# How do you create a function that returns a function in your language of choice? [closed]

Recently I've been learning Lua and I love how easy it is to write a function that returns a function. I know it's fairly easy in Perl as well, but I don't think I can do it in C without some heartache. How do you write a function generator in your favorite language?

So that it's easier to compare one language to another, please write a function that generates a quadratic formula:

``````f(x) = ax^2 + bx + c
``````

Your function should take three values (`a`, `b`, and `c`) and returns `f`. To test the function, show how to generate the quadratic formula:

``````f(x) = x^2 - 79x + 1601
``````

Then show how to calculate `f(42)`. I'll post my Lua result as an answer for an example.

Some additional requirements that came up:

1. All of `a`, `b`, `c`, `x`, and `f(x)` should be floating point numbers.

2. The function generator should be reentrant. That means it should be possible to generate:

``````g(x) = x^2 + x + 41
``````

And then use both `f(x)` and `g(x)` in the same scope.

Most of the answers already meet those requirements. If you see an answer that doesn't, feel free to either fix it or note the problem in a comment.

-

## closed as not constructive by WillJun 17 '13 at 14:12

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+1 just because :) –  leppie Mar 13 '09 at 22:27

# Standard ML

Using functional languages is just way too easy.

``````fun quadratic (a, b, c) = fn x => a*x*x + b*x + c : real;
val f = quadratic (1.0, ~79.0, 1601.0);
f 42.0;
``````
-
It can be done simpler though. fun quadratic (a, b, c) x = a*x*x + b*x + c; :) –  jalf Mar 13 '09 at 20:23

## C++ metaprogramming

For sheer perversity, using boost::mpl to do it all at compile time...

(Floats aren't allowed as template arguments, so this is integers only.)

``````#include <boost/mpl/arithmetic.hpp>
#include <boost/mpl/assert.hpp>
#include <boost/mpl/comparison.hpp>
#include <boost/mpl/equal_to.hpp>
#include <boost/mpl/lambda.hpp>
#include <iostream>
using namespace boost::mpl;

// g returns a quadratic function f(x)=a*x^2+b*x+c
template <typename a,typename b,typename c> struct g
:lambda<
plus<
multiplies<a,multiplies<_1,_1> >,
plus<multiplies<b,_1>,c>
>
>{};

// f is the quadratic function with the coefficients specified
typedef g<int_<1>,int_<-79>,int_<1601> >::type f;

// Compute the required result
typedef f::apply<int_<42> >::type result;

// Check the result is as expected
// Change the int_<47> here and you'll get a compiler (not runtime!) error
struct check47 {
BOOST_MPL_ASSERT((equal_to<result,int_<47> >));
};

// Well if you really must see the result...
int main(int,char**) {
std::cout << result::value << std::endl;
}
``````

(Works on Debian/Lenny's gcc+boost)

I'm not sure whether there's some way of getting the compiler to log out that the result is `int_<47>` without triggering a compiler error message.

Just to emphasise the compile-time aspect: if you inspect the assembler you'll see

`````` movl    \$47, 4(%esp)
movl    std::cout, (%esp)
call    std::basic_ostream<char, std::char_traits<char> >::operator<<(int)
``````

and you can plug `result::value` into anywhere that needs a compile-time constant e.g 'C'-array dimensions, integer template arguments, explicit enum values...

Practical applications ? Hmmm...

