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I don't understand why this program produces the output below.

void blah(const char* )       {printf("const char*\n");}
void blah(const std::string&) {printf("const string ref\n");}
template<class t>
void blah(t)                  {printf ("unknown\n");}

int main(int, char*)
  char a[4];
  std::string s;


const char*
const string

In VS2008. It is willing to convert the std::string to a const reference, but why won't it convert the char* to a const char* and use the overload?

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it's simply choosing the closest match from the options you've given it. class t can match char* exactly, with no conversion needed, so it chooses that one in preference. –  Dave Jun 7 '13 at 22:29
(incidentally, the string example isn't being converted to a reference, but rather it defaults to being passed by reference and only becomes a pass-by-copy if that has no matches. Templates can't change the reference-ness (except for a special case for rvalue references), so that template can only accept classes by copy) –  Dave Jun 7 '13 at 22:32
What do you mean that the string "defaults to being passed by reference"? Why can't the type t be std::string&? What gets me is that neither calls are exact matches. Neither the string nor the char* is const. –  Tyson Jacobs Jun 7 '13 at 23:38
As I said, "it defaults to being passed by reference and only becomes a pass-by-copy if that has no matches". In other words, it tries string& then const string& then string and const string. The template can only be the latter 2 (because "Templates can't change the reference-ness"). The first doesn't exist, so the first good match is the second. –  Dave Jun 7 '13 at 23:44
Ah, I understand, thanks! –  Tyson Jacobs Jun 7 '13 at 23:57

2 Answers 2

The type of "hi" is const char[3], whereas the type of a is char[4].

So, the first call requires only array-to-pointer conversion (aka "decay"). The third call requires only binding an object to a reference-to-const (I don't think "converting" is the correct terminology for reference-binding, although I may be mistaken). The second call would require array decay and a pointer conversion in order to call the const char* overload.

I claim without actually checking the overload resolution text in the standard that this extra step is what makes the template a better match than the const char* overload.

Btw, if you change "unknown\n" to "%s\n", typeid(t).name() then you can see what the type t was deduced as. For your code, it is deduced as char* (because arrays can't be passed by value), but see what happens if you change the template to take a t& parameter instead of t. Then t can be deduced as char[4].

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This seems incorrect. blah((char*)"hi") still produces unknown. –  Tyson Jacobs Jun 7 '13 at 23:35
@TysonJacobs of course it does. Just as blah((const char*)a) will produce const char*. An explicit cast happens before function resolution, so the function call would have to convert it back! –  Dave Jun 7 '13 at 23:41
@Dave but your point was that the template matched the call to blah("hi") because it had to "decay" the array to a pointer and convert the pointer type. Casting to char* eliminates one of those steps. –  Tyson Jacobs Jun 7 '13 at 23:45
@TysonJacobs one of us is confused. blah("hi") goes to const char*, whereas the cast changes that to unknown. That is exactly the behaviour I would expect from the rules me and Steve Jessop mentioned, so I don't see the problem… –  Dave Jun 7 '13 at 23:47
@TysonJacobs: blah((char*)a) requires a pointer conversion to call the const char* overload. So the fact that it selects the template seems entirely consistent with my claim/guess that it's the pointer conversion that makes the const char* overload a worse match than the template. The interesting thing about the array decay, is that although it's a conversion it doesn't result in a worse match. In short the reason for the asymmetry is that if you start with a non-const array or ptr then you need a pointer conversion to call the const char* overload. With a const array you don't. –  Steve Jessop Jun 8 '13 at 0:11

Because arrays and pointers are different types.



EDIT: ... which is to say that the template is a better match for the array type, even though the other one would be called if the template didn't exist.

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...did you actually try that? It produces the exact same output. Also arrays and pointers are the same type. See for example this quick testcase: codepad.org/vlvY5Pgb (it produces a compiler error because char[2] == char[4] when used as a function parameter) –  Dave Jun 7 '13 at 22:35
@Dave Wrong, they are different types. The example you post is misleading since array declarations in formal arguments are discarded and treated as pointers – but only there. –  Konrad Rudolph Jun 7 '13 at 22:43
yes but this question is about function arguments. I (of course) know that char a[2] and char *a are very different types, but they will both cause the exact same function to be resolved when used as a parameter. –  Dave Jun 7 '13 at 22:46
or, to put it another way, the code you suggest (&a[0]) makes absolutely no difference here. –  Dave Jun 7 '13 at 22:47
Function parameters cannot have array type. Function arguments can. If you add an overload blah(char (&)[4]);, then blah(a) and blah(&a[0]) are not the same. –  aschepler Jun 7 '13 at 22:57

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