I really don't understand this, I thought that compiler first executes what is in braces and then gives the result to the most appropriate function. Here it looks like it gives the function an initializer list to deal with it...

#include <string>
#include <vector>
using namespace std;

void func(vector<string> v) { }

void func(vector<wstring> v) { }

int main() {
  func({"apple", "banana"});


<stdin>: In function 'int main()':
<stdin>:11:27: error: call of overloaded 'func(<brace-enclosed initializer list>)' is ambiguous
<stdin>:11:27: note: candidates are:
<stdin>:6:6: note: void func(std::vector<std::basic_string<char> >)
<stdin>:8:6: note: void func(std::vector<std::basic_string<wchar_t> >)

Why isn't my func(vector<string> v) overload called, and can I make it so?


1 Answer 1


This one was subtle.

std::vector has a constructor taking two range iterators. It is a template constructor (defined in of the C++11 Standard):

template<typename InputIterator>
vector(InputIterator first, InputIterator last, 
const allocator_type& a = allocator_type());

Now the constuctor of std::vector<wstring> accepting an initializer_list is not a match for the implicit conversion in your function call, (const char* and string are different types); but the one above, which is of course included both in std::vector<string> and in std::vector<wstring>, is a potentially perfect match, because InputIterator can be deduced to be const char*. Unless some SFINAE technique is used to check whether the deduced template argument does indeed satisfy the InputIterator concept for the vector's underlying type, which is not our case, this constructor is viable.

But then again, both std::vector<string> and std::vector<wstring> have a viable constructor which realizes the conversion from the braced initializer list: hence, the ambiguity.

So the problem is in the fact that although "apple" and "banana" are not really iterators(*), they end up being seen as such. Adding one argument "joe" to the function call fixes the problem by disambiguating the call, because that forces the compiler to rule out the range-based constructors and choose the only viable conversion (initializer_list<wstring> is not viable because const char* cannot be converted to wstring).

*Actually, they are pointers to const char, so they could even be seen as constant iterators for characters, but definitely not for strings, as our template constructor is willing to think.

  • @OmnipotentEntity: Thank you :-)
    – Andy Prowl
    Jan 29, 2013 at 17:39
  • 2
    Now I hate so-called "uniform initialization" even more now, it's interfered with the feature I liked, std::initializer_list. Jan 29, 2013 at 17:45
  • 1
    @Praetorian: You're right, it does, but as constant iterator of chars, not of strings or wstrings.
    – Andy Prowl
    Jan 29, 2013 at 18:00
  • 1
    @AndyProwl your description makes it sounds to me "this constructor is a better match than the initializer list constructor, so it is preferred". But even if the template constructor would be a better match if the constructors would be compared against each other, the compiler would still use the initializer list constructor. Because the compiler first only looks at the initializer list constructors. And only if they don't match at all, then it considers all other constructors in addition, this time taking the initializer list elements as arguments separately, instead of the whole list. Jan 30, 2013 at 22:50
  • 2
    @AndyProwl because for vector<wstring>, it picks the template constructor and then both funcs match, with no one being better than the other. If one of the funcs would have its parameter of type std::initializer_list<X> and the other would not, that func would be preferred. It does not matter than in a nested overload resolution context, one parameter of the functions use an initializer list constructor to initialize itself. What matters is the parameter type itself, which is in both cases vector<X>. Jan 30, 2013 at 22:59

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