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I've been playing with the return type deduction supported in g++ with -std=c++1y.
If you prototype a function with an explicit return type, and then later try to define the function with return type deduction, the compiler complains of an ambiguous old declaration:

std::string some_function();
auto some_function(){ return std::string{"FOO"}; } //fails to compile

Is there a good reason why this doesn't work?
My rationale for using return type deduction in the definition is to keep the code clean, but want an explicit type in the prototype for self-documenting reasons. Recommendations on best practices for when and when not to use return type deduction would be appreciated :)

To be more clear, I would like answers to:
1. Is this an implementation mistake in the compiler? (I am fairly sure it is not)
2. Could this type of deduction be done, but isn't allowed by the proposal to the standard? If so, why not?
3. If this is really ambiguous, what are some examples where deducing the type and trying to match it with an explicit forward declaration would get you into trouble?
4. Are there deeper implementation specific issues behind this?
5. Is it simply an oversight?

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For when to use it, see my previous question. –  chris Aug 29 '13 at 19:39
I found this in the proposal: auto f(); // return type is unknown auto f() { return 42; } // return type is int auto f(); // redeclaration int f(); // error, declares a different function. Let me check N3690. –  chris Aug 29 '13 at 19:42
Ah, N3690 has the same with error, cannot be overloaded with auto f(). I can't find where it says it, but you're overloading it instead of defining it. –  chris Aug 29 '13 at 19:51
Not a real answer, but I'd feel better spelling out the signature the same way in the declaration and definition (make sure they stay the same), and keep auto for cases where there is no forward declaration. –  Marc Glisse Aug 29 '13 at 20:13
Works fine for me: gcc.godbolt.org/… –  user1233963 Aug 30 '13 at 12:15

3 Answers 3

up vote 3 down vote accepted

It's because of how the function tables and overloaded functions work in C++.

When the compiler reads your std::string some_function(); it creates a spot for it to reference in the binary and says if "this function is ever called jump to this spot".

So we have a vtable that looks like this...

(Address offset)  (Symbol)
0x????????       std::string somefunction();

Now it gets to your auto some_function() {...}. Normally it would first look in the function table to see if auto somefunction(); exists in the table or some variation there of, but the compiler notices that this is a implementation and it has the auto keyword so to reduce the entropy it writes *blank* some_function(); to the function table and ties to solve the return type.

Now the Function table looks like this...

(Address offset)  (Symbol)
0x????????       std::string somefunction();
0x????????       ????? somefunction();

So it chugs along compiling code into binary when it finds out the return type which in this case is std::string. The compiler now knows what the return type is so it goes to the function table and changes auto somefunction(); too std::string somefunction();.

Now the Function table looks like this...

(Address offset)  (Symbol)
0x????????       std::string somefunction();
0x????????       std::string somefunction();

Now the compiler goes back and continues to compile the function. Once it's done it goes back and finishes up the vtable only to find the same symbol is in there twice. It's now ambiguous to which symbol we are referring too.

So what is the reason for this?

Not 100% sure but vtables are made long before your code is worked down enough to allow for the deduction type to be made. So the only option the compiler has to work with at that stage in time is to just assume it's a new symbol. It's just something I've noticed looking at symbol tables all day and writing my own C++11 compiler.

I however can in no way speak for other compilers where lots of optimizations and other steps are introduced, I just work with the bare bones, however that is my understanding of the standard.

