Interactive programming with F#
F# Interactive (dotnet fsi) is used to run F# code interactively at the console, or to execute F# scripts. In other words, F# interactive executes a REPL (Read, Evaluate, Print Loop) for F#.
To run F# Interactive from the console, run dotnet fsi
. You will find dotnet fsi
in any .NET SDK.
Note
If you intend to use F# interactive under .NET Framework runtime, you'll need the Visual Studio Build Tools or an edition of Visual Studio installed, and invoke the FsiAnyCPU.exe
command from a "Developer Command Prompt" or simply make FsiAnyCPU.exe
available in the PATH
environment variable, in place of dotnet fsi
command line.
Tooling supports defining version F# Interactive runtime:
- In Visual Studio: In the menu bar, Tools / Options then F# Tools / F# Interactive, and adjust Use .NET Core Scripting.
- In Visual Studio Code (ionide extension): In the command palette, Preferences: Open User Settings, then Extensions / F# / FSharp: Fsi Sdk File Path.
For information about available command-line options, see F# Interactive Options.
Executing code directly in F# Interactive
Because F# Interactive is a REPL (read-eval-print loop), you can execute code interactively in it. Here is an example of an interactive session after executing dotnet fsi
from the command line:
Microsoft (R) F# Interactive version 11.0.0.0 for F# 5.0
Copyright (c) Microsoft Corporation. All Rights Reserved.
For help type #help;;
> let square x = x * x;;
val square : x:int -> int
> square 12;;
val it : int = 144
> printfn "Hello, FSI!"
- ;;
Hello, FSI!
val it : unit = ()
You'll notice two main things:
- All code must be terminated with a double semicolon (
;;
) to be evaluated - Code is evaluated and stored in an
it
value. You can referenceit
interactively.
F# Interactive also supports multi-line input. You just need to terminate your submission with a double semicolon (;;
). Consider the following snippet that has been pasted into and evaluated by F# Interactive:
> let getOddSquares xs =
- xs
- |> List.filter (fun x -> x % 2 <> 0)
- |> List.map (fun x -> x * x)
-
- printfn "%A" (getOddSquares [1..10]);;
[1; 9; 25; 49; 81]
val getOddSquares : xs:int list -> int list
val it : unit = ()
>
The code's formatting is preserved, and there is a double semicolon (;;
) terminating the input. F# Interactive then evaluated the code and printed the results!
Scripting with F#
Evaluating code interactively in F# Interactive can be a great learning tool, but you'll quickly find that it's not as productive as writing code in a normal editor. To support normal code editing, you can write F# scripts.
Scripts use the file extension .fsx. Instead of compiling source code and then later running the compiled assembly, you can just run dotnet fsi and specify the filename of the script of F# source code, and F# interactive reads the code and executes it in real time. For example, consider the following script called Script.fsx
:
let getOddSquares xs =
xs
|> List.filter (fun x -> x % 2 <> 0)
|> List.map (fun x -> x * x)
printfn "%A" (getOddSquares [1..10])
When this file is created in your machine, you can run it with dotnet fsi
and see the output directly in your terminal window:
dotnet fsi Script.fsx
[1; 9; 25; 49; 81]
F# scripting is natively supported in Visual Studio and Visual Studio Code.
Referencing packages in F# Interactive
Note
Package management system is extensible, see more about the plugins and extension mechanism.
Since 5.0 release of the language, F# Interactive supports referencing packages through an extensibility mechanism; out of the box, it can reference NuGet packages with the #r "nuget:"
syntax and an optional version:
#r "nuget: Newtonsoft.Json"
open Newtonsoft.Json
let data = {| Name = "Don Syme"; Occupation = "F# Creator" |}
JsonConvert.SerializeObject(data)
If a version is not specified, the highest available non-preview package is taken. To reference a specific version, introduce the version via a comma. This can be handy when referencing a preview version of a package. For example, consider this script using a preview version of DiffSharp:
#r "nuget: DiffSharp-lite, 1.0.0-preview-328097867"
open DiffSharp
// A 1D tensor
let t1 = dsharp.tensor [ 0.0 .. 0.2 .. 1.0 ]
// A 2x2 tensor
let t2 = dsharp.tensor [ [ 0; 1 ]; [ 2; 2 ] ]
// Define a scalar-to-scalar function
let f (x: Tensor) = sin (sqrt x)
printfn $"{f (dsharp.tensor 1.2)}"
Specifying a package source
You can also specify a package source with the #i
command. The following example specifies a remote and a local source:
#i "nuget: https://my-remote-package-source/index.json"
#i """nuget: C:\path\to\my\local\source"""
This will tell the resolution engine under the covers to also take into account the remote and/or local sources added to a script.
You can specify as many package references as you like in a script.
Note
There's currently a limitation for scripts that use framework references (e.g.Microsoft.NET.Sdk.Web
or Microsoft.NET.Sdk.WindowsDesktop
). Packages like Saturn, Giraffe, WinForms are not available. This is being tracked in issue #9417.
WinForms, still works in the .NET Framework version of F# Interactive.
To load additional extensions beside those shipped with the SDK and/or with your tooling, use the --compilertool:<extensionsfolderpath>
flag as argument for F# Interactive session (or in your tooling settings).
Referencing assemblies on disk with F# interactive
Alternatively, if you have an assembly on disk and wish to reference that in a script, you can use the #r
syntax to specify an assembly. Consider the following code in a project compiled into MyAssembly.dll
:
// MyAssembly.fs
module MyAssembly
let myFunction x y = x + 2 * y
Once compiled, you can reference it in a file called Script.fsx
like so:
#r "path/to/MyAssembly.dll"
printfn $"{MyAssembly.myFunction 10 40}"
The output is as follows:
dotnet fsi Script.fsx
90
You can specify as many assembly references as you like in a script.
