odytrice · November 15, 2024 22:36 · nasaphdisme · Jul 7, 2022 · kYasinAblay · Mar 1, 2023
diff --git a/fsharp-tutorial.fs b/fsharp-tutorial.fs
 // This sample will guide you through elements of the F# language.

 //
 // *******************************************************************************************************
 //   To execute the code in F# Interactive, highlight a section of code and press Alt-Enter in Windows or
 //   Ctrl-Enter Mac, or right-click and select "Send Selection to F# Interactive".
 //   You can open the F# Interactive Window from the "View" menu.
 // *******************************************************************************************************

 // For more about F#, see:
 //     http://fsharp.org
 //
 // For additional templates to use with F#, see the 'Online Templates' in Visual Studio,
 //     'New Project' --> 'Online Templates'
 //
 // For specific F# topics, see:
 //     http://fsharp.org (F# Open Organization)
 //     http://tryfsharp.org (F# Learning Portal)
 //     http://go.microsoft.com/fwlink/?LinkID=234174 (Visual F# Development Portal)
 //     http://go.microsoft.com/fwlink/?LinkID=124614 (Visual F# Code Gallery)
 //     http://go.microsoft.com/fwlink/?LinkId=235173 (Visual F# Math/Stats Programming)
 //     http://go.microsoft.com/fwlink/?LinkId=235176 (Visual F# Charting)
 //     http://github.com/ChrisMarinos/FSharpKoans (F# Koans)

 // Contents:

 //    - Integers and basic functions
 //    - Booleans
 //    - Strings
 //    - Tuples
 //    - Lists and list processing
 //    - Classes
 //    - Generic classes
 //    - Implementing interfaces
 //    - Arrays
 //    - Sequences
 //    - Recursive functions
 //    - Record types
 //    - Union types
 //    - Option types
 //    - Pattern matching
 //    - Units of measure
 //    - Parallel array programming
 //    - Using events
 //    - Database access using type providers
 //    - OData access using type providers

 // ---------------------------------------------------------------
 //         Integers and basic functions
 // ---------------------------------------------------------------

 module Integers =
    let sampleInteger = 176

    /// Do some arithmetic starting with the first integer
    let sampleInteger2 = (sampleInteger/4 + 5 - 7) * 4

    /// A list of the numbers from 0 to 99
    let sampleNumbers = [ 0 .. 99 ]

    /// A list of all tuples containing all the numbers from 0 to 99 and their squares
    let sampleTableOfSquares = [ for i in 0 .. 99 -> (i, i*i) ]

    // The next line prints a list that includes tuples, using %A for generic printing
    printfn "The table of squares from 0 to 99 is:\n%A" sampleTableOfSquares


 module BasicFunctions =

    // Use 'let' to define a function that accepts an integer argument and returns an integer.
    let func1 x = x*x + 3

    // Parenthesis are optional for function arguments
    let func1a (x) = x*x + 3

    /// Apply the function, naming the function return result using 'let'.
    /// The variable type is inferred from the function return type.
    let result1 = func1 4573

    printfn "The result of squaring the integer 4573 and adding 3 is %d" result1

    // When needed, annotate the type of a parameter name using '(argument:type)'
    let func2 (x:int) = 2*x*x - x/5 + 3

    let result2 = func2 (7 + 4)

    printfn "The result of applying the 1st sample function to (7 + 4) is %d" result2

    let func3 x =
        if x < 100.0 then
            2.0*x*x - x/5.0 + 3.0
        else
            2.0*x*x + x/5.0 - 37.0

    let result3 = func3 (6.5 + 4.5)

    printfn "The result of applying the 2nd sample function to (6.5 + 4.5) is %f" result3

 // ---------------------------------------------------------------
 //         Booleans
 // ---------------------------------------------------------------

 module SomeBooleanValues =

    let boolean1 = true

    let boolean2 = false

    let boolean3 = not boolean1 && (boolean2 || false)

    printfn "The expression 'not boolean1 && (boolean2 || false)' is %A" boolean3


 // ---------------------------------------------------------------
 //         Strings
 // ---------------------------------------------------------------

 module StringManipulation =

    let string1 = "Hello"

    let string2  = "world"

    /// Use @ to create a verbatim string literal

    let string3 = @"c:\Program Files\"

    /// Using a triple-quote string literal
    let string4 = """He said "hello world" after you did"""

    let helloWorld = string1 + " " + string2 // concatenate the two strings with a space in between

    printfn "%s" helloWorld

    /// A string formed by taking the first 7 characters of one of the result strings
    let substring = helloWorld.[0..6]

    printfn "%s" substring

 // ---------------------------------------------------------------
 //         Tuples (ordered sets of values)
 // ---------------------------------------------------------------

 module Tuples =

    /// A simple tuple of integers
    let tuple1 = (1, 2, 3)

    /// A function that swaps the order of two values in a tuple.
    /// QuickInfo shows that the function is inferred to have a generic type.

    let swapElems (a, b) = (b, a)

    printfn "The result of swapping (1, 2) is %A" (swapElems (1,2))

