234

Is there any way to achieve function overloading in C? I am looking at simple functions to be overloaded like

foo (int a)  
foo (char b)  
foo (float c , int d)

I think there is no straight forward way; I'm looking for workarounds if any exist.

  • 5
    Why would you want to do this? C has no polymorphic abilities. So foo(random type) is impossible. Just make real funcs foo_i, foo_ch, foo_d, etc. – jmucchiello Jan 26 '09 at 13:10
  • 3
    You can go the evil way using void pointers and type ids. – alk Oct 20 '11 at 9:28
  • 10
    I feel I should draw attention to the fact that the answer to this question has changed since it was originally asked, with the new C standard. – Leushenko Sep 7 '14 at 0:05

14 Answers 14

125

There are few possibilities:

  1. printf style functions (type as an argument)
  2. opengl style functions (type in function name)
  3. c subset of c++ (if You can use a c++ compiler)
  • 1
    can you explain or provide links for opengl style functions ? – FL4SOF Jan 26 '09 at 12:00
  • 2
    take a look at glprogramming.com/red/chapter01.html#name3 – Jacek Ławrynowicz Jan 26 '09 at 12:41
  • 2
    Any good links for "printf style functions"? – Lazer Mar 20 '10 at 10:07
  • 11
    No. printf is not function overloading. it uses vararg !!! And C doesn't support Function Overloading. – hqt Jul 29 '12 at 9:49
  • 50
    @hqt The answer doesn't ever mention the word overloading. – kyrias Jun 20 '13 at 16:12
217

Yes!

In the time since this question was asked, standard C (no extensions) has effectively gained support for function overloading (not operators), thanks to the addition of the _Generic keyword in C11. (supported in GCC since version 4.9)

(Overloading isn't truly "built-in" in the fashion shown in the question, but it's dead easy to implement something that works like that.)

_Generic is a compile-time operator in the same family as sizeof and _Alignof. It is described in standard section 6.5.1.1. It accepts two main parameters: an expression (which will not be evaluated at runtime), and a type/expression association list that looks a bit like a switch block. _Generic gets the overall type of the expression and then "switches" on it to select the end result expression in the list for its type:

_Generic(1, float: 2.0,
            char *: "2",
            int: 2,
            default: get_two_object());

The above expression evaluates to 2 - the type of the controlling expression is int, so it chooses the expression associated with int as the value. Nothing of this remains at runtime. (The default clause is optional: if you leave it off and the type doesn't match, it will cause a compilation error.)

The way this is useful for function overloading is that it can be inserted by the C preprocessor and choose a result expression based on the type of the arguments passed to the controlling macro. So (example from the C standard):

#define cbrt(X) _Generic((X),                \
                         long double: cbrtl, \
                         default: cbrt,      \
                         float: cbrtf        \
                         )(X)

This macro implements an overloaded cbrt operation, by dispatching on the type of the argument to the macro, choosing an appropriate implementation function, and then passing the original macro argument to that function.

So to implement your original example, we could do this:

foo_int (int a)  
foo_char (char b)  
foo_float_int (float c , int d)

#define foo(_1, ...) _Generic((_1),                                  \
                              int: foo_int,                          \
                              char: foo_char,                        \
                              float: _Generic((FIRST(__VA_ARGS__,)), \
                                     int: foo_float_int))(_1, __VA_ARGS__)
#define FIRST(A, ...) A

In this case we could have used a default: association for the third case, but that doesn't demonstrate how to extend the principle to multiple arguments. The end result is that you can use foo(...) in your code without worrying (much[1]) about the type of its arguments.


For more complicated situations, e.g. functions overloading larger numbers of arguments, or varying numbers, you can use utility macros to automatically generate static dispatch structures:

void print_ii(int a, int b) { printf("int, int\n"); }
void print_di(double a, int b) { printf("double, int\n"); }
void print_iii(int a, int b, int c) { printf("int, int, int\n"); }
void print_default(void) { printf("unknown arguments\n"); }

#define print(...) OVERLOAD(print, (__VA_ARGS__), \
    (print_ii, (int, int)), \
    (print_di, (double, int)), \
    (print_iii, (int, int, int)) \
)

#define OVERLOAD_ARG_TYPES (int, double)
#define OVERLOAD_FUNCTIONS (print)
#include "activate-overloads.h"

int main(void) {
    print(44, 47);   // prints "int, int"
    print(4.4, 47);  // prints "double, int"
    print(1, 2, 3);  // prints "int, int, int"
    print("");       // prints "unknown arguments"
}

(implementation here) So with some effort, you can reduce the amount of boilerplate to looking pretty much like a language with native support for overloading.

