# 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

## C - no globals, no non-standard library

Not pretty, and not very well generalized, but...

``````typedef struct tagQuadraticFunctor QuadraticFunctor, *PQuadraticFunctor;

double a;
double b;
double c;
};

return f->a * x * x + f->b * x + f->c;
}

rtn.a = a;
rtn.b = b;
rtn.c = c;
return rtn;
}

int main(){

double ans = f.exec(&f, 42);

printf("%g\n", ans);
}
``````

and here's a version that generalizes the functor a little more, and now it's really starting to look like C wannabe C++:

``````#include <stdarg.h>

typedef struct tagFunctor Functor, *PFunctor;

typedef void (*Exec)(PFunctor f, void *rtn, int count, ...);

struct tagFunctor{
void *data;
Exec exec;
};

void ExecQuadratic(PFunctor f, void *rtn, int count, ...){
if(count != 1)
return;

va_list vl;
va_start(vl, count);
double x = va_arg(vl, double);
va_end(vl);

double *args = (double*)f->data;
*(double*)rtn = args[0] * x * x + args[1] * x + args[2];
}

Functor Quadratic(double a, double b, double c){
Functor rtn;
rtn.data = malloc(sizeof(double) * 3);
double *args = (double*)rtn.data;
args[0] = a;
args[1] = b;
args[2] = c;
return rtn;
}

int main(){
Functor f = Quadratic(1, -79, 1601);

double ans;
f.exec(&f, &ans, 1, 42.0); // note that it's very important
// to make sure the last argument
// here is of the correct type!

printf("%g\n", ans);

free(f.data);
}
``````
-
It does illustrate some of the many ways in which C is starting to really show its age. Nevertheless, that beat-up old screwdriver you keep handy on the workbench is sometimes just the right tool for the job, eh? But not THIS job, me thinks. –  P Daddy Mar 16 '09 at 23:57
blegh, this is so not the right way to use C –  Matt Joiner Nov 6 '09 at 16:09

## JavaScript

``````function quadratic(a, b, c)
{
return function(x)
{
return a*(x*x) + b*x +c;
}
}

var f = quadratic(1, -79, 1601);
``````
-
Javascript gets a bad rap sometimes, but it's shocking how straightforward this implementation is. –  Beska Mar 13 '09 at 19:41
Javascript as a language is beautiful; it's the cross-browser / speed issues that cause the suckage. –  John McCollum Mar 13 '09 at 22:31
@John - that's kind of five years ago, the speed is almost never a factor now and the cross-browser pain is very easy to abstract away. –  annakata Mar 16 '09 at 21:28

``````quadratic a b c = \x -> a*x*x + b*x + c
``````

or, I think more neatly:

``````quadratic a b c x = a*x*x + b*x + c
``````

(if you call it with only three parameters, you get back a function ready for the fourth)

To use:

``````let f = quadratic 1 -79 1601 in f 42
``````

### Edit

Generalizing it to arbitrary-order polynomials (as the OCaml answer does) is even nicer in Haskell:

``````polynomial coeff = sum . zipWith (*) coeff . flip iterate 1 . (*)
f = polynomial [1601, -79, 1]
main = print \$ f 42
``````

### Perverse

Treating functions as if they were numbers:

``````{-# LANGUAGE FlexibleInstances #-}
instance Eq (a -> a) where (==) = const . const False
instance Show (a -> a) where show = const "->"
instance (Num a) => Num (a -> a) where
(f + g) x = f x + g x; (f * g) x = f x * g x
negate f = negate . f; abs f = abs . f; signum f = signum . f
fromInteger = const . fromInteger
instance (Fractional a) => Fractional (a -> a) where
(f / g) x = f x / g x
fromRational = const . fromRational

quadratic a b c = a*x^2 + b*x + c
where x = id :: (Fractional t) => t -> t
f = quadratic 1 (-79) 1601
main = print \$ f 42
``````

...although if `1 (-79) 1601` weren't numeric literals, this would require some additional application of `const`.

-
This makes me want to learn Haskell... –  Chris Lutz Mar 13 '09 at 19:49

## Python

``````def quadratic(a, b, c):
return lambda x: a*x**2 + b*x + c

# Outputs 47
``````

Without using lambda (functions can be passed around in Python like any variable, class etc):

``````def quadratic(a, b, c):
def returned_function(x):
return a*x**2 + b*x + c
return returned_function
# Outputs 47
``````

Equivalent using a class rather than returning a function:

``````class quadratic:
def __init__(self, a, b, c):
self.a, self.b, self.c = a, b, c
def __call__(self, x):
return self.a*x**2 + self.b*x + self.c

# Outputs 47
``````
-
I would say that returning a function here is more Pythonic, since the object returned from quadratic() (in either version) is only meant to be called. The class version is like creating an iterable class when all you need is a generator function—overkill, without any real benefit. –  Miles Mar 16 '09 at 23:28