    /// A tuple consisting of an integer, a string, and a double-precision floating point number
    let tuple2 = (1, "fred", 3.1415)

    printfn "tuple1: %A    tuple2: %A" tuple1 tuple2


 // ---------------------------------------------------------------
 //         Lists and list processing
 // ---------------------------------------------------------------

 module Lists =

    let list1 = [ ]            /// an empty list

    let list2 = [ 1; 2; 3 ]    /// list of 3 elements

    let list3 = 42 :: list2    /// a new list with '42' added to the beginning

    let numberList = [ 1 .. 1000 ]  /// list of integers from 1 to 1000

    /// A list containing all the days of the year
    let daysList =
        [ for month in 1 .. 12 do
              for day in 1 .. System.DateTime.DaysInMonth(2012, month) do
                  yield System.DateTime(2012, month, day) ]

    /// A list containing the tuples which are the coordinates of the black squares on a chess board.
    let blackSquares =

        [ for i in 0 .. 7 do
              for j in 0 .. 7 do
                  if (i+j) % 2 = 1 then
                      yield (i, j) ]

    /// Square the numbers in numberList, using the pipeline operator to pass an argument to List.map
    let squares =
        numberList
        |> List.map (fun x -> x*x)

    /// Computes the sum of the squares of the numbers divisible by 3.
    let sumOfSquaresUpTo n =
        numberList
        |> List.filter (fun x -> x % 3 = 0)
        |> List.sumBy (fun x -> x * x)

 // ---------------------------------------------------------------
 //         Classes
 // ---------------------------------------------------------------

 module DefiningClasses =
    /// The class's constructor takes two arguments: dx and dy, both of type 'float'.
    type Vector2D(dx : float, dy : float) =

        /// The length of the vector, computed when the object is constructed
        let length = sqrt (dx*dx + dy*dy)

        // 'this' specifies a name for the object's self identifier
        // In instance methods, it must appear before the member name.

        member this.DX = dx

        member this.DY = dy

        member this.Length = length

        member this.Scale(k) = Vector2D(k * this.DX, k * this.DY)


    /// An instance of the Vector2D class
    let vector1 = Vector2D(3.0, 4.0)

    /// Get a new scaled vector object, without modifying the original object
    let vector2 = vector1.Scale(10.0)

    printfn "Length of vector1: %f      Length of vector2: %f" vector1.Length vector2.Length


 // ---------------------------------------------------------------
 //         Generic classes
 // ---------------------------------------------------------------

 module DefiningGenericClasses =

    type StateTracker<'T>(initialElement: 'T) = // 'T is the type parameter for the class

        /// Store the states in an array
        let mutable states = [ initialElement ]

        /// Add a new element to the list of states
        member this.UpdateState newState =
            states <- newState :: states  // use the '<-' operator to mutate the value

        /// Get the entire list of historical states
        member this.History = states


        /// Get the latest state
        member this.Current = states.Head

    /// An 'int' instance of the state tracker class. Note that the type parameter is inferred.
    let tracker = StateTracker 10

    // Add a state
    tracker.UpdateState 17

 // ---------------------------------------------------------------
 //         Implementing interfaces
 // ---------------------------------------------------------------

 /// Type that implements IDisposable

 type ReadFile() =

    let file = new System.IO.StreamReader("readme.txt")

    member this.ReadLine() = file.ReadLine()

    // this class's implementation of IDisposable members
    interface System.IDisposable with
        member this.Dispose() = file.Close()

 // ---------------------------------------------------------------
 //         Arrays
 // ---------------------------------------------------------------

 module Arrays =

    /// The empty array
    let array1 = [| |]

    let array2 = [| "hello"; "world"; "and"; "hello"; "world"; "again" |]

    let array3 = [| 1 .. 1000 |]

    /// An array containing only the words "hello" and "world"

    let array4 = [| for word in array2 do
                        if word.Contains("l") then
                            yield word |]

    /// An array initialized by index and containing the even numbers from 0 to 2000
    let evenNumbers = Array.init 1001 (fun n -> n * 2)

    /// sub-array extracted using slicing notation
    let evenNumbersSlice = evenNumbers.[0..500]

    for word in array4 do
        printfn "word: %s" word

    // modify an array element using the left arrow assignment operator
    array2.[1] <- "WORLD!"

    /// Calculates the sum of the lengths of the words that start with 'h'
    let sumOfLengthsOfWords =
        array2
        |> Array.filter (fun x -> x.StartsWith "h")
        |> Array.sumBy (fun x -> x.Length)

 // ---------------------------------------------------------------
 //         Sequences
 // ---------------------------------------------------------------


 module Sequences =

    // Sequences are evaluated on-demand and are re-evaluated each time they are iterated.
    // An F# sequence is an instance of a System.Collections.Generic.IEnumerable<'T>,
    // so Seq functions can be applied to Lists and Arrays as well.

