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    • F Sharp (programming language)

    F# pronounced F sharp is a general purpose, strongly typed, multi-paradigm programming language that encompasses functional, imperative, and object-oriented programming methods. F# is most often used as a cross-platform Common Language Infrastructure CLI language, but it can also generate JavaScript and graphics processing unit GPU code.

    F# is developed by the F# Software Foundation, Microsoft and open contributors. An open source, cross-platform compiler for F# is available from the F# Software Foundation. F# is also a fully supported language in Visual Studio and Xamarin Studio. Other tools supporting F# development include Mono, MonoDevelop, SharpDevelop, MBrace, and WebSharper. Plug-ins supporting F# exist for many widely used editors, most notably the Ionide extension for Atom and Visual Studio Code, and integrations for other editors such as Vim, Emacs, and Rider.

    F# is a member of the ML language family and originated as a .NET Framework implementation of a core of the programming language OCaml. It has also been influenced by C#, Python, Haskell, Scala, and Erlang.

    History

    In the course of its development, the language has gone through several versions:

    JavaScript, GPU

    Ionide, Visual Studio Code, Atom, WebSharper, Rider

    JavaScript, GPU

    Ionide, Visual Studio Code, Atom, WebSharper, Rider

    F# uses an open development and engineering process. The language evolution process is managed by Don Syme from Microsoft Research as the benevolent dictator for life BDFL for the language design, together with the F# Software Foundation. Earlier versions of the F# language were designed by Microsoft and Microsoft Research using a closed development process.

    F# originates from Microsoft Research, Cambridge, UK. The language was originally designed and implemented by Don Syme, according to whom in the fsharp team, they say the F is for "Fun". Andrew Kennedy contributed to the design of units of measure. The Visual F# Tools for Visual Studio are developed by Microsoft. The F# Software Foundation developed the F# open-source compiler and tools, incorporating the open-source compiler implementation provided by the Microsoft Visual F# Tools team.

    Language overview

    F# is a strongly typed functional-first language that uses type inference. The programmer does not need to declare types—the compiler deduces types during compilation type inference. F# also allows explicit type annotations, and requires them in some situations.

    F# is an expression-based language using eager evaluation. Every statement in F#, including if expressions, try expressions and loops, is a composable expression with a static type. Functions and expressions that do not return any value have a return type of unit. F# uses the let keyword for binding values to a name. For example:

    let x = 3 + 4

    binds the value 7 to the name x.

    New types are defined using the type keyword. For functional programming, F# provides tuple, record, discriminated union, list, option, and result types. A tuple represents a set of n values, where n ≥ 0. The value n is called the arity of the tuple. A 3-tuple would be represented as A, B, C, where A, B, and C are values of possibly different types. A tuple can be used to store values only when the number of values is known at design-time and stays constant during execution.

    A record is a type where the data members are named. Here is an example of record definition: 

     type R = 
        { Name : string 
         Age : int }

    Records can be created as let r = { Name="AB"; Age=42 }. The with keyword is used to create a copy of a record, as in { r with Name="CD" }, which creates a new record by copying r and changing the value of the Name field assuming the record created in the last example was named r.

    A discriminated union type is a type-safe version of C unions. For example,

     type A = 
    | UnionCaseX of string
    | UnionCaseY of int

    Values of the union type can correspond to either union case. The types of the values carried by each union case is included in the definition of each case.

    The list type is an immutable linked list represented either using a head::tail notation :: is the cons operator or a shorthand as [item1; item2; item3]. An empty list is written []. The option type is a discriminated union type with choices Somex or None. F# types may be generic, implemented as generic .NET types.

    F# supports lambda functions and closures. All functions in F# are first class values and are immutable. Functions can be curried. Being first-class values, functions can be passed as arguments to other functions. Like other functional programming languages, F# allows function composition using the >> and << operators.

    F# provides sequence expressions that define a sequence seq { ... }, list [ ... ] or array [| ... |] through code that generates values. For example,

     seq { for b in 0 .. 25 do
           if b < 15 then
               yield b*b }

    forms a sequence of squares of numbers from 0 to 14 by filtering out numbers from the range of numbers from 0 to 25. Sequences are generators – values are generated on-demand i.e., are lazily evaluated – while lists and arrays are evaluated eagerly.

