Functional programming is a style of programming which—unlike imperative programming—models computations as the evaluation of expressions. This article is meant to describe it briefly; however, the best way to understand functional programming is to learn the basics of one of the functional programming languages (learn Haskell).
1 What is functional programming?
Functional programming means that programs are executed by evaluating expressions. This contrasts with imperative programming where programs are composed of statements which change global state when executed. Functional programming, on the other hand, avoids using state and mutable data.
Functional programming requires that functions are first-class, which means that they are treated like any other values and can be passed as arguments to other functions or be returned as a result of a function. Being first-class also means that it is possible to define and manipulate functions nested in code blocks. Special attention needs to be given to nested functions, called closures, that reference local variables from their scope. If such a function escapes their block after being returned from it, the local variables must be retained in memory, as they might be needed later when the function is called. Usually it is not possible to determine statically the moment of release, which means that an automatic memory management technique has to be used.
2 Functional vs imperative languages
Many programming languages support programming in both functional and imperative style but each language has syntax and facilities that are optimised only for one of these styles. Often, code written in one particular style is executed more efficiently by the implementation than if written in the other. In addition to that, coding conventions and libraries often force the programmer towards one of the styles. Therefore, programming languages are categorized into functional and imperative ones.
The following table shows which languages support functional programming (by supporting closures) and for which the functional style is the dominant one.
3 Features of functional languages
3.1 Higher-order functionsHigher-order functions (HOFs) are functions that take other functions as their arguments. A basic example of a HOF is
subtractTwoFromList l = map (\x -> x - 2) l
We can generalize this function to subtract any given number:
subtractFromList l y = map (\x -> x - y) l
Higher-order functions are very useful for refactoring code and reduce the amount of repetition. For example, typically most for loops can be expressed using maps or folds. Custom iteration schemes, such as parallel loops, can be easily expressed using HOFs.
Higher-order functions are often used to implement domain-specific languages embedded in Haskell as combinator libraries.
Higher-order functions can be usually simulated in object-oriented languages by functions that take function-objects, also called functors (note that functor in Haskell is an entirely different concept). Variables from the scope of the call can be bound inside the function-object which acts as if it were a closure. This way of simulating HOFs is, however, very verbose and requires declaring a new class each time we want to use a HOF.
Some functional languages allow expressions to yield actions in addition to return values. These actions are called side effects to emphasize that the return value is the most important outcome of a function (as opposed to the case in imperative programming). Languages that prohibit side effects are called pure. Even though some functional languages are impure they often contain a pure subset that is also useful as a programming language. It is usually beneficial to write a significant part of a functional program in a purely functional fashion and keep the code involving state and I/O to the minimum as impure code is more prone to errors.
3.2.1 Immutable data
Purely functional programmes operate only on immutable data. This is possible because on each modification a new version of a data structure is created and the old one is preserved. Therefore, data structures are persistent as it is possible to refer also to old versions of them. If there are no more references to the old version the unreferred data can be collected by automatic memory management, such as a garbage collector. Often, bigger data structures share their parts between versions and so do not consume as much memory as they would if all versions were stored separately.
3.2.2 Referential transparencyPure computations yield the same value each time they are invoked. This property is called referential transparency and makes possible to conduct equational reasoning on the code. For instance if
3.2.3 Lazy evaluation
Since pure computations are referentially transparent they can be performed at any time and still yield the same result. This makes it possible to defer the computation of values until they are needed, that is, to compute them lazily. Lazy evaluation avoids unnecessary computations and allows, for instance, to create lazy data structures that are built on the fly.
3.2.4 Purity and effects
Even though purely functional programming is very beneficial, the programmer might want to use features that are not available in pure programs, like efficient mutable arrays or convenient I/O. There are two approaches to this problem.
184.108.40.206 Side effects in the language
Some functional languages extend their purely functional core with side effects. The programmer must be careful not to use impure functions in places where only pure functions are expected.
220.127.116.11 Side effects through monads
Another way of introducing side effects to a pure language is to simulate them using monads. While the language remains pure and referentially transparent, monads can provide implicit state by threading it inside them. The compiler does not even have to 'know' about the imperative features because the language itself remains pure, however usually the implementations do 'know' about them due to the efficiency reasons, for instance to provide O(1) mutable arrays.
Allowing side effects only through monads and keeping the language pure makes it possible to have lazy evaluation that does not conflict with the effects of impure code. Even though the expressions are evaluated lazily, some parts of them are forced by monads to be evaluated in a specific order and the effects are properly sequenced.
Recursion is heavily used in functional programming as it is the canonical and often the only way to iterate. Loops are naturally expressed using tail recursion.
4 Benefits of functional programming
Functional programming is known to provide better support for structured programming than imperative programming. To make a program structured it is necessary to develop abstractions and split it into components which interface each other with those abstractions. Functional languages aid this by making it easy to create clean and simple abstractions. It is easy, for instance, to abstract out a recurring piece of code by creating a higher-order function which will make the resulting code more declarative and comprehensible.
Functional programs are often shorter and easier to understand than their imperative counterparts. Since various studies have shown that the average programmer's productivity in terms of lines of code is more or less the same for any programming language, this translates also to higher productivity.