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{{inline citations|date=September 2013}}
In [[mathematics]] and [[computer science]], a '''higher-order function''' (also '''functional form''', '''functional''' or '''functor''') is a [[function (mathematics)|function]] that does at least one of the following:
*takes one or more functions as an input
*outputs a function
All other functions are ''first-order functions''.  In mathematics higher-order functions are also known as ''[[operator (mathematics)|operators]]'' or ''[[functional (mathematics)|functionals]]''.  The [[derivative]] in [[calculus]] is a common example, since it maps a function to another function.
 
In the [[lambda calculus|untyped lambda calculus]], all functions are higher-order; in a [[typed lambda calculus]], from which most [[functional programming]] languages are derived, higher-order functions are values with types of the form <math>(\tau_1\to\tau_2)\to\tau_3</math>.
 
The <code>[[map (higher-order function)|map]]</code> function, found in many functional programming languages, is one example of a higher-order function.  It takes as arguments a function ''f'' and a list of elements, and as the result, returns a new list with ''f'' applied to each element from the list. Another very common kind of higher-order function in those languages which support them are sorting functions which take a comparison function as a parameter, allowing the programmer to separate the sorting algorithm from the comparisons of the items being sorted.  The [[C (programming language)|C]] standard [[function (computer science)|function]] <code>qsort</code> is an example of this.
 
Other examples of higher-order functions include [[fold (higher-order function)|fold]], [[function composition (computer science)|function composition]], [[integral|integration]], and the constant-function function λ''x''.λ''y''.''x''.
 
==Example==
''The following examples are not intended to compare and contrast programming languages, since each program performs a different task.''
 
This [[Python (programming language)|Python]] program defines the higher-order function <code>twice</code> which takes a function and an arbitrary object (here a number), and applies the function to the object twice. This example prints 13: twice(f, 7) = f(f(7)) = (7 + 3) + 3.
<source lang="python">
def f(x):
    return x + 3
 
def twice(function, x):
    return function(function(x))
 
print(twice(f, 7))
</source>
This [[Haskell (programming language)|Haskell]] code is the equivalent of the Python program above.
<source lang="haskell">
f = (+3)
twice function = function . function
main = print (twice f 7)
</source>
In this [[Scheme (programming language)|Scheme]] example the higher-order function <code>g()</code> takes a number and returns a function. The function <code>a()</code> takes a number and returns that number plus 7 (e.g. ''a''(3)=10).
<source lang="scheme">
(define (g x)
  (lambda (y) (+ x y)))
(define a (g 7))
(display (a 3))
</source>
 
In this [[Erlang (programming language)|Erlang]] example the higher-order function <code>or_else</code>/2 takes a list of functions (<code>Fs</code>) and argument (<code>X</code>). It evaluates the function <code>F</code> with the argument <code>X</code> as argument. If the function <code>F</code> returns false then the next function in <code>Fs</code> will be evaluated. If the function <code>F</code> returns <code>{false,Y}</code> then the next function in <code>Fs</code> with argument <code>Y</code> will be evaluated. If the function <code>F</code> returns <code>R</code> the higher-order function <code>or_else</code>/2 will return <code>R</code>. Note that <code>X</code>, <code>Y</code>, and <code>R</code> can be functions. The example returns <code>false</code>.
<source lang="erlang">
or_else([], _) -> false;
or_else([F | Fs], X) -> or_else(Fs, X, F(X)).
 
or_else(Fs, X, false) -> or_else(Fs, X);
or_else(Fs, _, {false, Y}) -> or_else(Fs, Y);
or_else(_, _, R) -> R.
 
or_else([fun erlang:is_integer/1, fun erlang:is_atom/1, fun erlang:is_list/1],3.23).
</source>
 
In this [[JavaScript]] example the higher-order function <code>ArrayForEach</code> takes an array and a method in as arguments and calls the method on every element in the array. That is, it [[Map (higher-order function)|Map]]s the function over the array elements.
<source lang="javascript">
function ArrayForEach(array, func) {
    for (var i = 0; i < array.length; i++) {
        if (i in array) {
            func(array[i]);
        }
    }
}
 
function log(msg) {
    console.log(msg);
}
 
ArrayForEach([1,2,3,4,5], log);
</source>
 
This [[Ruby  (programming language)|Ruby ]] code is the equivalent of the Python program above.
<source lang="ruby">
f1 = ->(x){ x + 3 }
def twice(f, x); f.call(f.call(x)) end
 
print twice(f1, 7)
</source>
 
==Alternatives==
 
In programming languages that support [[function pointer]]s, one can emulate higher-order functions to some extent. Such languages include the [[C (programming language)|C]] and [[C++]] family. An example is the following C code which computes an approximation of the integral of an arbitrary function:
 
<source lang=c>
// Compute the integral of f() within the interval [a,b]
double integral(double (*f)(double x), double a, double b)
{
    double  sum, dt;
    int    i;
 
    // Numerical integration: 0th order approximation
    sum = 0.0;
    dt = (b - a) / 100.0;
    for (i = 0;  i < 100;  i++)
        sum += (*f)(i * dt + a) * dt;
 
    return sum;
}
</source>
 
Another example is the function [[qsort]] from C standard library.
 
