	ThreadPool.QueueUserWorkItem(
	fun _ ->
	for i=arr.Length/2 to arr.Length-1 do
	lock(total) (fun () -> total := arr.[i] + !total)
	thread2Finished := true
	) \|> ignore

	//Wait while the two threads finished their work
	while !thread1Finished = false \|\| !thread2Finished =false do
	Thread.Sleep(0)

	!total

	#time

	sumArray millionOnes
	sumArrayLocked millionOnes //it's slower than unlock version

	//Run into deadlock in F#
	type BackAccount = {AccountID : int; OwnerName : string; mutable Balance : int}

	//Transfer money between back accounts
	let transferFunds amount (fromAcct : BackAccount) (toAcct : BackAccount) =
	printfn "Locking %s's account to deposit funds ..." toAcct.OwnerName
	lock fromAcct
	(fun () ->
	printfn "Locking %s's account to withdraw funds ..." fromAcct.OwnerName
	lock toAcct
	(fun () ->
	fromAcct.Balance <- fromAcct.Balance - amount
	toAcct.Balance <- toAcct.Balance + amount
	)
	)
	printfn "Final balance from %d to %d." fromAcct.Balance toAcct.Balance

	let john = { AccountID = 1; OwnerName = "John Smith"; Balance = 1000}
	let jane = { AccountID = 2; OwnerName = "Jane Doe"; Balance = 2000}

	ThreadPool.QueueUserWorkItem(fun _ -> transferFunds 100 john jane)
	ThreadPool.QueueUserWorkItem(fun _ -> transferFunds 100 jane john)


	//Asynchronous file I/O using F# asycn workflows
	open System
	open System.IO

	let asyncProcessFile (filePath : string) (processBytes : byte[] -> byte[]) =
	async {
	printfn "Processing file [%s]" (Path.GetFileName(filePath))

	use fileStream = new FileStream(filePath, FileMode.Open)
	let bytesToRead = int fileStream.Length

	let! data = fileStream.AsyncRead(bytesToRead)

	printfn "Opened [%s], read [%d] bytes"
	(Path.GetFileName(filePath)) data.Length

	let data' = processBytes data

	use resultFile = new FileStream(filePath + ".results", FileMode.Create)
	do! resultFile.AsyncWrite(data', 0, data'.Length)

	printfn "Finished processing file [%s]" <\| Path.GetFileName(filePath)
	} \|> Async.Start

	//apply with identity function
	asyncProcessFile @"C:\Test\ba-soft-skills-20140403.png" id

	//Async tasks
	open System.IO
	open System.Net

	let getHtml (url :string) =
	async {
	let req = WebRequest.Create(url)
	let! rsp = req.AsyncGetResponse()

	use stream = rsp.GetResponseStream()
	use reader = new StreamReader(stream)

	return reader.ReadToEndAsync().Result
	}

	let html =
	getHtml "http://www.bing.com"
	\|> Async.RunSynchronously

	//execute more tasks
	let webPages : string[] =
	["http://www.bing.com" ; "http://www.yahoo.com"; "http://www.google.com"]
	\|> List.map getHtml
	\|> Async.Parallel
	\|> Async.RunSynchronously

	webPages

	//Cancellation async operation
	open System
	open System.Threading

	let cancelableTask =
	async {
	printfn "Waiting 10 seconds ..."
	for i = 1 to 10 do
	printfn "%d ..." i
	do! Async.Sleep(1000)
	printfn "Finished ..."
	}

	//Callback used when the operation is canceled
	let cancelHandler (ex: OperationCanceledException) =
	printfn "The task has been cancelled."

	Async.TryCancelled(cancelableTask, cancelHandler) \|> Async.Start

	//this cancel just last asynchronous workflow
	Async.CancelDefaultToken()

	let computation = Async.TryCancelled(cancelableTask, cancelHandler)
	let cancellationSource = new CancellationTokenSource()

	Async.Start(computation, cancellationSource.Token)

	//cancel by reference
	cancellationSource.Cancel()

	//Create async primitives
	open System
	open System.IO

	type System.IO.Directory with
	//Retrieve all files under a path asynchronously
	static member AsyncGetFiles(path : string, searchPattern : string) =
	let dele = new Func<string * string, string[]>(Directory.GetFiles)
	Async.FromBeginEnd(
	(path, searchPattern),
	dele.BeginInvoke,
	dele.EndInvoke)

	type System.IO.File with
	//Copy a file asynchronously
	static member AsyncCopy(source : string, dest : string) =
	let dele = new Func<string * string, unit>(File.Copy)
	Async.FromBeginEnd(
	(source, dest),
	dele.BeginInvoke,
	dele.EndInvoke)

	let asyncBackup path searchPattern destPath =
	async {
	let! files = Directory.AsyncGetFiles(path, searchPattern)

	for file in files do
	let filename = Path.GetFileName(file)
	do! File.AsyncCopy(file, Path.Combine(destPath, filename))
	}

	//backing up my files :)
	asyncBackup @"C:\Test" "." @"C:\Backup" \|> Async.RunSynchronously

	//Parallel Programming with TPL

	//Parallel.For
	open System
	open System.Threading.Tasks

	//Multiply two matricies using the TPL
	let matrixMultiply (a : float[,]) (b:float[,]) =
	let aRow, aCol = Array2D.length1 a, Array2D.length2 b
	let bRow, bCol = Array2D.length1 a, Array2D.length2 b
	if aCol <> bRow then failwith "Array dimension mismatch"