    /// The empty sequence
    let seq1 = Seq.empty

    let seq2 = seq { yield "hello"; yield "world"; yield "and"; yield "hello"; yield "world"; yield "again" }

    let numbersSeq = seq { 1 .. 1000 }

    /// another array containing only the words "hello" and "world"
    let seq3 =
        seq { for word in seq2 do
                  if word.Contains("l") then
                      yield word }

    let evenNumbers = Seq.init 1001 (fun n -> n * 2)

    let rnd = System.Random()

    /// An infinite sequence which is a random walk
    //  Use yield! to return each element of a subsequence, similar to IEnumerable.SelectMany.

    let rec randomWalk x =
        seq { yield x
              yield! randomWalk (x + rnd.NextDouble() - 0.5) }

    let first100ValuesOfRandomWalk =
        randomWalk 5.0
        |> Seq.truncate 100
        |> Seq.toList

 // ---------------------------------------------------------------
 //         Recursive functions
 // ---------------------------------------------------------------

 module RecursiveFunctions  =

    /// Compute the factorial of an integer. Use 'let rec' to define a recursive function
    let rec factorial n =
        if n = 0 then 1 else n * factorial (n-1)

    /// Computes the greatest common factor of two integers.
    //  Since all of the recursive calls are tail calls, the compiler will turn the function into a loop,
    //  which improves performance and reduces memory consumption.

    let rec greatestCommonFactor a b =
        if a = 0 then b
        elif a < b then greatestCommonFactor a (b - a)
        else greatestCommonFactor (a - b) b

    /// Computes the sum of a list of integers using recursion.
    let rec sumList xs =
        match xs with
        | []    -> 0
        | y::ys -> y + sumList ys

    /// Make the function tail recursive, using a helper function with a result accumulator
    let rec private sumListTailRecHelper accumulator xs =
        match xs with
        | []    -> accumulator
        | y::ys -> sumListTailRecHelper (accumulator+y) ys

    let sumListTailRecursive xs = sumListTailRecHelper 0 xs


 // ---------------------------------------------------------------
 //         Record types
 // ---------------------------------------------------------------

 module RecordTypes =
    // define a record type
    type ContactCard =
        { Name     : string
          Phone    : string
          Verified : bool }

    let contact1 = { Name = "Alf" ; Phone = "(206) 555-0157" ; Verified = false }

    // Create a new record that is a copy of contact1,
    // but has different values for the 'Phone' and 'Verified' fields

    let contact2 = { contact1 with Phone = "(206) 555-0112"; Verified = true }

    /// Converts a 'ContactCard' object to a string
    let showCard c =
        c.Name + " Phone: " + c.Phone + (if not c.Verified then " (unverified)" else "")


 // ---------------------------------------------------------------
 //         Union types
 // ---------------------------------------------------------------

 module UnionTypes =

    /// Represents the suit of a playing card
    type Suit =
        | Hearts
        | Clubs
        | Diamonds
        | Spades

    /// Represents the rank of a playing card
    type Rank =
        /// Represents the rank of cards 2 .. 10
        | Value of int
        | Ace
        | King
        | Queen
        | Jack

        static member GetAllRanks() =
            [ yield Ace
              for i in 2 .. 10 do yield Value i
              yield Jack
              yield Queen
              yield King ]

    type Card =  { Suit: Suit; Rank: Rank }

    /// Returns a list representing all the cards in the deck

    let fullDeck =
        [ for suit in [ Hearts; Diamonds; Clubs; Spades] do
              for rank in Rank.GetAllRanks() do
                  yield { Suit=suit; Rank=rank } ]

    /// Converts a 'Card' object to a string
    let showCard c =
        let rankString =
            match c.Rank with
            | Ace -> "Ace"
            | King -> "King"
            | Queen -> "Queen"
            | Jack -> "Jack"
            | Value n -> string n

        let suitString =
            match c.Suit with
            | Clubs -> "clubs"
            | Diamonds -> "diamonds"
            | Spades -> "spades"
            | Hearts -> "hearts"

        rankString  + " of " + suitString

    let printAllCards() =
        for card in fullDeck do
            printfn "%s" (showCard card)


 // ---------------------------------------------------------------
 //         Option types
 // ---------------------------------------------------------------

 module OptionTypes =
    /// Option values are any kind of value tagged with either 'Some' or 'None'.
    /// They are used extensively in F# code to represent the cases where many other
    /// languages would use null references.

    type Customer = { zipCode : decimal option }

    /// Abstract class that computes the shipping zone for the customer's zip code,
    /// given implementations for the 'GetState' and 'GetShippingZone' abstract methods.

