Elm (programming language)

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Elm

The Elm tangram
Paradigm	functional
Family	Haskell
Designed by	Evan Czaplicki
First appeared	March 30, 2012; 13 years ago (2012-03-30)[1]
Stable release	0.19.1 / October 21, 2019; 5 years ago (2019-10-21)[2]
Typing discipline	static, strong, inferred
Platform	x86-64
OS	macOS, Windows
License	Permissive (Revised BSD)[3]
Filename extensions	.elm
Website	elm-lang.org
Influenced by
Haskell, Standard ML, OCaml, F#
Influenced
Redux,[4] Rust,[5] Vue,[6] Roc,[7] Derw,[8] Gren[9]

Elm is a domain-specific programming language for declaratively creating web browser-based graphical user interfaces. Elm is purely functional, and is developed with emphasis on usability, performance, and robustness. It advertises "no runtime exceptions in practice",^[10] made possible by the Elm compiler's static type checking.

Elm was initially designed by Evan Czaplicki as his thesis in 2012.^[11] The first release of Elm came with many examples and an online editor that made it easy to try out in a web browser.^[12] Czaplicki joined Prezi in 2013 to work on Elm,^[13] and in 2016 moved to NoRedInk as an Open Source Engineer, also starting the Elm Software Foundation.^[14]

The initial implementation of the Elm compiler targets HyperText Markup Language (HTML), Cascading Style Sheets (CSS), and JavaScript.^[15] The set of core tools has continued to expand, now including a read–eval–print loop (REPL),^[16] package manager,^[17] time-travelling debugger,^[18] and installers for macOS and Windows.^[19] Elm also has an ecosystem of community created libraries,^[20] and Ellie, an advanced online editor that allows saved work and including community libraries.^[21]

Elm has a small set of language constructs, including traditional if-expressions, let-expressions for storing local values, and case-expressions for pattern matching.^[22] As a functional language, it supports anonymous functions, functions as arguments, and functions can return functions, the latter often by partial application of curried functions. Functions are called by value. Its semantics include immutable values, stateless functions, and static typing with type inference. Elm programs render HTML through a virtual DOM, and may interoperate with other code by using "JavaScript as a service".

All values in Elm are immutable, meaning that a value cannot be modified after it is created. Elm uses persistent data structures to implement its arrays, sets, and dictionaries in the standard library.^[23]

Elm is statically typed. Type annotations are optional (due to type inference) but strongly encouraged. Annotations exist on the line above the definition (unlike C-family languages where types and names are interspersed). Elm uses a single colon to mean "has type".

Types include primitives like integers and strings, and basic data structures such as lists, tuples, and records. Functions have types written with arrows, for example round : Float -> Int. Custom types allow the programmer to create custom types to represent data in a way that matches the problem domain.^[24]

Types can refer to other types, for example a List Int. Types are always capitalized; lowercase names are type variables. For example, a List a is a list of values of unknown type. It is the type of the empty list and of the argument to List.length, which is agnostic to the list's elements. There are a few special types that programmers create to interact with the Elm runtime. For example, Html Msg represents a (virtual) DOM tree whose event handlers all produce messages of type Msg.

Rather than allow any value to be implicitly nullable (such as JavaScript's undefined or a null pointer), Elm's standard library defines a Maybe a type. Code that produces or handles an optional value does so explicitly using this type, and all other code is guaranteed a value of the claimed type is actually present.

Elm provides a limited number of built-in type classes: number which includes Int and Float to facilitate the use of numeric operators such as (+) or (*), comparable which includes numbers, characters, strings, lists of comparable things, and tuples of comparable things to facilitate the use of comparison operators, and appendable which includes strings and lists to facilitate concatenation with (++). Elm does not provide a mechanism to include custom types into these type classes or create new type classes (see Limits).

Elm has a module system that allows users to break their code into smaller parts called modules. Modules can hide implementation details such as helper functions, and group related code together. Modules serve as a namespace for imported code, such as Bitwise.and. Third party libraries (or packages) consist of one or more modules, and are available from the Elm Public Library. All libraries are versioned according to semver, which is enforced by the compiler and other tools. That is, removing a function or changing its type can only be done in a major release.

Elm uses an abstraction called ports to communicate with JavaScript.^[25] It allows values to flow in and out of Elm programs, making it possible to communicate between Elm and JavaScript.

Elm has a library called elm/html that a programmer can use to write HTML and CSS within Elm.^[26] It uses a virtual DOM approach to make updates efficient.^[27]

Elm does not officially support server-side development. Czaplicki does consider it a primary goal at this point, but public progress on this front has been slow. Nevertheless, there are several independent projects which attempt to explore Elm on the backend.

