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I have this very simple wrapper template:

template<class T>
struct wrapper {
    inline operator T () {
        return v;
    }

    inline wrapper(T v):v(v) { }

    T v;
};

Trying to use it with any non-primitive type with (for example) comparison operator relying on the template having it defined doesn't look promising:

std::string t = "test";
assert(t == t);

typedef wrapper<std::string> string_wrapper;
assert(string_wrapper(t) == string_wrapper(t));

GCC 4.4.5 complains with this error:

error: no match for ‘operator==’ in ‘wrapper<std::basic_string<char> >(std::basic_string<char>(((const std::basic_string<char>&)((const std::basic_string<char>*)(& t))))) == wrapper<std::basic_string<char> >(std::basic_string<char>(((const std::basic_string<char>&)((const std::basic_string<char>*)(& t)))))’

What is interesting is that GCC triple-casts the template then fails to use operator == that was defined for std::string.

I don't think that implicit coercion is impossible, since if I change std::string to int or double, bool or anything primitive, GCC will choose the correct operator.

I do not want to define operator == for the wrapper struct, because that operator is just an example, and I need wrapper to 'feel' just like the real type regarding operators.

Just in cast GCC misunderstands my syntax, if I create a wrapper and try to compare it to itself, GCC complains again (though without triple casting) that it cannot find a matching == operator:

typedef wrapper<std::string> string_wrapper;
string_wrapper tw(t);
assert(tw == tw);

error: no match for ‘operator==’ in ‘tw == tw’

Why can't GCC find and/or use std::string operator == std::string when wrapper provides the cast?

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I tried that as well, it stills errors. I even tried making the entire wrapper struct const-correct - the error still occurs. –  LiraNuna Feb 16 '11 at 3:09
1  
What's the purpose of the wrapper class? –  In silico Feb 16 '11 at 3:10
    
In this case, nothing. However it's a simplified test case of a more complex problem primarily used to generate several other templates doing the same thing with extra functionality. I understand this example is really stupid and useless, just like any other example :) –  LiraNuna Feb 16 '11 at 3:12
    
If any of you question the existence of wrapper, I will happily supply a real world example. –  LiraNuna Feb 16 '11 at 3:16
1  
As an aside, your use of the inline keyword here is redundant; member functions defined in the class definition are implicitly inline. –  GManNickG Feb 16 '11 at 3:18

3 Answers 3

That operator T is called a "conversion operator" or "conversion function" instead of a cast. "Conversions" are implicit; casting is explicit.

The compiler can't find the operator== for std::string because the overload resolution rules don't allow that to happen. More details about what you're really trying to do could help provide a solution.

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Why when I change std::string to int it works? Also, in the same project, I got two separate classes that have casting operators to the same class, which do define an equality operator - and that works great. What is the difference here? –  LiraNuna Feb 16 '11 at 3:13
    
@LiraNuna: Built-in operators are considered independently of user-defined operators WRT to name lookup and context of the expression. See §13.3.1.2p3 for details. –  Fred Nurk Feb 16 '11 at 3:16
    
That is understood. How about the fact I have two distinct struct that define a casting operator to another class, which defines an operator ==, and GCC happily finds the correct way to cast both into it? –  LiraNuna Feb 16 '11 at 3:19
    
@LiraNuna: I tend to purposefully avoid implicit conversions. I suspect there's a much better solution for what you really want to do that doesn't need them. –  Fred Nurk Feb 16 '11 at 3:23
up vote 0 down vote accepted

Apparently this is a GCC 4.5 bug. The code is valid, unlike what Fred Nurk says.

http://gcc.gnu.org/bugzilla/show_bug.cgi?id=45383

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You have picked the wrong PR. It has nothing to do with this. –  Johannes Schaub - litb Feb 21 '11 at 6:12

The questioner has answered itself with some GCC PR, but which really does not answer his question.

The reason is like @Fred describes. Reducing it:

template<typename T>
struct A {
  operator T() { return T(); }
};

int main() {
  A<std::string>() == A<std::string>();
}

What can the compiler do? It could call operator std::string() on both operands and then do the comparison. But why should it do that call in the first place? It first needs to find an operator== that has two parameters of type std::string. Let's look at how its operator is defined

template<class charT, class traits, class Allocator>
bool operator==(const basic_string<charT,traits,Allocator>& lhs,
                const basic_string<charT,traits,Allocator>& rhs);

There we have it. It first needs to do template argument deduction, and the fact that A does not match const basic_string<> will make it so that this operator== is ignored. You are lucky that operator== is found anyway using ADL so that it does argument deduction in the first place (since std::string is a template argument of your type, it will consider namespace std by ADL and find this operator).

So we have no suitable operator== to call and therefor GCC is alright with rejecting your code for the reasons @Fred gave in a nutshell. In the end, trying to make a class behave like another type is deemed to failure.

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