    [<AbstractClass>]

    type ShippingCalculator =

        abstract GetState : decimal -> string option

        abstract GetShippingZone : string -> int

        /// Return the shipping zone corresponding to the customer's ZIP code
        /// Customer may not yet have a ZIP code or the ZIP code may be invalid
        member this.CustomerShippingZone(customer : Customer) =

            customer.zipCode
            |> Option.bind this.GetState
            |> Option.map this.GetShippingZone


 // ---------------------------------------------------------------
 //         Pattern matching
 // ---------------------------------------------------------------

 module PatternMatching =

    /// A record for a person's first and last name

    type Person =
        { First : string
          Last  : string }

    /// Define a discriminated union of 3 different kinds of employees

    type Employee =
        /// Engineer is just herself
        | Engineer  of Person
        /// Manager has list of reports
        | Manager   of Person * list<Employee>
        /// Executive also has an assistant
        | Executive of Person * list<Employee> * Employee

    /// Count everyone underneath the employee in the management hierarchy, including the employee
    let rec countReports(emp : Employee) =
        1 + match emp with
            | Engineer(id) ->
                0
            | Manager(id, reports) ->
                reports |> List.sumBy countReports
            | Executive(id, reports, assistant) ->
                (reports |> List.sumBy countReports) + countReports assistant

    /// Find all managers/executives named "Dave" who do not have any reports
    let rec findDaveWithOpenPosition(emps : Employee list) =
        emps
        |> List.filter(function
                       | Manager({First = "Dave"}, []) -> true       // [] matches the empty list
                       | Executive({First = "Dave"}, [], _) -> true
                       | _ -> false)                                 // '_' is a wildcard pattern that matches anything
                                                                     // this handles the "or else" case

 // ---------------------------------------------------------------
 //         Units of measure
 // ---------------------------------------------------------------

 module UnitsOfMeasure =
    // Code can be annotated with units of measure when using F# arithmetic over numeric types

    open Microsoft.FSharp.Data.UnitSystems.SI.UnitNames

    [<Measure>]
    type mile =

        /// Conversion factor mile to meter: meter is defined in SI.UnitNames

        static member asMeter = 1600.<meter/mile>


    let d  = 50.<mile>          // Distance expressed using imperial units
    let d' = d * mile.asMeter   // Same distance expressed using metric system

    printfn "%A = %A" d d'
    // let error = d + d'       // Compile error: units of measure do not match


 // ---------------------------------------------------------------
 //         Parallel array programming
 // ---------------------------------------------------------------

 module ParallelArrayProgramming =

    let oneBigArray = [| 0 .. 100000 |]

    // do some CPU intensive computation
    let rec computeSomeFunction x =
        if x <= 2 then 1
        else computeSomeFunction (x - 1) + computeSomeFunction (x - 2)

    // Do a parallel map over a large input array
    let computeResults() = oneBigArray |> Array.Parallel.map (fun x -> computeSomeFunction (x % 20))

    printfn "Parallel computation results: %A" (computeResults())


 // ---------------------------------------------------------------
 //         Using events
 // ---------------------------------------------------------------

 module Events =

    open System

    // Create instance of Event object that consists of subscription point (event.Publish) and event trigger (event.Trigger)
    let simpleEvent = new Event<int>()

    // Add handler
    simpleEvent.Publish.Add(fun x -> printfn "this is handler was added with Publish.Add: %d" x)

    // Trigger event
    simpleEvent.Trigger(5)

    // Create instance of Event that follows standard .NET convention: (sender, EventArgs)
    let eventForDelegateType = new Event<EventHandler, EventArgs>()


    // Add handler
    eventForDelegateType.Publish.AddHandler(
        EventHandler(fun _ _ -> printfn "this is handler was added with Publish.AddHandler"))


    // Trigger event (note that sender argument should be set)
    eventForDelegateType.Trigger(null, EventArgs.Empty)

 // ---------------------------------------------------------------
 //         Database access using type providers
 // ---------------------------------------------------------------

 module DatabaseAccess =

    // The easiest way to access a SQL database from F# is to use F# type providers.
    // Add references to System.Data, System.Data.Linq, and FSharp.Data.TypeProviders.dll.
    // You can use Server Explorer to build your ConnectionString.

    (*

    #r "System.Data"
    #r "System.Data.Linq"
    #r "FSharp.Data.TypeProviders"

    open Microsoft.FSharp.Data.TypeProviders

    type SqlConnection = SqlDataConnection<ConnectionString = @"Data Source=.\sqlexpress;Initial Catalog=tempdb;Integrated Security=True">
    let db = SqlConnection.GetDataContext()

    let table =
        query { for r in db.Table do
                select r }

    *)

    // You can also use SqlEntityConnection instead of SqlDataConnection, which accesses the database using Entity Framework.

    ()


 // ---------------------------------------------------------------
 //         OData access using type providers
 // ---------------------------------------------------------------

 module OData =

    (*

    open System.Data.Services.Client
    open Microsoft.FSharp.Data.TypeProviders

    // Consume demographics population and income OData service from Azure Marketplace.
    // For more information, see http://go.microsoft.com/fwlink/?LinkId=239712

    type Demographics = Microsoft.FSharp.Data.TypeProviders.ODataService<ServiceUri = "https://api.datamarket.azure.com/Esri/KeyUSDemographicsTrial/">
    let ctx = Demographics.GetDataContext()

    // Sign up for a Azure Marketplace account at https://datamarket.azure.com/account/info
    ctx.Credentials <- System.Net.NetworkCredential ("<your liveID>", "<your Azure Marketplace Key>")

    let cities =
        query { for c in ctx.demog1 do
                where (c.StateName = "Washington") }

    for c in cities do
        printfn "%A - %A" c.GeographyId c.PerCapitaIncome2010.Value

    *)

    ()


 #if COMPILED

 module BoilerPlateForForm =
    [<System.STAThread>]
    do ()
 //    do System.Windows.Forms.Application.Run()

 #endif
	// This sample will guide you through elements of the F# language.

