How should I use array of function pointers in C?

How can I initialize them?

10 Answers 10


You have a good example here (Array of Function pointers), with the syntax detailed.

int sum(int a, int b);
int subtract(int a, int b);
int mul(int a, int b);
int div(int a, int b);

int (*p[4]) (int x, int y);

int main(void)
  int result;
  int i, j, op;

  p[0] = sum; /* address of sum() */
  p[1] = subtract; /* address of subtract() */
  p[2] = mul; /* address of mul() */
  p[3] = div; /* address of div() */

To call one of those function pointers:

result = (*p[op]) (i, j); // op being the index of one of the four functions
  • 2
    Good answer - you should extend it to show how to call one of the functions, though. – Jonathan Leffler Oct 31 '08 at 19:30
  • Is it from K&R? – user Mar 30 '12 at 1:49
  • 1
    @crucifiedsoul "the C Programming Language" written by Brian Kernighan and Dennis Ritchie? It could be, but I didn't have it as a reference at the time I wrote the answer three and an half year ago. So I don't know. – VonC Mar 30 '12 at 1:51
  • 10
    I'd like to add you can initialize p with (*p[4]) (int, int) {sum,substract,mul,div} – jiggunjer Jul 7 '15 at 8:04
  • 1
    @VonC: great answer. +1 for the links. – Destructor Jul 9 '15 at 17:04

The above answers may help you but you may also want to know how to use array of function pointers.

void fun1()


void fun2()


void fun3()


void (*func_ptr[3]) = {fun1, fun2, fun3};

    int option;

    printf("\nEnter function number you want");
    printf("\nYou should not enter other than 0 , 1, 2"); /* because we have only 3 functions */


    return 0;

You can only assign the addresses of functions with the same return type and same argument types and no of arguments to a single function pointer array.

You can also pass arguments like below if all the above functions are having the same number of arguments of same type.


Note: here in the array the numbering of the function pointers will be starting from 0 same as in general arrays. So in above example fun1 can be called if option=0, fun2 can be called if option=1 and fun3 can be called if option=2.

  • Even for this little demo, you should add a check for the input value, since code targets a newbie... :-) – PhiLho Oct 31 '08 at 6:53
  • if((option<0)||(option>2)) { (*func_ptr[option])(); } Dude this means the method is called only when the user types in an invalid index! – ljs Oct 31 '08 at 7:24
  • 6
    That is a good answer, however you should add parenthesis after (*func_ptr[3]) to make it valid code. – Alex May 22 '09 at 21:56
  • This is a horribly bad answer. Due to the missing parentheses, this code does not even compile. – CL. Oct 30 '15 at 10:17
  • like @Alex said, just change it from (*func_ptr[3]) to (*func_ptr[3])() and it will compiled – dsaydon Feb 1 at 16:56

Here's how you can use it:


#ifndef NEW_FUN_H_
#define NEW_FUN_H_

#include <stdio.h>

typedef int speed;
speed fun(int x);

enum fp {
    f1, f2, f3, f4, f5

void F1();
void F2();
void F3();
void F4();
void F5();


#include "New_Fun.h"

speed fun(int x)
    int Vel;
    Vel = x;
    return Vel;

void F1()
    printf("From F1\n");

void F2()
    printf("From F2\n");

void F3()
    printf("From F3\n");

void F4()
    printf("From F4\n");

void F5()
    printf("From F5\n");


#include <stdio.h>
#include "New_Fun.h"

int main()
    int (*F_P)(int y);
    void (*F_A[5])() = { F1, F2, F3, F4, F5 };    // if it is int the pointer incompatible is bound to happen
    int xyz, i;

    printf("Hello Function Pointer!\n");
    F_P = fun;
    xyz = F_P(5);
    printf("The Value is %d\n", xyz);
    //(*F_A[5]) = { F1, F2, F3, F4, F5 };
    for (i = 0; i < 5; i++)
    return 0;

I hope this helps in understanding Function Pointer.