    F# uses pattern matching to bind values to names. Pattern matching is also used when accessing discriminated unions – the union is value matched against pattern rules and a rule is selected when a match succeeds. F# also supports Active Patterns as a form of extensible pattern matching. It is used, for example, when multiple ways of matching on a type exist.

    F# supports a general syntax for defining compositional computations called computation expressions. Sequence expressions, asynchronous computations and queries are particular kinds of computation expressions. Computation expressions are an implementation of the monad pattern.

    F# support for imperative programming includes

    Values and record fields can also be labelled as mutable. For example:

    // Define 'x' with initial value '1'
let mutable x = 1
// Change the value of 'x' to '3'
x <- 3

    Also, F# supports access to all CLI types and objects such as those defined in the System.Collections.Generic namespace defining imperative data structures.

    Like other Common Language Infrastructure CLI languages, F# can use CLI types and objects through object programming. F# support for object programming in expressions includes:

    Support for object programming in patterns includes

    F# object type definitions can be class, struct, interface, enum, or delegate type definitions, corresponding to the definition forms found in C#. For example, here is a class with a constructor taking a name and age, and declaring two properties.

    /// A simple object type definition
type Personname : string, age : int =
    member x.Name = name
    member x.Age = age

    F# supports asynchronous programming through asynchronous workflows. An asynchronous workflow is defined as a sequence of commands inside an async{ ... }, as in

    let asynctask = 
    async { let req = WebRequest.Createurl
            let! response = req.GetResponseAsync
            use stream = response.GetResponseStream
            use streamreader = new System.IO.StreamReaderstream
            return streamreader.ReadToEnd }

    The let! indicates that the expression on the right getting the response should be done asynchronously but the flow should only continue when the result is available. In other words, from the point of view of the code block, it's as if getting the response is a blocking call, whereas from the point of view of the system, the thread won't be blocked and may be used to process other flows while the result needed for this one doesn't become available.

    The async block may be invoked using the Async.RunSynchronously function. Multiple async blocks can be executed in parallel using the Async.Parallel function that takes a list of async objects in the example, asynctask is an async object and creates another async object to run the tasks in the lists in parallel. The resultant object is invoked using Async.RunSynchronously. Inversion of control in F# follows this pattern.

    Parallel programming is supported partly through the Async.Parallel, Async.Start and other operations that run asynchronous blocks in parallel.

    Parallel programming is also supported through the Array.Parallel functional programming operators in the F# standard library, direct use of the System.Threading.Tasks task programming model, the direct use of .NET thread pool and .NET threads and through dynamic translation of F# code to alternative parallel execution engines such as GPU code.

    The F# type system supports units of measure checking for numbers. The units of measure feature integrates with F# type inference to require minimal type annotations in user code.

    F# allows some forms of syntax customizing via metaprogramming to support embedding custom domain-specific languages within the F# language, particularly through computation expressions.

    F# includes a feature for run-time meta-programming called quotations. A quotation expression evaluates to an abstract syntax tree representation of the F# expressions. Similarly, definitions labelled with the [<ReflectedDefinition>] attribute can also be accessed in their quotation form. F# quotations are used for various purposes including to compile F# code into JavaScript and GPU code. Quotations represent their F# code expressions as data for use by other parts of the program while requiring it to be syntactically correct F# code.

    F# 3.0 introduced a form of compile-time meta-programming through statically extensible type generation called F# type providers. F# type providers allow the F# compiler and tools to be extended with components that provide type information to the compiler on-demand at compile time. F# type providers have been used to give strongly typed access to connected information sources in a scalable way, including to the Freebase knowledge graph.

    In F# 3.0 the F# quotation and computation expression features are combined to implement LINQ queries. For example:

    // Use the OData type provider to create types that can be used to access the Northwind database.
open Microsoft.FSharp.Data.TypeProviders
type Northwind = ODataService<"http://services.odata.org/Northwind/Northwind.svc">
let db = Northwind.GetDataContext
// A query expression.
let query1 = query { for customer in db.Customers do
                     select customer }

    The combination of type providers, queries and strongly typed functional programming is known as information rich programming.

    F# supports a variation of the Actor programming model through the in-memory implementation of lightweight asynchronous agents. For example, the following code defines an agent and posts 2 messages:

    let counter =
    MailboxProcessor.Startfun inbox ->
        let rec loop n =
            async { do printfn "n = %d, waiting..." n
                    let! msg = inbox.Receive
                    return! loopn+msg }
        loop 0