-

## PowerShell

PowerShell has a notion of ScriptBlock, which is like an anonymous method;

``````\$quadratic = { process { \$args[0]*(\$_*\$_) + \$args[1]*\$_ + \$args[2]; } }
42 | &\$quadratic 1 (-79) 1601
47
``````
-

## D 2.0

``````auto quadratic(float a, float b, float c) {
return delegate(float x) { return a * x * x + b * x + c; };
}       //     ^ optional

auto f = quadratic(1, -79, 1601);
writeln( f(42) );
``````
-

## Standard ML

``````fun quadratic (a, b, c) x = a*x*x + b*x + c : real;
val f = quadratic (1.0, ~79.0, 1601.0);
f 42.0;
``````

or

``````fun quadratic a b c x = a*x*x + b*x + c : real;
val f = quadratic 1.0 ~79.0 1601.0;
f 42.0;
``````

(but I think the first version more closely matches what was requested)

-

## MATLAB (part deux)

This is a variant of what Azim posted, which will allow you to create functions that do computations which are too complex to encompass in an anonymous function:

``````function f = quadratic(a,b,c)
f = @nested_fcn;
function value = nested_fcn(x)
value = a*x^2+b*x+c;
end
end
``````

Usage:

``````fcn = quadratic(1,-79,1601);
fcn(42)
``````
-
nice. I never realized you could nest functions like that. When you do nest functions in this way, do variables such as (a,b,c) have "global" scope within the function? I noticed you didn't have to pass them as arguments to nested_fcn? –  Azim Mar 14 '09 at 16:29

## MATLAB

Using an anonymous function

``````function f=quadratic(a,b,c)
% FUNCTION quadratic. returns an inline polynomial with coefficients a,b,c
f = @(x)a*x^2+b*x+c;
``````

or using inline which is not as clean/concise

``````function f=quadratic2(a,b,c)
% FUNCTION quadratic. returns an inline polynomial with coefficients a,b,c
f = inline(['(',num2str(a),'*x^2)+(',num2str(b),'*x)+(',num2str(c),')'],'x');
``````

Usage

``````>> ff = quadratic(1,-79,1601);
>> ff(42)
ans =
47
``````
-

C# 2.0

Create a delegate named QuadraticFormula with the following return type and parameter

``````delegate float QuadraticFormula(float x);
``````

create static method named CreateFormula to return delegate QuadraticFormula

``````class Program
{

static void Main(string[] args)
{

QuadraticFormula formula = CreateFormula(1, 2, 1);

Console.WriteLine(formula(-1));
}

static QuadraticFormula CreateFormula(float a, float b, float c)
{
return delegate(float x)
{
return a * x * x + b * x + c;
};
}
}
``````
-

## Mathematica

``````quadratic[a_, b_, c_] := a #^2 + b # + c &
Print[f[42]];
``````

47

Using a form of currying:

``````quad[a_, b_, c_][x_] := a x^2 + b x + c

f[42]
``````

47

Using pure functions:

``````f = Function[x, # x^2 + #2 x + #3] &;

g = f[1, -79, 1601];

g[42]
``````

47

Generalization to arbitrary polynomials:

``````poly[a__]:= With[{n=Length@{a}},Evaluate[Table[#,{n}]^Reverse@Range[0,n-1].{a}]&]
poly[1,-79,1601][42]
``````

47

-

CoffeeScript

``````quadratic = (a, b, c) -> (x) -> a * x * x + b * x + c
``````
-

## Visual Basic .NET using Only Lambdas

This is possible in Visual Basic .NET too.

``````Dim quadratic = Function (a As Double,b As Double,c As Double) _
Function(x As Double) (a * x * x) + (b * x) + c

Dim f = quadratic(1.0, -79.0, 1601.0)

f(42.0)
``````
-

## Perl

Alternate version:

``````sub fn {
my ( \$aa, \$bb, \$cc ) = @_;
sub { \$x = shift; \$x = \$x ** 2 * \$aa + \$x * \$bb + \$cc }
}

print fn( 1, -79, 1601 )->( 42 );
``````

One could also actually store the generated function:

``````\$f = fn( 1, -79, 1601 );
print \$f->( 42 );
``````
-

ActionScript 2

``````function quadratic(a:Number, b:Number, c:Number):Function {

function r(x) {
var ret = a*(x*x)+b*x+c;
return ret;
}
return r;
}

var f = quadratic(1, -79, 1601);
trace(f(42));
``````
-