  • Line 15 of Main.c should be for (i = 0; i < 5; i++), right? – user3116936 Jan 14 '17 at 3:40
  • @user3116936: Yes you are right – Rasmi Ranjan Nayak Feb 15 '17 at 17:48
  • Why did you declare the fp enumerator? – Arrrow Sep 18 '17 at 12:50
  • @Arrrow: I think I saw some of the legacy code where they made it in that way... And it looks very beautiful. Just remove f1, f2 ... and in place of then enter 'writefile, readfromfile...'... it becomes more redable – Rasmi Ranjan Nayak Nov 13 '17 at 21:06

This "answer" is more of an addendum to VonC's answer; just noting that the syntax can be simplified via a typedef, and aggregate initialization can be used:

typedef int FUNC(int, int);

FUNC sum, subtract, mul, div;
FUNC *p[4] = { sum, subtract, mul, div };

int main(void)
    int result;
    int i = 2, j = 3, op = 2;  // 2: mul

    result = p[op](i, j);   // = 6

// maybe even in another file
int sum(int a, int b) { return a+b; }
int subtract(int a, int b) { return a-b; }
int mul(int a, int b) { return a*b; }
int div(int a, int b) { return a/b; }

Oh, there are tons of example. Just have a look at anything within glib or gtk. You can see the work of function pointers in work there all the way.

Here e.g the initialization of the gtk_button stuff.

static void
gtk_button_class_init (GtkButtonClass *klass)
  GObjectClass *gobject_class;
  GtkObjectClass *object_class;
  GtkWidgetClass *widget_class;
  GtkContainerClass *container_class;

  gobject_class = G_OBJECT_CLASS (klass);
  object_class = (GtkObjectClass*) klass;
  widget_class = (GtkWidgetClass*) klass;
  container_class = (GtkContainerClass*) klass;

  gobject_class->constructor = gtk_button_constructor;
  gobject_class->set_property = gtk_button_set_property;
  gobject_class->get_property = gtk_button_get_property;

And in gtkobject.h you find the following declarations:

struct _GtkObjectClass
  GInitiallyUnownedClass parent_class;

  /* Non overridable class methods to set and get per class arguments */
  void (*set_arg) (GtkObject *object,
           GtkArg    *arg,
           guint      arg_id);
  void (*get_arg) (GtkObject *object,
           GtkArg    *arg,
           guint      arg_id);

  /* Default signal handler for the ::destroy signal, which is
   *  invoked to request that references to the widget be dropped.
   *  If an object class overrides destroy() in order to perform class
   *  specific destruction then it must still invoke its superclass'
   *  implementation of the method after it is finished with its
   *  own cleanup. (See gtk_widget_real_destroy() for an example of
   *  how to do this).
  void (*destroy)  (GtkObject *object);

The (*set_arg) stuff is a pointer to function and this can e.g be assigned another implementation in some derived class.

Often you see something like this

struct function_table {
   char *name;
   void (*some_fun)(int arg1, double arg2);

void function1(int  arg1, double arg2)....

struct function_table my_table [] = {
    {"function1", function1},

So you can reach into the table by name and call the "associated" function.

Or maybe you use a hash table in which you put the function and call it "by name".


  • Would it be pssible to use such a function_table for hashing functions within the hash table implementation itself? (Read: circular dependecy involved). – Flavius Dec 1 '09 at 12:50

This should be a short & simple copy & paste piece of code example of the above responses. Hopefully this helps.