Loading other scripts
When scripting, it can often be helpful to use different scripts for different tasks. Sometimes you may want to reuse code from one script in another. Rather than copy-pasting its contents into your file, you can simply load and evaluate it with #load
.
Consider the following Script1.fsx
:
let square x = x * x
And the consuming file, Script2.fsx
:
#load "Script1.fsx"
open Script1
printfn $"%d{square 12}"
You can evaluate Script2.fsx
like so:
dotnet fsi Script2.fsx
144
You can specify as many #load
directives as you like in a script.
Note
The open Script1
declaration is required. This is because constructs in an F# script are compiled into a top-level module that is the name of the script file it is in. If the script file has a lowercase name such as script3.fsx
then the implied module name is automatically capitalized, and you will need to use open Script3
. If you would like a loadable-script to define constructs in a specific namespace of module you can include a namespace of module declaration, for example:
module MyScriptLibrary
Using the fsi
object in F# code
F# scripts have access to a custom fsi
object that represents the F# Interactive session. It allows you to customize things like output formatting. It is also how you can access command-line arguments.
The following example shows how to get and use command-line arguments:
let args = fsi.CommandLineArgs
for arg in args do
printfn $"{arg}"
When evaluated, it prints all arguments. The first argument is always the name of the script that is evaluated:
dotnet fsi Script1.fsx hello world from fsi
Script1.fsx
hello
world
from
fsi
You can also use System.Environment.GetCommandLineArgs()
to access the same arguments.
F# Interactive directive reference
The #r
and #load
directives seen previously are only available in F# Interactive. There are several directives only available in F# Interactive:
Directive | Description |
---|---|
#r "nuget:..." |
References a package from NuGet |
#r "extname:..." |
Reference a package from extname extension[^1] (such as paket ) |
#r "assembly-name.dll" |
References an assembly on disk |
#load "file-name.fsx" |
Reads a source file, compiles it, and runs it. |
#help |
Displays information about available directives or documentation for specific functions. |
#I |
Specifies an assembly search path in quotation marks. |
#quit |
Terminates an F# Interactive session. |
#time on or #time off |
By itself, #time toggles whether to display performance information. When it is on , F# Interactive measures real time, CPU time, and garbage collection information for each section of code that is interpreted and executed. |
[^1]: More about F# Interactive extensions.
When you specify files or paths in F# Interactive, a string literal is expected. Therefore, files and paths must be in quotation marks, and the usual escape characters apply. You can use the @
character to cause F# Interactive to interpret a string that contains a path as a verbatim string. This causes F# Interactive to ignore any escape characters.
For other cases, quotation marks are optional, starting with F# 9.
Extended #help directive
The #help
directive now supports displaying documentation for specific functions. You can pass the name of the function directly to retrieve details.
#help List.map;;
The output is as follows:
Description:
Builds a new collection whose elements are the results of applying the given function
to each of the elements of the collection.
Parameters:
- mapping: The function to transform elements from the input list.
- list: The input list.
Returns:
The list of transformed elements.
Examples:
let inputs = [ "a"; "bbb"; "cc" ]
inputs |> List.map (fun x -> x.Length)
// Evaluates to [ 1; 3; 2 ]
Full name: Microsoft.FSharp.Collections.ListModule.map
Assembly: FSharp.Core.dll
This enhancement makes it easier to explore and understand F# libraries interactively.
For more details, refer to the official devblog.
Interactive and compiled preprocessor directives
When you compile code in F# Interactive, whether you are running interactively or running a script, the symbol INTERACTIVE is defined. When you compile code in the compiler, the symbol COMPILED is defined. Thus, if code needs to be different in compiled and interactive modes, you can use these preprocessor directives for conditional compilation to determine which to use. For example:
#if INTERACTIVE
// Some code that executes only in FSI
// ...
#endif
Using F# Interactive in Visual Studio
To run F# Interactive through Visual Studio, you can click the appropriate toolbar button labeled F# Interactive, or use the keys Ctrl+Alt+F. Doing this will open the interactive window, a tool window running an F# Interactive session. You can also select some code that you want to run in the interactive window and hit the key combination Alt+Enter. F# Interactive starts in a tool window labeled F# Interactive. When you use this key combination, make sure that the editor window has the focus.
Whether you are using the console or Visual Studio, a command prompt appears and the interpreter awaits your input. You can enter code just as you would in a code file. To compile and execute the code, enter two semicolons (;;) to terminate a line or several lines of input.
F# Interactive attempts to compile the code and, if successful, it executes the code and prints the signature of the types and values that it compiled. If errors occur, the interpreter prints the error messages.
Code entered in the same session has access to any constructs entered previously, so you can build up programs. An extensive buffer in the tool window allows you to copy the code into a file if needed.
When run in Visual Studio, F# Interactive runs independently of your project, so, for example, you cannot use constructs defined in your project in F# Interactive unless you copy the code for the function into the interactive window.
You can control the F# Interactive command-line arguments (options) by adjusting the settings. On the Tools menu, select Options..., and then expand F# Tools. The two settings that you can change are the F# Interactive options and the 64-bit F# Interactive setting, which is relevant only if you are running F# Interactive on a 64-bit machine. This setting determines whether you want to run the dedicated 64-bit version of fsi.exe or fsianycpu.exe, which uses the machine architecture to determine whether to run as a 32-bit or 64-bit process.
Related articles
Title | Description |
---|---|
F# Interactive Options | Describes command-line syntax and options for the F# Interactive, fsi.exe. |