Actionscript 2 or 3:

``````function findQuadradic( a:Number, b:number, c:Number ):Function
{
var func:Function = function( x:Number ){
return
a * Math.pow( x, 2 ) +
b * Math.pow( x, 1 ) + // TECHNICALLY more correct than * x.
c * Math.pow( x, 0 );  // TECHNICALLY more correct than * 1.
}

``````

More interestingly, you could do it another way:

`````` function findExponential( ...a:Array ):Function{
// in AS2, replace this with findExponential():Function{
var args:Array = arguments.concat() // clone the arguments array.
var retFunc:Function = function( x:Number ):Number{
{
var retNum:Number = 0;
for( var i:Number = 0; i < args.length; i++ )
{
retNum += arg[ i ] * Math.pow( x, args.length - 1 - i );
}
return retNum
}
}
``````

Now you could do:

``````  var quad:Function = findExponential( 1, -79, 1601 );
``````

Or

``````  var line:Function = findExponential( 1, -79 );
return line( 42 );
``````
-

# Tcl

``````proc quadratic { a b c } {
proc \$name {x} "return \[expr (\$a)*(\\$x)*(\\$x)+(\$b)*(\\$x)+(\$c)\]"
return \$name
}
``````

Usage:

``````set f [quadratic 1 -79 1601]
\$f 123
``````

Notes:

• Tcl doesn't have first class functions. Commands must be named and called by name. Fortunately that name can be stored in a variable.
• the expr command chokes on spaces. No, thats not a regex, just a regular infix expression.
• proc command bodies are usually wrapped in `{}`'s, but to get variable substitution to work correctly, without going to a lot of trouble elsewhere, It's set here using `"`'s and abundant `\`'s

RHSeeger suggests a way to make the function construction a little easier, using `[string map]`:

``````proc quadratic { a b c } {
proc \$name {x} [string map [list %A \$a %B \$b %C \$c] {
return [expr {(%A * \$x * \$x) + (%B * \$x) + %C}]
}]
return \$name
}
``````

Of course this can be used in the very same way. Tcl8.5 also has a way to apply a function to arguments without creating a named proc, by using the `[apply]` command. It looks similar, again using the `[string map]` method.

``````proc quadratic_lambda { a b c } {
return [list {x} [string map [list %A \$a %B \$b %C \$c] {
return [expr {(%A * \$x * \$x) + (%B * \$x) + %C}]
}]]
}

set f [quadratic_lambda 1 -79 1601]
apply \$f 123
``````

I've given this version a different name to emphasize that it works a little differently. Notice that it returns a list that looks similar to the arguments to a proc. Using `[apply]` on this value is exactly equivalent to invoking a proc with args and body matching the first argument of the apply command with the rest of the apply command. The upside of this is that you don't polute any namespaces for one-off type procs. the downside is that it makes it just a little more tricky to use a proc that actually does exist.

-
I tend to use [string map] for cases like this. proc quadratic { a b c } { set name "quadratic_\${a}_\${b}_\${c}" proc \$name {x} [string map [list %A \$a %B \$b %C \$c] { return [expr {(%A * \$x * \$x) + (%B * \$x) + %C}] }] return \$name } –  RHSeeger Jul 29 '09 at 15:40

## Java

Here's a generalized version using Functional Java. First import these:

``````import fj.F;
import fj.pre.Monoid;
import fj.data.Stream;
import static fj.data.Stream.iterate;
import static fj.data.Stream.zipWith;
import static fj.Function.compose;
``````