	// Allocate space for the resulting matrix
	let c = Array2D.create aCol bRow 0.0
	let cRow, cCol = aCol, bRow

	//Compute each row of the resulting matrix
	let rowTask rowIdx =
	for colIdx=0 to cCol-1 do
	for x=0 to aRow-1 do
	c.[colIdx, rowIdx] <-
	c.[colIdx, rowIdx] + a.[x,colIdx] * b.[rowIdx, x]
	()
	let _ = Parallel.For(0, cRow, new Action<int>(rowTask))
	c // return the computed matrix


	let x = Array2D.create 10 10 2.0
	let y = Array2D.create 10 10 8.0
	let result = matrixMultiply x y

	//Using the Array.Parallel library
	open System.IO

	let getSecretData keyword =
	let secretFiles = Directory.GetFiles(@"C:\Test", "*.png")

	Array.Parallel.iter File.Decrypt secretFiles

	let secretData =
	Directory.GetFiles(@"C:\Test", "*.png")
	\|> Array.Parallel.map (fun filePath -> File.ReadAllText(filePath))
	\|> Array.Parallel.choose (fun contents ->
	if contents.Contains(keyword)
	then Some(contents)
	else None)

	Array.Parallel.iter File.Encrypt secretFiles

	secretData

	//Using parallel primitoves
	//using Tasks.WaitAll to wait for taks to complete
	open System
	open System.IO
	open System.Drawing
	open System.Drawing.Imaging
	open System.Drawing.Drawing2D
	open System.Threading.Tasks

	//Resize images to a new width, height
	let resizeImage (newWidth : int, newHeight : int) (filePath : string) =
	let originalImage = Bitmap.FromFile(filePath)

	let resizedImage = new Bitmap(newWidth, newHeight)
	use g = Graphics.FromImage(resizedImage)
	g.InterpolationMode <- InterpolationMode.HighQualityBicubic
	g.DrawImage(originalImage, 0, 0, newWidth, newHeight)

	let fileName = Path.GetFileNameWithoutExtension(filePath)
	let fileFolder = Path.GetDirectoryName(filePath)
	resizedImage.Save(
	Path.Combine(fileFolder, fileName+".resized.png"),
	ImageFormat.Png)

	//Spawns a new TPL task to resize an image
	let spawnTask filePath =
	let taskBody = new Action(fun () -> resizeImage (640, 480) filePath)
	Task.Factory.StartNew(taskBody)

	let imageFiles = Directory.GetFiles(@"C:\Test\", "*.png")

	//Spawning resize tasks
	let resizeTasks = imageFiles \|> Array.map spawnTask

	//Wait for all tasks
	Task.WaitAll(resizeTasks)

	//Concurrent dictionary
	open System
	open System.IO
	open System.Collections.Concurrent

	//Queue of files to process
	let filesToProcess =
	Directory.GetFiles(@"C:\Test", "*.txt")
	\|> (fun files -> new ConcurrentQueue<_>(files))

	//Dictionary to store the occurence of particular words
	let wordUsage = new ConcurrentDictionary<string, int>()

	let processFile filePath =
	let text = File.ReadAllText(filePath)
	let words =
	text.Split([\| ' '; '\r'; '\n' \|], StringSplitOptions.RemoveEmptyEntries)
	\|> Array.map (fun word -> word.Trim())

	//Add the word to our lookup table. Inserts value '1', or if the key
	//is already present updates it to be 'count + 1'
	Array.Parallel.iter(fun word ->
	wordUsage.AddOrUpdate(word, (fun _ -> 1), (fun _ count -> count + 1))
	\|> ignore
	) words

	//Begins updating the word Usage dictionary
	let fillDictionary() =
	let mutable continueWorking = true

	while continueWorking do

	let dequeueSuccessful, filePath = filesToProcess.TryDequeue()
	if not dequeueSuccessful then
	//If the queue is empty, then we are done working
	if filesToProcess.IsEmpty then
	continueWorking <- false
	// ... otherwise, two tasks tried to dequeue
	// at the same time. Try again!
	else
	continueWorking <- true

	else
	//Process the file
	processFile filePath

	fillDictionary()
	fillDictionary()
	fillDictionary()

	//Using the concurrent bag class to store parallel results
	open System
	open System.Threading.Tasks
	open System.Collections.Concurrent
	open System.Collections.Generic

	// Check if a member is prime
	let isPrime x =
	let rec primeCheck count =
	//If the counter has reached x, then we know x is prime
	if count = x then true
	//If x is divisible by the counter, we know x isn't prime
	elif x % count = 0 then false
	else primeCheck (count + 1)
	//Special case
	if x = 1 then true
	else primeCheck 2

	let computePrimes tasksToSpawn maxValue =
	let range = maxValue / tasksToSpawn
	let primes = new ConcurrentBag<int>()

	//Spawn several tasks at once, adding any primes they find
	// to the ConcurrentBag
	let tasks =
	[\|
	for i in 0 .. tasksToSpawn - 1 do
	yield Task.Factory.StartNew(
	Action(fun () ->
	for x=i * range to (i+1)*range-1 do
	if isPrime x then primes.Add(x)
	)
	)
	\|]
	Task.WaitAll(tasks)
	new HashSet<_>(primes :> seq<int>)

	#time
	computePrimes 10 100000
	computePrimes 2 100000