	//
	// *******************************************************************************************************
	// To execute the code in F# Interactive, highlight a section of code and press Alt-Enter in Windows or
	// Ctrl-Enter Mac, or right-click and select "Send Selection to F# Interactive".
	// You can open the F# Interactive Window from the "View" menu.
	// *******************************************************************************************************

	// For more about F#, see:
	// http://fsharp.org
	//
	// For additional templates to use with F#, see the 'Online Templates' in Visual Studio,
	// 'New Project' --> 'Online Templates'
	//
	// For specific F# topics, see:
	// http://fsharp.org (F# Open Organization)
	// http://tryfsharp.org (F# Learning Portal)
	// http://go.microsoft.com/fwlink/?LinkID=234174 (Visual F# Development Portal)
	// http://go.microsoft.com/fwlink/?LinkID=124614 (Visual F# Code Gallery)
	// http://go.microsoft.com/fwlink/?LinkId=235173 (Visual F# Math/Stats Programming)
	// http://go.microsoft.com/fwlink/?LinkId=235176 (Visual F# Charting)
	// http://github.com/ChrisMarinos/FSharpKoans (F# Koans)

	// Contents:

	// - Integers and basic functions
	// - Booleans
	// - Strings
	// - Tuples
	// - Lists and list processing
	// - Classes
	// - Generic classes
	// - Implementing interfaces
	// - Arrays
	// - Sequences
	// - Recursive functions
	// - Record types
	// - Union types
	// - Option types
	// - Pattern matching
	// - Units of measure
	// - Parallel array programming
	// - Using events
	// - Database access using type providers
	// - OData access using type providers

	// ---------------------------------------------------------------
	// Integers and basic functions
	// ---------------------------------------------------------------

	module Integers =
	let sampleInteger = 176

	/// Do some arithmetic starting with the first integer
	let sampleInteger2 = (sampleInteger/4 + 5 - 7) * 4

	/// A list of the numbers from 0 to 99
	let sampleNumbers = [ 0 .. 99 ]

	/// A list of all tuples containing all the numbers from 0 to 99 and their squares
	let sampleTableOfSquares = [ for i in 0 .. 99 -> (i, i*i) ]

	// The next line prints a list that includes tuples, using %A for generic printing
	printfn "The table of squares from 0 to 99 is:\n%A" sampleTableOfSquares


	module BasicFunctions =

	// Use 'let' to define a function that accepts an integer argument and returns an integer.
	let func1 x = x*x + 3

	// Parenthesis are optional for function arguments
	let func1a (x) = x*x + 3

	/// Apply the function, naming the function return result using 'let'.
	/// The variable type is inferred from the function return type.
	let result1 = func1 4573

	printfn "The result of squaring the integer 4573 and adding 3 is %d" result1

	// When needed, annotate the type of a parameter name using '(argument:type)'
	let func2 (x:int) = 2xx - x/5 + 3

	let result2 = func2 (7 + 4)

	printfn "The result of applying the 1st sample function to (7 + 4) is %d" result2

	let func3 x =
	if x < 100.0 then
	2.0xx - x/5.0 + 3.0
	else
	2.0xx + x/5.0 - 37.0

	let result3 = func3 (6.5 + 4.5)

	printfn "The result of applying the 2nd sample function to (6.5 + 4.5) is %f" result3

	// ---------------------------------------------------------------
	// Booleans
	// ---------------------------------------------------------------

	module SomeBooleanValues =

	let boolean1 = true

	let boolean2 = false

	let boolean3 = not boolean1 && (boolean2 \|\| false)

	printfn "The expression 'not boolean1 && (boolean2 \|\| false)' is %A" boolean3


	// ---------------------------------------------------------------
	// Strings
	// ---------------------------------------------------------------

	module StringManipulation =

	let string1 = "Hello"

	let string2 = "world"

	/// Use @ to create a verbatim string literal

	let string3 = @"c:\Program Files\"

	/// Using a triple-quote string literal
	let string4 = """He said "hello world" after you did"""

	let helloWorld = string1 + " " + string2 // concatenate the two strings with a space in between

	printfn "%s" helloWorld

	/// A string formed by taking the first 7 characters of one of the result strings
	let substring = helloWorld.[0..6]

	printfn "%s" substring

	// ---------------------------------------------------------------
	// Tuples (ordered sets of values)
	// ---------------------------------------------------------------

	module Tuples =

	/// A simple tuple of integers
	let tuple1 = (1, 2, 3)

	/// A function that swaps the order of two values in a tuple.
	/// QuickInfo shows that the function is inferred to have a generic type.

	let swapElems (a, b) = (b, a)

	printfn "The result of swapping (1, 2) is %A" (swapElems (1,2))