In other [[imperative programming]] languages it is possible to achieve some of the same algorithmic results as are obtained through use of higher-order functions by dynamically executing code (sometimes called "Eval" or "Execute" operations) in the scope of evaluation. There can be significant drawbacks to this approach:
*The argument code to be executed is usually not [[type system#Static typing|statically typed]]; these languages generally rely on [[type system#Dynamic typing|dynamic typing]] to determine the well-formedness and safety of the code to be executed.
*The argument is usually provided as a string, the value of which may not be known until run-time.  This string must either be compiled during program execution (using [[just-in-time compilation]]) or evaluated by [[interpreter (computing)|interpretation]], causing some added overhead at run-time, and usually generating less efficient code.
 
[[Macro (computer science)|macros]] can also be used to achieve some of the effects of higher order functions.  However, macros cannot easily avoid the problem of variable capture; they may also result in large amounts of duplicated code, which can be more difficult for a compiler to optimize.  Macros are generally not strongly typed, although they may produce strongly typed code.
 
In [[object-oriented programming]] languages that do not support higher-order functions, [[object (computer science)|objects]] can be an effective substitute. An object's [[method (computer science)|methods]] act in essence like functions, and a method may accept objects as parameters and produce objects as return values. Objects often carry added run-time overhead compared to pure functions, however, and added [[boilerplate code]] for defining and instantiating an object and its method(s). Languages that permit [[stack-based memory allocation|stack]]-based (versus [[dynamic memory allocation|heap]]-based) objects or [[structs]] can provide more flexibility with this method.
 
An example of using a simple stack based record in [[Free Pascal]] with a function that returns a function:
 
<source lang=pascal>
program example;
 
type
  int = integer;
  Txy = record x, y: int; end;
  Tf = function (xy: Txy): int;
   
function f(xy: Txy): int;
begin
  Result := xy.y + xy.x;
end;
 
function g(func: Tf): Tf;
begin
  result := func;
end;
 
var
  a: Tf;
  xy: Txy = (x: 3; y: 7);
 
begin 
  a := g(@f);      // return a function to "a"
  writeln(a(xy)); // prints 10
end.
</source>
 
The function <code>a()</code> takes a <code>Txy</code> record as input and returns the integer value of the sum of the record's <code>x</code> and <code>y</code> fields (3 + 7).
 
==See also==
*[[First-class function]]
*[[Combinatory logic]]
*[[Function-level programming]]
*[[Functional programming]]
*[[Kappa calculus]] - a formalism for functions which ''excludes'' higher-order functions
*[[Strategy pattern]]
*[[Higher order message]]s
 
==External links==
*[http://ergodicity.iamganesh.com/2006/08/07/higher-order-functions/ Higher-order functions and variational calculus]
*[http://boost.org/doc/html/lambda.html Boost Lambda Library for C++]
*[http://hop.perl.plover.com/book/ Higher Order Perl]
 
[[Category:Functional programming]]
[[Category:Lambda calculus]]
[[Category:Higher-order functions| ]]
[[Category:Subroutines]]
[[Category:Articles with example Python code]]
[[Category:Articles with example Haskell code]]
[[Category:Articles with example Scheme code]]
[[Category:Articles with example Erlang code]]
[[Category:Articles with example JavaScript code]]
[[Category:Articles with example C code]]
[[Category:Articles with example Pascal code]]

Revision as of 00:35, 1 February 2014

Library Technician Anton from Strathroy, has many passions that include r/c helicopters, property developers in condo new launch singapore and coin collecting. Finds the beauty in planing a trip to spots around the globe, recently only returning from Old Town of Corfu. Template:Inline citations In mathematics and computer science, a higher-order function (also functional form, functional or functor) is a function that does at least one of the following:

  • takes one or more functions as an input
  • outputs a function

All other functions are first-order functions. In mathematics higher-order functions are also known as operators or functionals. The derivative in calculus is a common example, since it maps a function to another function.

In the untyped lambda calculus, all functions are higher-order; in a typed lambda calculus, from which most functional programming languages are derived, higher-order functions are values with types of the form (τ1τ2)τ3.

The map function, found in many functional programming languages, is one example of a higher-order function. It takes as arguments a function f and a list of elements, and as the result, returns a new list with f applied to each element from the list. Another very common kind of higher-order function in those languages which support them are sorting functions which take a comparison function as a parameter, allowing the programmer to separate the sorting algorithm from the comparisons of the items being sorted. The C standard function qsort is an example of this.