#include <iostream>
using namespace std;

#define DBG_PRINT(x) do { std::printf("Line:%-4d" "  %15s = %-10d\n", __LINE__, #x, x); } while(0);

void F0(){ printf("Print F%d\n", 0); }
void F1(){ printf("Print F%d\n", 1); }
void F2(){ printf("Print F%d\n", 2); }
void F3(){ printf("Print F%d\n", 3); }
void F4(){ printf("Print F%d\n", 4); }
void (*fArrVoid[N_FUNC])() = {F0, F1, F2, F3, F4};

int Sum(int a, int b){ return(a+b); }
int Sub(int a, int b){ return(a-b); }
int Mul(int a, int b){ return(a*b); }
int Div(int a, int b){ return(a/b); }
int (*fArrArgs[4])(int a, int b) = {Sum, Sub, Mul, Div};

int main(){
    for(int i = 0; i < 5; i++)  (*fArrVoid[i])();


  • If it is a copy&paste from other anwers, I'm not sure it adds any value... – Fabio Turati Jul 28 '16 at 15:12
  • Yes I see your point, I will add the value tonight currently at work. – nimig18 Jul 29 '16 at 18:15

Can use it in the way like this:

//! Define:
#define F_NUM 3
int (*pFunctions[F_NUM])(void * arg);

//! Initialise:
int someFunction(void * arg) {
    int a= *((int*)arg);
    return a*a;

pFunctions[0]= someFunction;

//! Use:
int someMethod(int idx, void * arg, int * result) {
    int done= 0;
    if (idx < F_NUM && pFunctions[idx] != NULL) {
        *result= pFunctions[idx](arg);
        done= 1;
    return done;

int x= 2;
int z= 0;
someMethod(0, (void*)&x, &z);
assert(z == 4);

This question has been already answered with very good examples. The only example that might be missing is one where the functions return pointers. I wrote another example with this, and added lots of comments, in case someone finds it helpful:

#include <stdio.h>

char * func1(char *a) {
    *a = 'b';
    return a;

char * func2(char *a) {
    *a = 'c';
    return a;

int main() {
    char a = 'a';
    /* declare array of function pointers
     * the function pointer types are char * name(char *)
     * A pointer to this type of function would be just
     * put * before name, and parenthesis around *name:
     *   char * (*name)(char *)
     * An array of these pointers is the same with [x]
    char * (*functions[2])(char *) = {func1, func2};
    printf("%c, ", a);
    /* the functions return a pointer, so I need to deference pointer
     * Thats why the * in front of the parenthesis (in case it confused you)
    printf("%c, ", *(*functions[0])(&a)); 
    printf("%c\n", *(*functions[1])(&a));

    a = 'a';
    /* creating 'name' for a function pointer type
     * funcp is equivalent to type char *(*funcname)(char *)
    typedef char *(*funcp)(char *);
    /* Now the declaration of the array of function pointers
     * becomes easier
    funcp functions2[2] = {func1, func2};

    printf("%c, ", a);
    printf("%c, ", *(*functions2[0])(&a));
    printf("%c\n", *(*functions2[1])(&a));

    return 0;

This simple example for multidimensional array with function pointers":

void one( int a, int b){    printf(" \n[ ONE ]  a =  %d   b = %d",a,b);}
void two( int a, int b){    printf(" \n[ TWO ]  a =  %d   b = %d",a,b);}
void three( int a, int b){    printf("\n [ THREE ]  a =  %d   b = %d",a,b);}
void four( int a, int b){    printf(" \n[ FOUR ]  a =  %d   b = %d",a,b);}
void five( int a, int b){    printf(" \n [ FIVE ]  a =  %d   b = %d",a,b);}
void(*p[2][2])(int,int)   ;
int main()
    int i,j;
    printf("multidimensional array with function pointers\n");

    p[0][0] = one;    p[0][1] = two;    p[1][0] = three;    p[1][1] = four;
    for (  i  = 1 ; i >=0; i--)
        for (  j  = 0 ; j <2; j++)
            (*p[i][j])( (i, i*j);
    return 0;

The simplest solution is to give the address of the final vector you want , and modify it inside the function.

void calculation(double result[] ){  //do the calculation on result

   result[0] = 10+5;
   result[1] = 10 +6;

int main(){

    double result[10] = {0}; //this is the vector of the results

    calculation(result);  //this will modify result

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