As an aside, it was already possible to overload on the number of arguments (not the type) in C99.


[1] note that the way C evaluates types might trip you up though. This will choose foo_int if you try to pass it a character literal, for instance, and you need to mess about a bit if you want your overloads to support string literals. Still overall pretty cool though.

  • Based on your example it looks like the only thing being overloaded is function like macros. Let me see if I understand correctly: If you want to overload functions you'd just be using the preprocessor to divert the function call based on the data types passed in, right? – Nick Feb 5 '15 at 17:47
  • Alas, whenever C11 begins to catch on I assume MISRA will not embrace this feature for the same reasons they forbid variable arguments lists. I try to stick by MISRA pretty close in my world. – Nick Feb 5 '15 at 17:50
  • 9
    @Nick that's all overloading is. It's just handled implicitly in other languages (e.g. you can't really get "a pointer to an overloaded function" in any language, because overloading implies multiple bodies). Note that this can't be done by the preprocessor alone, it requires type dispatch of some kind; the preprocessor just changes how it looks. – Leushenko Feb 5 '15 at 20:16
  • 1
    As somebody who is fairly familiar with C99 and wants to learn how to do this, this seems overly complicated, even for C. – Tyler Crompton May 3 '16 at 20:06
  • 5
    @TylerCrompton It's evaluated at compile time. – JAB Apr 21 '17 at 14:45
75

As already stated, overloading in the sense that you mean isn't supported by C. A common idiom to solve the problem is making the function accept a tagged union. This is implemented by a struct parameter, where the struct itself consists of some sort of type indicator, such as an enum, and a union of the different types of values. Example:

#include <stdio.h>

typedef enum {
    T_INT,
    T_FLOAT,
    T_CHAR,
} my_type;

typedef struct {
    my_type type;
    union {
        int a; 
        float b; 
        char c;
    } my_union;
} my_struct;

void set_overload (my_struct *whatever) 
{
    switch (whatever->type) 
    {
        case T_INT:
            whatever->my_union.a = 1;
            break;
        case T_FLOAT:
            whatever->my_union.b = 2.0;
            break;
        case T_CHAR:
            whatever->my_union.c = '3';
    }
}

void printf_overload (my_struct *whatever) {
    switch (whatever->type) 
    {
        case T_INT:
            printf("%d\n", whatever->my_union.a);
            break;
        case T_FLOAT:
            printf("%f\n", whatever->my_union.b);
            break;
        case T_CHAR:
            printf("%c\n", whatever->my_union.c);
            break;
    }

}

int main (int argc, char* argv[])
{
    my_struct s;

    s.type=T_INT;
    set_overload(&s);
    printf_overload(&s);

    s.type=T_FLOAT;
    set_overload(&s);
    printf_overload(&s);

    s.type=T_CHAR;
    set_overload(&s);
    printf_overload(&s); 
}
  • 21
    Why wouldn't you just make all the whatevers into separate functions (set_int, set_float, etc). Then "tagging with the type" becomes "add the type name to the function name". The version in this answer involves more typing, more runtime cost, more chance of errors that won't be caught at compile time... I fail to see any advantage at all to doing things this way! 16 upvotes?! – Ben Jan 29 '13 at 21:24
  • 19
    Ben, this answer is upvoted because it answers the question, instead of just saying “don’t do that”. You are correct that it is more idiomatic in C to use separate functions, but if one wants polymorphism in C, this is a good way to do it. Further, this answer shows how you would implement run-time polymorphism in a compiler or VM: tag the value with a type, and then dispatch based on that. It is thus an excellent answer to the original question. – Nils von Barth Nov 8 '14 at 23:12
  • 1
    @Ben If there are some common code structure in set_int, set_float, etc ... – weakish Apr 11 '15 at 8:51
19

If your compiler is gcc and you don't mind doing hand updates every time you add a new overload you can do some macro magic and get the result you want in terms of callers, it's not as nice to write... but it's possible

look at __builtin_types_compatible_p, then use it to define a macro that does something like

#define foo(a) \
((__builtin_types_compatible_p(int, a)?foo(a):(__builtin_types_compatible_p(float, a)?foo(a):)

but yea nasty, just don't

EDIT: C1X will be getting support for type generic expressions they look like this:

#define cbrt(X) _Generic((X), long double: cbrtl, \
                              default: cbrt, \
                              float: cbrtf)(X)
18

Here is the clearest and most concise example I've found demonstrating function overloading in C:

#include <stdio.h>
#include <stdlib.h>
#include <string.h>

int addi(int a, int b) {
    return a + b;
}

char *adds(char *a, char *b) {
    char *res = malloc(strlen(a) + strlen(b) + 1);
    strcpy(res, a);
    strcat(res, b);
    return res;
}