	/// A tuple consisting of an integer, a string, and a double-precision floating point number
	let tuple2 = (1, "fred", 3.1415)

	printfn "tuple1: %A tuple2: %A" tuple1 tuple2


	// ---------------------------------------------------------------
	// Lists and list processing
	// ---------------------------------------------------------------

	module Lists =

	let list1 = [ ] /// an empty list

	let list2 = [ 1; 2; 3 ] /// list of 3 elements

	let list3 = 42 :: list2 /// a new list with '42' added to the beginning

	let numberList = [ 1 .. 1000 ] /// list of integers from 1 to 1000

	/// A list containing all the days of the year
	let daysList =
	[ for month in 1 .. 12 do
	for day in 1 .. System.DateTime.DaysInMonth(2012, month) do
	yield System.DateTime(2012, month, day) ]

	/// A list containing the tuples which are the coordinates of the black squares on a chess board.
	let blackSquares =

	[ for i in 0 .. 7 do
	for j in 0 .. 7 do
	if (i+j) % 2 = 1 then
	yield (i, j) ]

	/// Square the numbers in numberList, using the pipeline operator to pass an argument to List.map
	let squares =
	numberList
	\|> List.map (fun x -> x*x)

	/// Computes the sum of the squares of the numbers divisible by 3.
	let sumOfSquaresUpTo n =
	numberList
	\|> List.filter (fun x -> x % 3 = 0)
	\|> List.sumBy (fun x -> x * x)

	// ---------------------------------------------------------------
	// Classes
	// ---------------------------------------------------------------

	module DefiningClasses =
	/// The class's constructor takes two arguments: dx and dy, both of type 'float'.
	type Vector2D(dx : float, dy : float) =

	/// The length of the vector, computed when the object is constructed
	let length = sqrt (dxdx + dydy)

	// 'this' specifies a name for the object's self identifier
	// In instance methods, it must appear before the member name.

	member this.DX = dx

	member this.DY = dy

	member this.Length = length

	member this.Scale(k) = Vector2D(k * this.DX, k * this.DY)


	/// An instance of the Vector2D class
	let vector1 = Vector2D(3.0, 4.0)

	/// Get a new scaled vector object, without modifying the original object
	let vector2 = vector1.Scale(10.0)

	printfn "Length of vector1: %f Length of vector2: %f" vector1.Length vector2.Length


	// ---------------------------------------------------------------
	// Generic classes
	// ---------------------------------------------------------------

	module DefiningGenericClasses =

	type StateTracker<'T>(initialElement: 'T) = // 'T is the type parameter for the class

	/// Store the states in an array
	let mutable states = [ initialElement ]

	/// Add a new element to the list of states
	member this.UpdateState newState =
	states <- newState :: states // use the '<-' operator to mutate the value

	/// Get the entire list of historical states
	member this.History = states


	/// Get the latest state
	member this.Current = states.Head

	/// An 'int' instance of the state tracker class. Note that the type parameter is inferred.
	let tracker = StateTracker 10

	// Add a state
	tracker.UpdateState 17

	// ---------------------------------------------------------------
	// Implementing interfaces
	// ---------------------------------------------------------------

	/// Type that implements IDisposable

	type ReadFile() =

	let file = new System.IO.StreamReader("readme.txt")

	member this.ReadLine() = file.ReadLine()

	// this class's implementation of IDisposable members
	interface System.IDisposable with
	member this.Dispose() = file.Close()

	// ---------------------------------------------------------------
	// Arrays
	// ---------------------------------------------------------------

	module Arrays =

	/// The empty array
	let array1 = [\| \|]

	let array2 = [\| "hello"; "world"; "and"; "hello"; "world"; "again" \|]

	let array3 = [\| 1 .. 1000 \|]

	/// An array containing only the words "hello" and "world"

	let array4 = [\| for word in array2 do
	if word.Contains("l") then
	yield word \|]

	/// An array initialized by index and containing the even numbers from 0 to 2000
	let evenNumbers = Array.init 1001 (fun n -> n * 2)

	/// sub-array extracted using slicing notation
	let evenNumbersSlice = evenNumbers.[0..500]

	for word in array4 do
	printfn "word: %s" word

	// modify an array element using the left arrow assignment operator
	array2.[1] <- "WORLD!"

	/// Calculates the sum of the lengths of the words that start with 'h'
	let sumOfLengthsOfWords =
	array2
	\|> Array.filter (fun x -> x.StartsWith "h")
	\|> Array.sumBy (fun x -> x.Length)

	// ---------------------------------------------------------------
	// Sequences
	// ---------------------------------------------------------------


	module Sequences =

	// Sequences are evaluated on-demand and are re-evaluated each time they are iterated.
	// An F# sequence is an instance of a System.Collections.Generic.IEnumerable<'T>,
	// so Seq functions can be applied to Lists and Arrays as well.