Other examples of higher-order functions include fold, function composition, integration, and the constant-function function λxy.x.

Example

The following examples are not intended to compare and contrast programming languages, since each program performs a different task.

This Python program defines the higher-order function twice which takes a function and an arbitrary object (here a number), and applies the function to the object twice. This example prints 13: twice(f, 7) = f(f(7)) = (7 + 3) + 3.

def f(x):
    return x + 3

def twice(function, x):
    return function(function(x))

print(twice(f, 7))

This Haskell code is the equivalent of the Python program above.

f = (+3)
twice function = function . function
main = print (twice f 7)

In this Scheme example the higher-order function g() takes a number and returns a function. The function a() takes a number and returns that number plus 7 (e.g. a(3)=10).

(define (g x)
  (lambda (y) (+ x y)))
(define a (g 7))
(display (a 3))

In this Erlang example the higher-order function or_else/2 takes a list of functions (Fs) and argument (X). It evaluates the function F with the argument X as argument. If the function F returns false then the next function in Fs will be evaluated. If the function F returns {false,Y} then the next function in Fs with argument Y will be evaluated. If the function F returns R the higher-order function or_else/2 will return R. Note that X, Y, and R can be functions. The example returns false.

or_else([], _) -> false;
or_else([F | Fs], X) -> or_else(Fs, X, F(X)).

or_else(Fs, X, false) -> or_else(Fs, X);
or_else(Fs, _, {false, Y}) -> or_else(Fs, Y);
or_else(_, _, R) -> R.

or_else([fun erlang:is_integer/1, fun erlang:is_atom/1, fun erlang:is_list/1],3.23).

In this JavaScript example the higher-order function ArrayForEach takes an array and a method in as arguments and calls the method on every element in the array. That is, it Maps the function over the array elements.

function ArrayForEach(array, func) {
    for (var i = 0; i < array.length; i++) {
        if (i in array) {
            func(array[i]);
        }
    }
}

function log(msg) {
    console.log(msg);
}

ArrayForEach([1,2,3,4,5], log);

This Ruby code is the equivalent of the Python program above.

f1 = ->(x){ x + 3 } 
def twice(f, x); f.call(f.call(x)) end

print twice(f1, 7)

Alternatives

In programming languages that support function pointers, one can emulate higher-order functions to some extent. Such languages include the C and C++ family. An example is the following C code which computes an approximation of the integral of an arbitrary function:

// Compute the integral of f() within the interval [a,b]
double integral(double (*f)(double x), double a, double b)
{
    double  sum, dt;
    int     i;

    // Numerical integration: 0th order approximation
    sum = 0.0;
    dt = (b - a) / 100.0;
    for (i = 0;  i < 100;  i++)
        sum += (*f)(i * dt + a) * dt;

    return sum;
}

Another example is the function qsort from C standard library.

In other imperative programming languages it is possible to achieve some of the same algorithmic results as are obtained through use of higher-order functions by dynamically executing code (sometimes called "Eval" or "Execute" operations) in the scope of evaluation. There can be significant drawbacks to this approach:

  • The argument code to be executed is usually not statically typed; these languages generally rely on dynamic typing to determine the well-formedness and safety of the code to be executed.
  • The argument is usually provided as a string, the value of which may not be known until run-time. This string must either be compiled during program execution (using just-in-time compilation) or evaluated by interpretation, causing some added overhead at run-time, and usually generating less efficient code.

macros can also be used to achieve some of the effects of higher order functions. However, macros cannot easily avoid the problem of variable capture; they may also result in large amounts of duplicated code, which can be more difficult for a compiler to optimize. Macros are generally not strongly typed, although they may produce strongly typed code.

In object-oriented programming languages that do not support higher-order functions, objects can be an effective substitute. An object's methods act in essence like functions, and a method may accept objects as parameters and produce objects as return values. Objects often carry added run-time overhead compared to pure functions, however, and added boilerplate code for defining and instantiating an object and its method(s). Languages that permit stack-based (versus heap-based) objects or structs can provide more flexibility with this method.

An example of using a simple stack based record in Free Pascal with a function that returns a function:

program example; 

type 
  int = integer;
  Txy = record x, y: int; end;
  Tf = function (xy: Txy): int;
     
function f(xy: Txy): int; 
begin 
  Result := xy.y + xy.x; 
end;

function g(func: Tf): Tf; 
begin 
  result := func; 
end;

var 
  a: Tf;
  xy: Txy = (x: 3; y: 7);

begin  
  a := g(@f);      // return a function to "a"
  writeln(a(xy)); // prints 10
end.

The function a() takes a Txy record as input and returns the integer value of the sum of the record's x and y fields (3 + 7).

See also

External links