One last thing the type is completely arbitrary. It doesn't even matter if they don't match at the time of deduction. It never get's that far. The problem arises that there are two of the same symbols in the table, and you can't overload on return types.

share|improve this answer
If I'm wrong and it's failing for another reason besides this I would love to know. It would help me make better compilers in the future. –  Matt Kaes Sep 3 '13 at 16:39

you need to do it as:

auto some_function() -> decltype(std::string) { return std::string{"FOO"}; } 

for more info look in http://en.wikipedia.org/wiki/C%2B%2B11 -> alternative function syntax

share|improve this answer
This is only true for C++11, not C++1y, and the decltype shouldn't be there. –  chris Aug 29 '13 at 19:44
isn't c++1y an update to c++11, which should contain all c++11's stuff? –  Michał Walenciak Aug 29 '13 at 19:46
auto some_function() -> std::string would be fine but this does not address my question as I am wondering about why return type deduction doesn't work with an explicitly typed prototype, while this would be an explicitly typed definition. –  mio iwakura Aug 29 '13 at 19:58
Yes (I can't think of any breaking changes), but stating that it must be done the C++11 way is wrong because there is a new way to do it. I might have misinterpreted your answer as this instead of merely suggesting the C++11 syntax to fix the problem, but it still doesn't explain why this is necessary. –  chris Aug 29 '13 at 19:59
@mioiwakura: Your example is simple, but image you would place a definition of this function to .h file. How could the other compilation units know what is the right return type? I think this is way you cannot do it like this, even if it looks fine –  Michał Walenciak Aug 29 '13 at 20:31

EDIT: (Based on first comment, anyway I dont like this method)

Based in type deduction with an explicit prototype:

when C++ compiler transform the code to assambler auto data deduction type is begin transform to the most logic data type, as well the return method and calls should be specified:

Error example:

using namespace std;

auto some_function(){ return string{"FOO"}; } //This gonna take a error cause
//isn't used as logic operator so the auto deduction data type can't be
//transformed to assably variable wich can handle the retrun type.

int main() {
    cout << "HI";
        return 0;

This is another example:

using namespace std;

auto some_function(){ return 1; }

int FunctionWithALongParameter(long handle){ return handle + 1; }

int main() {

  cout << some_function() << endl << FunctionWithALongParameter(some_function());
  //The auto deduction data type deduces than the return value is a long cause a
  //long matches in both cases.
        return 0;

So, now let's go to your error:

using namespace std;

auto some_function(){ return string{"FOO"}; } //This throw a error cause the
//return data type is specified but assambler dosn't know wich data type sould

int main() {

    cout << "HI";
        return 0;

The fix:

using namespace std;

auto some_function(){ return string{"FOO"}; }

int main() {

    cout << some_function(); //This prevents the error cause now auto deduction
    //data type know exacly how to operand this, the variable should be compatibe
    //with a buffer join so char * the data type should be char *.
        return 0;

Take a look in this online IDE:

http://ideone.com/VvDdLQ and see how it works.

Another not deduction explicit solution:

std::string is a typedef of basic_string< char > (Edited by first comment)

typedef basic_string<char> string;

Here are the constructors:

string(); // Creates a new instance
string (const string& str); //Copys another string instance
string (const string& str, size_t pos, size_t len = npos);// Create a Substring
string (const char* s); // Initialize from c-string
string (const char* s, size_t n); // Initialize from sequence
string (size_t n, char c); // Fill with char the size_t of the string
template <class InputIterator> string  (InputIterator first, InputIterator last);

so, in your case the string should be initialized like so:

std::string(char *); // Char pointer

and just to be a little bit carefully (Retail programing like):

  std::string some_function(){ return std::string("FOO"); }
//^ Add a type                             Fix this ^

Please read follow documentation:

http://www.cplusplus.com/reference/string/string/string/ String constructor

http://www.cplusplus.com/reference/string/string/ String definition

http://ideone.com/czUq5r See how the code works.

I hope it mightly helps.

share|improve this answer
This has nothing to do with the question. std::string is a type alias of std::basic_string<char>. char * cannot point to a string literal. auto is perfectly fine where it is, the return type is deduced. The uniform initialization of the string is fine, and this reference is superior to that one. –  chris Aug 29 '13 at 19:54
you are right about the alias, I mistaked that but: ideone.com/czUq5r is working at least. –  Marcos Eusebi Aug 29 '13 at 20:00

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