	/// The empty sequence
	let seq1 = Seq.empty

	let seq2 = seq { yield "hello"; yield "world"; yield "and"; yield "hello"; yield "world"; yield "again" }

	let numbersSeq = seq { 1 .. 1000 }

	/// another array containing only the words "hello" and "world"
	let seq3 =
	seq { for word in seq2 do
	if word.Contains("l") then
	yield word }

	let evenNumbers = Seq.init 1001 (fun n -> n * 2)

	let rnd = System.Random()

	/// An infinite sequence which is a random walk
	// Use yield! to return each element of a subsequence, similar to IEnumerable.SelectMany.

	let rec randomWalk x =
	seq { yield x
	yield! randomWalk (x + rnd.NextDouble() - 0.5) }

	let first100ValuesOfRandomWalk =
	randomWalk 5.0
	\|> Seq.truncate 100
	\|> Seq.toList

	// ---------------------------------------------------------------
	// Recursive functions
	// ---------------------------------------------------------------

	module RecursiveFunctions =

	/// Compute the factorial of an integer. Use 'let rec' to define a recursive function
	let rec factorial n =
	if n = 0 then 1 else n * factorial (n-1)

	/// Computes the greatest common factor of two integers.
	// Since all of the recursive calls are tail calls, the compiler will turn the function into a loop,
	// which improves performance and reduces memory consumption.

	let rec greatestCommonFactor a b =
	if a = 0 then b
	elif a < b then greatestCommonFactor a (b - a)
	else greatestCommonFactor (a - b) b

	/// Computes the sum of a list of integers using recursion.
	let rec sumList xs =
	match xs with
	\| [] -> 0
	\| y::ys -> y + sumList ys

	/// Make the function tail recursive, using a helper function with a result accumulator
	let rec private sumListTailRecHelper accumulator xs =
	match xs with
	\| [] -> accumulator
	\| y::ys -> sumListTailRecHelper (accumulator+y) ys

	let sumListTailRecursive xs = sumListTailRecHelper 0 xs


	// ---------------------------------------------------------------
	// Record types
	// ---------------------------------------------------------------

	module RecordTypes =
	// define a record type
	type ContactCard =
	{ Name : string
	Phone : string
	Verified : bool }

	let contact1 = { Name = "Alf" ; Phone = "(206) 555-0157" ; Verified = false }

	// Create a new record that is a copy of contact1,
	// but has different values for the 'Phone' and 'Verified' fields

	let contact2 = { contact1 with Phone = "(206) 555-0112"; Verified = true }

	/// Converts a 'ContactCard' object to a string
	let showCard c =
	c.Name + " Phone: " + c.Phone + (if not c.Verified then " (unverified)" else "")


	// ---------------------------------------------------------------
	// Union types
	// ---------------------------------------------------------------

	module UnionTypes =

	/// Represents the suit of a playing card
	type Suit =
	\| Hearts
	\| Clubs
	\| Diamonds
	\| Spades

	/// Represents the rank of a playing card
	type Rank =
	/// Represents the rank of cards 2 .. 10
	\| Value of int
	\| Ace
	\| King
	\| Queen
	\| Jack

	static member GetAllRanks() =
	[ yield Ace
	for i in 2 .. 10 do yield Value i
	yield Jack
	yield Queen
	yield King ]

	type Card = { Suit: Suit; Rank: Rank }

	/// Returns a list representing all the cards in the deck

	let fullDeck =
	[ for suit in [ Hearts; Diamonds; Clubs; Spades] do
	for rank in Rank.GetAllRanks() do
	yield { Suit=suit; Rank=rank } ]

	/// Converts a 'Card' object to a string
	let showCard c =
	let rankString =
	match c.Rank with
	\| Ace -> "Ace"
	\| King -> "King"
	\| Queen -> "Queen"
	\| Jack -> "Jack"
	\| Value n -> string n

	let suitString =
	match c.Suit with
	\| Clubs -> "clubs"
	\| Diamonds -> "diamonds"
	\| Spades -> "spades"
	\| Hearts -> "hearts"

	rankString + " of " + suitString

	let printAllCards() =
	for card in fullDeck do
	printfn "%s" (showCard card)


	// ---------------------------------------------------------------
	// Option types
	// ---------------------------------------------------------------

	module OptionTypes =
	/// Option values are any kind of value tagged with either 'Some' or 'None'.
	/// They are used extensively in F# code to represent the cases where many other
	/// languages would use null references.

	type Customer = { zipCode : decimal option }

	/// Abstract class that computes the shipping zone for the customer's zip code,
	/// given implementations for the 'GetState' and 'GetShippingZone' abstract methods.

	[<AbstractClass>]

	type ShippingCalculator =

	abstract GetState : decimal -> string option

	abstract GetShippingZone : string -> int

	/// Return the shipping zone corresponding to the customer's ZIP code
	/// Customer may not yet have a ZIP code or the ZIP code may be invalid
	member this.CustomerShippingZone(customer : Customer) =

	customer.zipCode
	\|> Option.bind this.GetState
	\|> Option.map this.GetShippingZone


	// ---------------------------------------------------------------
	// Pattern matching
	// ---------------------------------------------------------------

	module PatternMatching =

	/// A record for a person's first and last name

	type Person =
	{ First : string
	Last : string }

	/// Define a discriminated union of 3 different kinds of employees

	type Employee =
	/// Engineer is just herself
	\| Engineer of Person
	/// Manager has list of reports
	\| Manager of Person * list<Employee>
	/// Executive also has an assistant
	\| Executive of Person * list<Employee> * Employee

