What does this error message mean?

error: call of overloaded ‘setval(int)’ is ambiguous
huge.cpp:18: note: candidates are: void huge::setval(unsigned int)
huge.cpp:28: note:                 void huge::setval(const char*)

My code looks like this:

#include <iostream>
#define BYTES 8
using namespace std ;

class huge {
    unsigned char data[BYTES];
    void setval(unsigned int);
    void setval(const char *);  

void huge::setval(unsigned int t) {
    for(int i = 0; i< BYTES ; i++) {
        data[i] = t;
        t = t >> 1;

void huge::setval(const char *s) {
    for(int i = 0; i< BYTES ; i++)
        data[i] = s[i];

int main() {
    huge p;
    return 0;
  • 5
    I guess the answer to this question would depend on which version of the function you ARE trying to call. I could assume, but clearly I can't be sure either way unless you tell me. Would that work with the compiler I wonder... Jan 12 '11 at 17:59
  • @KonradRudolph The literal 0 is a valid value for both unsigned int and const char *.
    – kitti
    Mar 23 '17 at 22:47
  • @RyanP Yeah, I'm generally aware. No idea what I meant back then. Mar 23 '17 at 22:51

The literal 0 has two meanings in C++.
On the one hand, it is an integer with the value 0.
On the other hand, it is a null-pointer constant.

As your setval function can accept either an int or a char*, the compiler can not decide which overload you meant.

The easiest solution is to just cast the 0 to the right type.
Another option is to ensure the int overload is preferred, for example by making the other one a template:

class huge
  unsigned char data[BYTES];
  void setval(unsigned int);
  template <class T> void setval(const T *); // not implemented
  template <> void setval(const char*);
  • For what it's worth, I had to include the specialization outside of the class declaration. Basically include template <> void huge::setval(const char*); just below your class declaration. If I didn't, I received an error about specializing the template in the class scope. Great trick though, this has stumped me before with some of my interfaces.
    – vmrob
    Apr 23 '14 at 1:50
  • 2
    0 has only one meaning in C++. It is an integer literal of the type int. If the OP really had an overload taking an int and another taking a char*, the overload resolution would succeed and chose the int overload. However, OP uses unsigned int as the parameter type. And those two conversions, int -> unsigned int vs null pointer constant -> char* are ambiguous.
    – dyp
    Apr 4 '15 at 21:42
  • @dyp: If 0 has only one meaning, how can it be involved in two ambiguous conversions with different starting types? Apr 5 '15 at 6:58
  • 1
    I don't quite understand what you mean with "starting types". The type of 0 is int. An int can be converted to an unsigned int. A constant expression of type int that evaluates to 0 can also be converted to any pointer type. For example, g++ and clang++ accept 1-1 as a valid null pointer constant (though clang++ only in C++03 mode). That is, 0 is not special, it simply fulfils the conditions to enable those two separate conversions.
    – dyp
    Apr 5 '15 at 13:26
  • What about if I cast and it still complains that it's ambiguous? I have a struct declaration with a constructor, and it claims to be ambiguous between the constructor and the actual struct Thing { line? Sep 16 '18 at 9:39

The solution is very simple if we consider the type of the constant value, which should be "unsigned int" instead of "int".

Instead of:




The suffix "u" tell the compiler this is a unsigned integer. Then, no conversion would be needed, and the call will be unambiguous.

  • 1
    Best answer, simple and elegant way to tell the compiler
    – Bug Killer
    Jul 13 '15 at 20:02

replace p.setval(0); with the following.

const unsigned int param = 0;

That way it knows for sure which type the constant 0 is.



p.setval(static_cast<const char *>(0));


p.setval(static_cast<unsigned int>(0));

As indicated by the error, the type of 0 is int. This can just as easily be cast to an unsigned int or a const char *. By making the cast manually, you are telling the compiler which overload you want.


Cast the value so the compiler knows which function to call:

p.setval(static_cast<const char *>( 0 ));

Note, that you have a segmentation fault in your code after you get it to compile (depending on which function you really wanted to call).


That is ambiguous because a pointer is just an address, so an int can also be treated as a pointer – 0 (an int) can be converted to unsigned int or char * equally easily.

The short answer is to call p.setval() with something that's unambiguously one of the types it's implemented for: unsigned int or char *. p.setval(0U), p.setval((unsigned int)0), and p.setval((char *)0) will all compile.

It's generally a good idea to stay out of this situation in the first place, though, by not defining overloaded functions with such similar types.

  • Can't wait for C++0x, when we'll finally have the nullptr keyword :) Jan 12 '11 at 18:05
  • p.setval((char *)0) will compile, but application crashes. p.setval(0U) works fine
    – Rajesh
    Aug 10 '17 at 7:24

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

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