#define add(a, b) _Generic(a, int: addi, char*: adds)(a, b)

int main(void) {
    int a = 1, b = 2;
    printf("%d\n", add(a, b)); // 3

    char *c = "hello ", *d = "world";
    printf("%s\n", add(c, d)); // hello world

    return 0;
}

https://gist.github.com/barosl/e0af4a92b2b8cabd05a7

  • 1
    I think this is a dupe of stackoverflow.com/a/25026358/1240268 in spirit (but with less explanation). – Andy Hayden Jul 27 '15 at 5:29
  • 1
    I definitely prefer 1 single continuous block of complete and runnable code to the slicing and dicing chop that is #1240268. To each their own. – Jay Taylor Jul 27 '15 at 17:02
  • 1
    I prefer answers that explain what they're doing and why they work. This does neither. "Best I've seen yet:" is not exposition. – underscore_d Aug 20 '17 at 10:26
13

Yes, sort of.

Here you go by example :

void printA(int a){
printf("Hello world from printA : %d\n",a);
}

void printB(const char *buff){
printf("Hello world from printB : %s\n",buff);
}

#define Max_ITEMS() 6, 5, 4, 3, 2, 1, 0 
#define __VA_ARG_N(_1, _2, _3, _4, _5, _6, N, ...) N
#define _Num_ARGS_(...) __VA_ARG_N(__VA_ARGS__) 
#define NUM_ARGS(...) (_Num_ARGS_(_0, ## __VA_ARGS__, Max_ITEMS()) - 1) 
#define CHECK_ARGS_MAX_LIMIT(t) if(NUM_ARGS(args)>t)
#define CHECK_ARGS_MIN_LIMIT(t) if(NUM_ARGS(args) 
#define print(x , args ...) \
CHECK_ARGS_MIN_LIMIT(1) printf("error");fflush(stdout); \
CHECK_ARGS_MAX_LIMIT(4) printf("error");fflush(stdout); \
({ \
if (__builtin_types_compatible_p (typeof (x), int)) \
printA(x, ##args); \
else \
printB (x,##args); \
})

int main(int argc, char** argv) {
    int a=0;
    print(a);
    print("hello");
    return (EXIT_SUCCESS);
}

It will output 0 and hello .. from printA and printB.

  • 2
    int main(int argc, char** argv) { int a=0; print(a); print("hello"); return (EXIT_SUCCESS); } will output 0 and hello .. from printA and printB ... – Nautical Oct 22 '12 at 11:24
  • 1
    __builtin_types_compatible_p, isn't that GCC compiler specific? – Sogartar Mar 22 '13 at 12:35
11

The following approach is similar to a2800276's, but with some C99 macro magic added:

// we need `size_t`
#include <stddef.h>

// argument types to accept
enum sum_arg_types { SUM_LONG, SUM_ULONG, SUM_DOUBLE };

// a structure to hold an argument
struct sum_arg
{
    enum sum_arg_types type;
    union
    {
        long as_long;
        unsigned long as_ulong;
        double as_double;
    } value;
};

// determine an array's size
#define count(ARRAY) ((sizeof (ARRAY))/(sizeof *(ARRAY)))

// this is how our function will be called
#define sum(...) _sum(count(sum_args(__VA_ARGS__)), sum_args(__VA_ARGS__))

// create an array of `struct sum_arg`
#define sum_args(...) ((struct sum_arg []){ __VA_ARGS__ })

// create initializers for the arguments
#define sum_long(VALUE) { SUM_LONG, { .as_long = (VALUE) } }
#define sum_ulong(VALUE) { SUM_ULONG, { .as_ulong = (VALUE) } }
#define sum_double(VALUE) { SUM_DOUBLE, { .as_double = (VALUE) } }

// our polymorphic function
long double _sum(size_t count, struct sum_arg * args)
{
    long double value = 0;

    for(size_t i = 0; i < count; ++i)
    {
        switch(args[i].type)
        {
            case SUM_LONG:
            value += args[i].value.as_long;
            break;

            case SUM_ULONG:
            value += args[i].value.as_ulong;
            break;

            case SUM_DOUBLE:
            value += args[i].value.as_double;
            break;
        }
    }

    return value;
}

// let's see if it works

#include <stdio.h>

int main()
{
    unsigned long foo = -1;
    long double value = sum(sum_long(42), sum_ulong(foo), sum_double(1e10));
    printf("%Le\n", value);
    return 0;
}
11

This may not help at all, but if you're using clang you can use the overloadable attribute - This works even when compiling as C

http://clang.llvm.org/docs/AttributeReference.html#overloadable

Header

extern void DecodeImageNow(CGImageRef image, CGContextRef usingContext) __attribute__((overloadable));
extern void DecodeImageNow(CGImageRef image) __attribute__((overloadable));

Implementation

void __attribute__((overloadable)) DecodeImageNow(CGImageRef image, CGContextRef usingContext { ... }
void __attribute__((overloadable)) DecodeImageNow(CGImageRef image) { ... }
10

In the sense you mean — no, you cannot.