	/// Count everyone underneath the employee in the management hierarchy, including the employee
	let rec countReports(emp : Employee) =
	1 + match emp with
	\| Engineer(id) ->
	0
	\| Manager(id, reports) ->
	reports \|> List.sumBy countReports
	\| Executive(id, reports, assistant) ->
	(reports \|> List.sumBy countReports) + countReports assistant

	/// Find all managers/executives named "Dave" who do not have any reports
	let rec findDaveWithOpenPosition(emps : Employee list) =
	emps
	\|> List.filter(function
	\| Manager({First = "Dave"}, []) -> true // [] matches the empty list
	\| Executive({First = "Dave"}, [], _) -> true
	\| _ -> false) // '_' is a wildcard pattern that matches anything
	// this handles the "or else" case

	// ---------------------------------------------------------------
	// Units of measure
	// ---------------------------------------------------------------

	module UnitsOfMeasure =
	// Code can be annotated with units of measure when using F# arithmetic over numeric types

	open Microsoft.FSharp.Data.UnitSystems.SI.UnitNames

	[<Measure>]
	type mile =

	/// Conversion factor mile to meter: meter is defined in SI.UnitNames

	static member asMeter = 1600.<meter/mile>


	let d = 50.<mile> // Distance expressed using imperial units
	let d' = d * mile.asMeter // Same distance expressed using metric system

	printfn "%A = %A" d d'
	// let error = d + d' // Compile error: units of measure do not match


	// ---------------------------------------------------------------
	// Parallel array programming
	// ---------------------------------------------------------------

	module ParallelArrayProgramming =

	let oneBigArray = [\| 0 .. 100000 \|]

	// do some CPU intensive computation
	let rec computeSomeFunction x =
	if x <= 2 then 1
	else computeSomeFunction (x - 1) + computeSomeFunction (x - 2)

	// Do a parallel map over a large input array
	let computeResults() = oneBigArray \|> Array.Parallel.map (fun x -> computeSomeFunction (x % 20))

	printfn "Parallel computation results: %A" (computeResults())


	// ---------------------------------------------------------------
	// Using events
	// ---------------------------------------------------------------

	module Events =

	open System

	// Create instance of Event object that consists of subscription point (event.Publish) and event trigger (event.Trigger)
	let simpleEvent = new Event<int>()

	// Add handler
	simpleEvent.Publish.Add(fun x -> printfn "this is handler was added with Publish.Add: %d" x)

	// Trigger event
	simpleEvent.Trigger(5)

	// Create instance of Event that follows standard .NET convention: (sender, EventArgs)
	let eventForDelegateType = new Event<EventHandler, EventArgs>()


	// Add handler
	eventForDelegateType.Publish.AddHandler(
	EventHandler(fun _ _ -> printfn "this is handler was added with Publish.AddHandler"))


	// Trigger event (note that sender argument should be set)
	eventForDelegateType.Trigger(null, EventArgs.Empty)

	// ---------------------------------------------------------------
	// Database access using type providers
	// ---------------------------------------------------------------

	module DatabaseAccess =

	// The easiest way to access a SQL database from F# is to use F# type providers.
	// Add references to System.Data, System.Data.Linq, and FSharp.Data.TypeProviders.dll.
	// You can use Server Explorer to build your ConnectionString.

	(*

	#r "System.Data"
	#r "System.Data.Linq"
	#r "FSharp.Data.TypeProviders"

	open Microsoft.FSharp.Data.TypeProviders

	type SqlConnection = SqlDataConnection<ConnectionString = @"Data Source=.\sqlexpress;Initial Catalog=tempdb;Integrated Security=True">
	let db = SqlConnection.GetDataContext()

	let table =
	query { for r in db.Table do
	select r }

	*)

	// You can also use SqlEntityConnection instead of SqlDataConnection, which accesses the database using Entity Framework.

	()


	// ---------------------------------------------------------------
	// OData access using type providers
	// ---------------------------------------------------------------

	module OData =

	(*

	open System.Data.Services.Client
	open Microsoft.FSharp.Data.TypeProviders

	// Consume demographics population and income OData service from Azure Marketplace.
	// For more information, see http://go.microsoft.com/fwlink/?LinkId=239712

	type Demographics = Microsoft.FSharp.Data.TypeProviders.ODataService<ServiceUri = "https://api.datamarket.azure.com/Esri/KeyUSDemographicsTrial/">
	let ctx = Demographics.GetDataContext()

	// Sign up for a Azure Marketplace account at https://datamarket.azure.com/account/info
	ctx.Credentials <- System.Net.NetworkCredential ("<your liveID>", "<your Azure Marketplace Key>")

	let cities =
	query { for c in ctx.demog1 do
	where (c.StateName = "Washington") }

	for c in cities do
	printfn "%A - %A" c.GeographyId c.PerCapitaIncome2010.Value

	*)

	()


	#if COMPILED

	module BoilerPlateForForm =
	[<System.STAThread>]
	do ()
	// do System.Windows.Forms.Application.Run()

	#endif