The primary production-ready full-stack Elm platform is Lamdera, an open-core "unfork" of Elm.^[28][29][30] Czaplicki has also teased Elm Studio, a potential alternative to Lamdera, but it isn't available to the public yet.^[31] Current speculation is that Elm Studio will use a future version of Elm that targets C, uses Emscripten to compile to WASM, and supports type-safe Postgres table generation.^[32][33]

For full-stack frameworks, as opposed to BaaS products, elm-pages is perhaps the most popular fully open-source option.^[34] It does not extend the Elm language, but just runs the compiled JS on Node.js. It also supports scripting. There is also Pine, an Elm to .NET compiler, which allows safe interop with C#, F#, and other CLR languages.^[35]

There were also some attempts in Elm versions prior to 0.19.0 to use the BEAM (Erlang virtual machine) to run Elm, but they are stuck due to the removal of native code in 0.19.0 and changes to the package manager. One of the projects executed Elm directly on the environment,^[36] while another one compiled it to Elixir.^[37]

Finally, the Gren programming language started out a fork of Elm primarily focused on backend support, although its goals have since shifted.

The Elm Architecture is a software design pattern and as a TLA called TEA pattern for building interactive web applications. Elm applications are naturally constructed in that way, but other projects may find the concept useful.

An Elm program is always split into three parts:

• Model - the state of the application
• View - a function that turns the model into HTML
• Update - a function that updates the model based on messages

Those are the core of the Elm Architecture.

For example, imagine an application that displays a number and a button that increments the number when pressed.^[38] In this case, all we need to store is one number, so our model can be as simple as type alias Model = Int. The view function would be defined with the Html library and display the number and button. For the number to be updated, we need to be able to send a message to the update function, which is done through a custom type such as type Msg = Increase. The Increase value is attached to the button defined in the view function such that when the button is clicked by a user, Increase is passed on to the update function, which can update the model by increasing the number.

In the Elm Architecture, sending messages to update is the only way to change the state. In more sophisticated applications, messages may come from various sources: user interaction, initialization of the model, internal calls from update, subscriptions to external events (window resize, system clock, JavaScript interop...) and URL changes and requests.

Elm does not support higher-kinded polymorphism,^[39] which related languages Haskell, Scala and PureScript offer, nor does Elm support the creation of type classes.

This means that, for example, Elm does not have a generic map function which works across multiple data structures such as List and Set. In Elm, such functions are typically invoked qualified by their module name, for example calling List.map and Set.map. In Haskell or PureScript, there would be only one function map. This is a known feature request that is on Czaplicki's rough roadmap since at least 2015.^[40] On the other hand, implementations of TEA pattern in advanced languages like Scala does not suffer from such limitations and can benefit from Scala's type classes, type-level and kind-level programming constructs.^[41]

Another outcome is a large amount of boilerplate code in medium to large size projects as illustrated by the author of "Elm in Action," a former Elm core team member, in his single page application example^[42] with almost identical fragments being repeated in update, view, subscriptions, route parsing and building functions.

-- This is a single line comment.

{-
This is a multi-line comment.
It is {- nestable. -}
-}

-- Here we define a value named `greeting`. The type is inferred as a `String`.
greeting =
    "Hello World!"

-- It is best to add type annotations to top-level declarations.
hello : String
hello =
    "Hi there."

-- Functions are declared the same way, with arguments following the function name.
add x y =
    x + y

-- Again, it is best to add type annotations.
hypotenuse : Float -> Float -> Float
hypotenuse a b =
    sqrt (a^2 + b^2)

-- We can create lambda functions with the `\[arg] -> [expression]` syntax.
hello : String -> String
hello = \s -> "Hi, " ++ s

-- Function declarations may have the anonymous parameter names denoted by `_`, 
-- which are matched but not used in the body. 
const : a -> b -> a
const k _ = k

-- Functions are also curried; here we've curried the multiplication 
-- infix operator with a `2`
multiplyBy2 : number -> number
multiplyBy2 =
    (*) 2

-- If-expressions are used to branch on `Bool` values
absoluteValue : number -> number
absoluteValue number =
    if number < 0 then negate number else number

-- Records are used to hold values with named fields
book : { title : String, author : String, pages : Int }
book =
    { title = "Steppenwolf"
    , author = "Hesse"
    , pages = 237 
    }

-- Record access is done with `.`
title : String
title =
    book.title

-- Record access `.` can also be used as a function
author : String
author =
    .author book

-- We can create tagged unions with the `type` keyword.
-- The following value represents a binary tree.
type Tree a
    = Empty
    | Node a (Tree a) (Tree a)

-- It is possible to inspect these types with case-expressions.
depth : Tree a -> Int
depth tree =
    case tree of
        Empty -> 0
        Node _ left right ->
            1 + max (depth left) (depth right)

• PureScript – A strongly-typed, purely-functional programming language that compiles to JavaScript
• Reason – A syntax extension and toolchain for OCaml that can also transpile to JavaScript

• Official website
• Elm on GitHub