You can declare a va_arg function like

void my_func(char* format, ...);

, but you'll need to pass some kind of information about number of variables and their types in the first argument — like printf() does.

6

Normally a wart to indicate the type is appended or prepended to the name. You can get away with macros is some instances, but it rather depends what you're trying to do. There's no polymorphism in C, only coercion.

Simple generic operations can be done with macros:

#define max(x,y) ((x)>(y)?(x):(y))

If your compiler supports typeof, more complicated operations can be put in the macro. You can then have the symbol foo(x) to support the same operation different types, but you can't vary the behaviour between different overloads. If you want actual functions rather than macros, you might be able to paste the type to the name and use a second pasting to access it (I haven't tried).

  • can you explain a little more on macro based approach. – FL4SOF Jan 26 '09 at 9:35
4

Leushenko's answer is really cool - solely: the foo example does not compile with GCC, which fails at foo(7), stumbling over the FIRST macro and the actual function call ((_1, __VA_ARGS__), remaining with a surplus comma. Additionally, we are in trouble if we want to provide additional overloads, such as foo(double).

So I decided to elaborate the answer a little further, including to allow a void overload (foo(void) – which caused quite some trouble...).

Idea now is: Define more than one generic in different macros and let select the correct one according to the number of arguments!

Number of arguments is quite easy, based on this answer:

#define foo(...) SELECT(__VA_ARGS__)(__VA_ARGS__)

#define SELECT(...) CONCAT(SELECT_, NARG(__VA_ARGS__))(__VA_ARGS__)
#define CONCAT(X, Y) CONCAT_(X, Y)
#define CONCAT_(X, Y) X ## Y

That's nice, we resolve to either SELECT_1 or SELECT_2 (or more arguments, if you want/need them), so we simply need appropriate defines:

#define SELECT_0() foo_void
#define SELECT_1(_1) _Generic ((_1),    \
        int: foo_int,                   \
        char: foo_char,                 \
        double: foo_double              \
)
#define SELECT_2(_1, _2) _Generic((_1), \
        double: _Generic((_2),          \
                int: foo_double_int     \
        )                               \
)

OK, I added the void overload already – however, this one actually is not covered by the C standard, which does not allow empty variadic arguments, i. e. we then rely on compiler extensions!

At very first, an empty macro call (foo()) still produces a token, but an empty one. So the counting macro actually returns 1 instead of 0 even on empty macro call. We can "easily" eliminate this problem, if we place the comma after __VA_ARGS__ conditionally, depending on the list being empty or not:

#define NARG(...) ARG4_(__VA_ARGS__ COMMA(__VA_ARGS__) 4, 3, 2, 1, 0)

That looked easy, but the COMMA macro is quite a heavy one; fortunately, the topic is already covered in a blog of Jens Gustedt (thanks, Jens). Basic trick is that function macros are not expanded if not followed by parentheses, for further explanations, have a look at Jens' blog... We just have to modify the macros a little to our needs (I'm going to use shorter names and less arguments for brevity).

#define ARGN(...) ARGN_(__VA_ARGS__)
#define ARGN_(_0, _1, _2, _3, N, ...) N
#define HAS_COMMA(...) ARGN(__VA_ARGS__, 1, 1, 1, 0)

#define SET_COMMA(...) ,

#define COMMA(...) SELECT_COMMA             \
(                                           \
        HAS_COMMA(__VA_ARGS__),             \
        HAS_COMMA(__VA_ARGS__ ()),          \
        HAS_COMMA(SET_COMMA __VA_ARGS__),   \
        HAS_COMMA(SET_COMMA __VA_ARGS__ ()) \
)

#define SELECT_COMMA(_0, _1, _2, _3) SELECT_COMMA_(_0, _1, _2, _3)
#define SELECT_COMMA_(_0, _1, _2, _3) COMMA_ ## _0 ## _1 ## _2 ## _3

#define COMMA_0000 ,
#define COMMA_0001
#define COMMA_0010 ,
// ... (all others with comma)
#define COMMA_1111 ,

And now we are fine...