And here's a generalized polynomials module:

``````public class Polynomials<A> {
private final Monoid<A> sum;
private final Monoid<A> mul;

private static <A> F<F<A, A>, Stream<A>> iterate(final A a) {
return new F<F<A, A>, Stream<A>>() {
public Stream<A> f(final F<A, A> f) {
return iterate(f, a);
}
}
}

private static <A> F<Stream<A>, A> zipWith(final F<A, F<A, A>> f,
final Stream<A> xs) {
return new F<Stream<A>, A>() {
public A f(final Stream<A> ys) {
return xs.zipWith(f, ys);
}
}
}

public Polynomials(final Monoid<A> sum, final Monoid<A> mul) {
this.sum = sum;
this.mul = mul;
}

public F<A, A> polynomial(final Stream<A> coeff) {
return new F<A, A>() {
public A f(final A x) {
return compose(sum.sumLeft(),
compose(zipWith(mul.sum(), coeff),
compose(iterate(1), mul)));
}
}
}
}
``````

Example usage with integers:

``````import static fj.pre.Monoid.intAdditionMonoid;
import static fj.pre.Monoid.intMultiplicationMonoid;
import static fj.data.List.list;
...

intMultiplicationMonoid);
F<Integer, Integer> f = p.polynomial(list(1601, -79, 1).toStream());
System.out.println(f.f(42));
``````
-
``````var quadratic = func(a,b,c) {
func(x) {a* (x*x) +b*x +c} # implicitly returned to caller
}

print(result~"\n");
``````
-

## Bourne Shell

``````quadratic(){
eval "\${quadratic:=f}(){ let r=\${a:=1}*\\$x*\\$x+\${b:=1}*\\$x+\${c:=1} ; echo \\$r ; }"
}
``````

To use it, you need to set `a`, `b`, and `c`:

``````a=1; b=-79; c=1601; quadratic=f; quadratic
``````

(The `quadratic` function defaults to setting the constants to 1, but it's best not to rely on that.) Here's how to get the results:

``````\$ x=42;f;g
47
1847
``````

Tested with `ksh` and `bash`.

Note: fails the floating-point requirement. You could use `bc` or some such in the body of the `quadratic` function to implement it, but I don't think it would be worth the effort.

-

# Oz/Mozart

``````declare

fun {\$ X}
A*X*X + B*X + C
end
end

F = {Quadratic 1.0 ~79.0 1601.0}

in

{Show {F 42.0}}
``````

I think it's interesting that Oz does not have special syntax for unnamed functions. Instead, it has a more general concept: The "nesting marker", which marks the return value of an expression by its position.

-

Clojure

The first call creates a polynomial function by grouping multiplications, in the example (a x^2 + b x + c) => (((a) x + b) x + c) The second created the poly and evaluates it.

``````(defn polynomial [& a] #(reduce (fn[r ai] (+ (* r %) ai)) a))

((polynomial 1, -79, 1601 ) 42)   ; => 47
``````
-

# JavaScript 1.8

``````function quadratic(a, b, c)
function(x)
a*(x*x) + b*x +c
``````
-

## R

``````quadratic <- function(a, b, c) {
function(x) a*x*x + b*x + c
}

f(42)
g(42)
``````
-

# PostScript

With no named local variables (though you could use them if you want... :p).

``````/quadratic {[4 1 roll {3 index dup mul 4 3 roll mul add 3 1 roll mul add}

/f 1 -79 1601 quadratic def
/g 1 1 41 quadratic def

42 f =
42 g =
``````

Returns

``````47
1847
``````

Of course, you don't need to name these functions either. Here's a completely anonymous version:

``````42 dup {[4 1 roll {3 index dup mul 4 3 roll mul add 3 1 roll mul add}
aload pop] cvx} exch 1 -79 1601 4 index exec exec = 1 1 41 4 3 roll exec exec =
``````
-

## C (take four, pure ANSI C)

### warning, this fails the new "re-entrant" criterion

Not perfect, but...

``````/* file "quad.c" */

static double _a, _b, _c;

typedef double(*fnptr)(double);

{
return _a * x * x + _b * x + _c;
}

fnptr quadratic(double a, double b, double c)
{
_a = a;
_b = b;
_c = c;
}

typedef double(*fnptr)(double);
extern fnptr quadratic(double a, double b, double c);

/* file "main.c" */

#include <stdio.h>