## C# using only Lambdas

``````Func<double, double, double, Func<double, double>> curry =
(a, b, c) => (x) => (a * (x * x) + b * x + c);
Func<double, double> quad = curry(1, -79, 1601);
``````
-

## PHP 5.3

``````function quadratic(\$a, \$b, \$c)
{
return function(\$x) use(\$a, \$b, \$c)
{
return \$a*(\$x*\$x) + \$b*\$x + \$c;
};
}

echo \$f(42);
``````
-

## C++

I don't see one using boost::lambda yet...

``````#include <boost/function.hpp>
#include <boost/lambda/lambda.hpp>
#include <iostream>

using namespace std;
using namespace boost;
using namespace boost::lambda;

function<float(float)> g(float a,float b,float c)
{
return a*_1*_1 + b*_1 + c;
}

int main(int,char**)
{
const function<float(float)> f=g(1.0,-79.0,1601.0);

cout << f(42.0) << endl;

return 0;
}
``````

(works with whichever gcc and boost are current on Debian/Lenny).

-
boost::lambda challenges me and fills me with a pleasant kind of fear. –  IfLoop Mar 14 '09 at 4:10

## Clojure

```(defn quadratic [a b c]
#(+ (* a % %) (* b %) c))

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

### Edit

Arbitrary-order polynomials:

```(use 'clojure.contrib.seq-utils 'clojure.contrib.math)
(defn polynomial [& cs]
#(apply +
(map (fn [[pow c]] (* c (expt % pow)))
(indexed cs))))

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

Featuring parameter list destructuring goodness and some handy libs from clojure.contrib.

-

## Scheme

``````(define (quadratic a b c)
(lambda (x)
(+ (* a x x) (* b x) c)) )

(display ((quadratic 1 -79 1601) 42))
``````
-

# Java

(untested)

First, we need a Function interface:

``````public interface Function {
public double f(double x);
}
``````

And a method somewhere to create our quadratic function. Here we're returning an anonymous implementation of our Function interface. This is how Java does "closures". Yeah, it's ugly. Our parameters need to be final for this to compile (which is good).

``````public Function quadratic(final double a, final double b, final double c) {
return new Function() {
public double f(double x) {
return a*x*x + b*x + c;
}
};
}
``````

From here on out, it's reasonably clean. We get our quadratic function:

``````Function ourQuadratic = quadratic(1, -79, 1601);
``````

and use it to get our answer:

``````double answer = ourQuadratic.f(42);
``````
-

## Java

You don't.

And here's why:

``````// OneArgFunction.java
// Generic interface for reusability!
public interface OneArgFunction<P,R> {
public R evaluate(P param);
}
public OneArgFunction<Double, Double> quadratic(final double a, final double b, final double c) {
return new OneArgFunction<Double, Double>() {
public Double evaluate(Double param) {
return param*param*a + param*b + c;
}
};
}
// And...
``````
-
For all the griping about this, it does show the way to something better. Just a little syntactic sugar would allow a lambda-like expression to implement a one-method interface. A bit of type inference and it would be fine. Okay, the names closed over must be `final`, but Haskell wears that same limitation with pride! –  Daniel Earwicker Jan 29 '10 at 12:32

## Ruby

``````def foo (a,b,c)
lambda {|x| a*x**2 + b*x + c}
end

bar = foo(1, -79, 1601)

puts bar[42]
``````

gives

``````47
``````
-
I kind of like bar.call(), actually. It's nice and explicit, and it clearly says "Hey, this isn't a function but we're calling it as one!" At least, as far as I can tell. –  Chris Lutz Mar 13 '09 at 20:18
Methods and variables are in different namespaces. It would be ambiguous whether you wanted to call the method bar or the lambda that's the value of the variable bar. Proc#call is the "real" method for calling a lambda, but since lambdas are objects and Ruby is TIMTOWTDI, the [] method is an alias. –  Chuck Mar 15 '09 at 1:49

# F#

Here's a nice one line example in F#:

``````let quadratic a b c x = a*x*x + b*x + c
let f = quadratic 1 -79 1601 // Use function currying.

printfn "%i" (f 42)
``````

And for arbitrary-order:

``````let polynomial coeffs x =
coeffs |> List.mapi (fun i c -> c * (pown x i)) |> List.sum
let f = polynomial [1601; -79; 1]
f 42
``````