The complete code in one block:

/*
 * demo.c
 *
 *  Created on: 2017-09-14
 *      Author: sboehler
 */

#include <stdio.h>

void foo_void(void)
{
    puts("void");
}
void foo_int(int c)
{
    printf("int: %d\n", c);
}
void foo_char(char c)
{
    printf("char: %c\n", c);
}
void foo_double(double c)
{
    printf("double: %.2f\n", c);
}
void foo_double_int(double c, int d)
{
    printf("double: %.2f, int: %d\n", c, d);
}

#define foo(...) SELECT(__VA_ARGS__)(__VA_ARGS__)

#define SELECT(...) CONCAT(SELECT_, NARG(__VA_ARGS__))(__VA_ARGS__)
#define CONCAT(X, Y) CONCAT_(X, Y)
#define CONCAT_(X, Y) X ## Y

#define SELECT_0() foo_void
#define SELECT_1(_1) _Generic ((_1), \
        int: foo_int,                \
        char: foo_char,              \
        double: foo_double           \
)
#define SELECT_2(_1, _2) _Generic((_1), \
        double: _Generic((_2),          \
                int: foo_double_int     \
        )                               \
)

#define ARGN(...) ARGN_(__VA_ARGS__)
#define ARGN_(_0, _1, _2, N, ...) N

#define NARG(...) ARGN(__VA_ARGS__ COMMA(__VA_ARGS__) 3, 2, 1, 0)
#define HAS_COMMA(...) ARGN(__VA_ARGS__, 1, 1, 0)

#define SET_COMMA(...) ,

#define COMMA(...) SELECT_COMMA             \
(                                           \
        HAS_COMMA(__VA_ARGS__),             \
        HAS_COMMA(__VA_ARGS__ ()),          \
        HAS_COMMA(SET_COMMA __VA_ARGS__),   \
        HAS_COMMA(SET_COMMA __VA_ARGS__ ()) \
)

#define SELECT_COMMA(_0, _1, _2, _3) SELECT_COMMA_(_0, _1, _2, _3)
#define SELECT_COMMA_(_0, _1, _2, _3) COMMA_ ## _0 ## _1 ## _2 ## _3

#define COMMA_0000 ,
#define COMMA_0001
#define COMMA_0010 ,
#define COMMA_0011 ,
#define COMMA_0100 ,
#define COMMA_0101 ,
#define COMMA_0110 ,
#define COMMA_0111 ,
#define COMMA_1000 ,
#define COMMA_1001 ,
#define COMMA_1010 ,
#define COMMA_1011 ,
#define COMMA_1100 ,
#define COMMA_1101 ,
#define COMMA_1110 ,
#define COMMA_1111 ,

int main(int argc, char** argv)
{
    foo();
    foo(7);
    foo(10.12);
    foo(12.10, 7);
    foo((char)'s');

    return 0;
}
1

Can't you just use C++ and not use all other C++ features except this one?

If still no just strict C then I would recommend variadic functions instead.

  • 3
    Not if a C++ compiler is not available for the OS he is coding for. – Brian Jan 26 '09 at 9:27
  • 2
    not only that but he might want a C ABI that does not have name mangling in it. – Spudd86 Jul 22 '11 at 22:21
-3

Try to declare these functions as extern "C++" if your compiler supports this, http://msdn.microsoft.com/en-us/library/s6y4zxec(VS.80).aspx

  • 3
    This may change name mangling to give them unique names (probably not), but it won't suddenly give C overload resolution rules. – Ben Voigt Nov 8 '13 at 15:53
-4

I hope the below code will help you to understand function overloading

#include <stdio.h>
#include<stdarg.h>

int fun(int a, ...);
int main(int argc, char *argv[]){
   fun(1,10);
   fun(2,"cquestionbank");
   return 0;
}
int fun(int a, ...){
  va_list vl;
  va_start(vl,a);

  if(a==1)
      printf("%d",va_arg(vl,int));
   else
      printf("\n%s",va_arg(vl,char *));
}
  • 2
    An answer should explain what it's doing and why it works. If it doesn't, how can it help anyone understand anything? – underscore_d Aug 20 '17 at 10:27
  • There is no overloading here. – melpomene Jun 25 '18 at 8:48
  • va_end was never called – user2262111 Jun 10 at 22:58

protected by Sheldore Jul 19 at 12:13

Thank you for your interest in this question. Because it has attracted low-quality or spam answers that had to be removed, posting an answer now requires 10 reputation on this site (the association bonus does not count).

Would you like to answer one of these unanswered questions instead?

Not the answer you're looking for? Browse other questions tagged or ask your own question.