And to generalize over numerics:

``````let inline polynomial coeffs x =
coeffs |> List.rev |> List.mapi (fun i c -> c * (pown x i)) |> List.sum

> let f = polynomial [1601.; -79.; 1.];;
val f : (float -> float)

> let g = polynomial [1601m; -79m; 1m];;
val g : (decimal -> decimal)
``````
-

x86_32 Assembly (I am very new to it, it may not be the best way to do it, comments welcome):

``````#define ENTER_FN \
pushl %ebp; \
movl %esp, %ebp
#define EXIT_FN \
movl %ebp, %esp; \
popl %ebp; \
ret
.global main

calculate_fabcx: #c b a x
ENTER_FN

# %eax= a*x*x
movl 20(%ebp), %eax
imull %eax, %eax
imull 16(%ebp), %eax

# %ebx=b*x
movl 12(%ebp), %ebx
imull 20(%ebp), %ebx

# %eax = f(x)

EXIT_FN

calculate_f: #x
ENTER_FN

pushl 8(%ebp) # push x
movl \$0xFFFFFFFF, %eax # replace by a
pushl %eax
movl \$0xEEEEEEEE, %eax # replace by b
pushl %eax
movl \$0xDDDDDDDD, %eax # replace by c
pushl %eax

movl \$calculate_fabcx, %eax
call *%eax
popl %ecx
popl %ecx
popl %ecx
popl %ecx

EXIT_FN
.set calculate_f_len, . - calculate_f

generate_f: #a b c
ENTER_FN

#allocate memory
pushl \$calculate_f_len
call malloc
popl %ecx

pushl \$calculate_f_len
pushl \$calculate_f
pushl %eax
call copy_bytes
popl %eax
popl %ecx
popl %ecx

movl %eax, %ecx

movl 8(%ebp), %edx
movl %edx, (%ecx)

movl 12(%ebp), %edx
movl %edx, (%ecx)

movl 16(%ebp), %edx
movl %edx, (%ecx)

EXIT_FN

format:
.ascii "%d\n\0"

main:
ENTER_FN

pushl \$1601
pushl \$-79
pushl \$1
call generate_f
popl %ecx
popl %ecx
popl %ecx

pushl \$42
call *%eax
popl %ecx

pushl %eax
pushl \$format
call printf
popl %ecx
popl %ecx

movl \$0, %eax
EXIT_FN

copy_bytes: #dest source length
ENTER_FN

subl \$24, %esp

movl 8(%ebp), %ecx # dest
movl %ecx, -4(%ebp)

movl 12(%ebp), %ebx # source
movl %ebx, -8(%ebp)

movl 16(%ebp), %eax # length
movl %eax, -12(%ebp)

addl %eax, %ecx # last dest-byte
movl %ecx, -16(%ebp)

addl %eax, %edx # last source-byte
movl %ecx, -20(%ebp)

movl -4(%ebp), %eax
movl -8(%ebp), %ebx
movl -16(%ebp), %ecx

copy_bytes_2:
movb (%ebx), %dl
movb %dl, (%eax)
incl %eax
incl %ebx
cmp %eax, %ecx
jne copy_bytes_2

EXIT_FN
``````

By coincidence, this thread fits perfectly to whan I am doing at the moment, namely, collecting implementations of Church Numerals in several languages (which is a similar problem, but slightly more complicated). I have already posted some (javascript, java, c++, haskell, etc.) on my Blog, for example here and in older posts, just if somebody is interested in this (or has an additional implementation for me ^^).

-
Trouble if the heap is execute-protected (i.e. W^X or similar technologies) -- you really should mmap a new page and mprotect to make it executable. Otherwise, it's written just fine -- clear and easy to read. –  ephemient Mar 16 '09 at 15:37
Currying in assembly? Sweet. –  ojrac Mar 17 '09 at 21:24

## Common Lisp

```(defun make-quad (a b c)
#'(lambda (x) (+ (* a x x) (* b x) c)))

(funcall (make-quad 1 -78 1601) 42)
```
-

## Lua

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

local f = quadratic (1, -79, 1601)

print (f(42))
``````

The result:

47

Several other answers have further generalized the problem to cover all polynomials. Lua handles this case as well:

``````function polynomial (...)
local constants = {...}

return function (x)
local result = 0
for i,v in ipairs(constants) do
result = result + v*math.pow(x, #constants-i)
end
return result
end
end
``````
-

## C++

``````#include <iostream>

{
int a_,b_,c_;
public:
Quadratic(int a, int b, int c)
{
a_ = a;
b_ = b;
c_ = c;
}
int operator()(int x)
{
return a_*x*x + b_*x + c_;
}
}

int main()
{
std::cout << f(42);
return 0;
}
``````
-
Isn't this passing around an object, rather than a function? If that's all that is required, the implementation in most any OO language is trivial. –  T.E.D. Mar 13 '09 at 20:07
@Jon: It's a very common technique, and used a lot in the standard library. An object that overloads operator() is called a functor. Very useful if you want to use some custom comparer while sorting with std::sort, for example –  jalf Mar 13 '09 at 20:43

## C++0x

I don't actually have a compiler that supports this, so it could be (probably is) wrong.

``````auto quadratic = [](double a, double b, double c) {
return [=] (double x) { return a*x*x + b*x + c; };
};

auto f = quadratic(1, -79, 1601);
std::cout << f(42) << std::endl;
``````
-

## perl

``````sub quadratic {
my (\$a, \$b, \$c) = @_;
return sub {
my (\$x) = @_;
return \$a*(\$x*\$x) + \$b*\$x + \$c;
}
}

my \$f = quadratic (1, -79, 1601);

print \$f->(42);
``````
-

## PHP

``````function quadratic(\$a, \$b, \$c) {
return create_function('\$x',
'return ' . \$a . ' * (\$x * \$x) + ' . \$b . ' * \$x + ' . \$c . ';'
);
}

echo \$f(42) . "\n";
``````

The result:

47

-
I interpreted your answer to mean that you chose to answer the question in PHP. ;-) But I do see your top tag is: "php ×37". Must mean you like helping the lost and suffering! –  Jon Ericson Mar 13 '09 at 21:40
Lost and suffering? There is a subset of PHP 5.2+ that is a fantastic language. –  postfuturist Mar 13 '09 at 21:46
The PHP 5.3 answer looked pretty good! I'll try to keep my PHP bashing to a minimum from now on. ;-) –  Jon Ericson Mar 13 '09 at 23:07

## Prolog

``````test :-
writeln(Result).

create_quadratic([A, B, C], f(X, A * X**2 + B * X + C)).

evaluate(f(X, Expression), X, Result) :-
Result is Expression.
``````

Testing:

``````?- test.
47
true.
``````
-

## Python

In Python using only lambdas:

``````curry = lambda a, b, c: lambda x: a*x**2 + b*x + c
``````
-

## Ocaml

``````let quadratic a b c = fun x -> a*x*x + b*x + c
``````

but really, thanks to currying, the following is equivalent:

``````let quadratic a b c x = a*x*x + b*x + c
``````

For compilation reasons, the first is actually better because the compiler wont need to call caml_applyX and caml_curryX. Read more here

How about general polynomials (with floats)?

``````let polynomial coeff =
(fun x ->
snd (List.fold_right
(fun co (i,sum) ->
((i+.1.0), sum +. co *. (x ** i))) coeff (0.0,0.0))
)
``````
-

## C#

``````public Func<double, double> F(double a, double b, double c){
Func<double, double> ret = x => a * x * x + b * x + c;

return ret;
}

public void F2(){
var f1 = F(1, -79, 1601);

Console.WriteLine(f1(42));
}
``````
-
F could just return the lambda directly, instead of using that intermediate ret variable. –  Daniel Earwicker Mar 13 '09 at 21:57
yeah you right, just accostumed to do this for debugging purposes –  Jhonny D. Cano -Leftware- Mar 13 '09 at 22:05

## Scala

``````def makeQuadratic(a: Int, b: Int, c: Int) = (x: Int) => a * x * x + b * x + c
val f = makeQuadratic(1, -79, 1601)
println(f(42))
``````

Edit: Apparently, the above solution uses integer values instead of floating point values. To comply with the new requirements, makeQuadratic must be changed to:

``````def makeQuadratic(a: Float, b: Float, c: Float) =
(x: Float) => a * x * x + b * x + c
``````
-

# C

With the FFCALL library installed,

``````#include <trampoline.h>

double a;
double b;
double c;

double a, b, c;
return a*x*x + b*x + c;
}

double (*quadratic(double a, double b, double c))(double) {
args = malloc(sizeof(*args));
args->a = a;
args->b = b;
args->c = c;
}

int main() {
double (*f)(double);
printf("%g\n", f(42));
free(trampoline_data(f));
free_trampoline(f);
return 0;
}
``````
-

Smalltalk

A simple solution using a code block:

```| quadratic f |
quadratic := [:a :b :c | [:x | (a * x squared) + (b * x) + c]].
```

And to generate the function and call it:

```f := quadratic value: 1 value: -79 value: 1601.
f value: 42.
```
-

# Perl 6

``````sub quadratic(\$a, \$b, \$c) { -> \$x { \$a*\$x*\$x + \$b*\$x + \$c } }
my &f := quadratic(1, -79, 1601);
say f(42);
``````
-

## C (sorta)

clang (LLVM's C compiler) has support for what they call blocks (closures in C):

``````double (^quadratic(double a, double b, double c))(double) {
return _Block_copy(^double(double x) {return a*x*x + b*x + c;});
}

int main() {
double (^f)(double);
printf("%g\n", (^f)(42));
_Block_release(f);
return 0;
}
``````

At least, that's how it should work. I haven't tried it out myself.

-

## JavaScript

``````function quadratic(a,b,c) {
return function(x) {
return a*(x*x) + b*x + c;
}
}

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

f(42);
``````
-