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Consider the following code:

template <typename T>
class B

template <typename T>
B<T> f(T& t)
    return B<T>();

class A
    class C {};
    C c;
    A() {}

    decltype(f(c)) get_c() const { return f(c); }

int main()
    A a;

When I try to compile this, I get the error:

test.cpp: In member function 'B<A::C> A::get_c() const':
test.cpp:31:46: error: conversion from 'B<const A::C>' to non-scalar type 'B<A::C>' requested

It seems that in the decltype, the compiler doesn't know that this is a const member function and therefore c is of type const C, and as a result incorrectly deduces the type of f(c) to be B<C> rather than B<const C> which is what it really is.

Am I doing something incorrectly, or is this a compiler bug? I use gcc 4.6, but 4.4 and 4.5 exhibit the same behaviour.

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4 Answers 4

up vote 7 down vote accepted

The compiler operates correctly according to the current C++0x WP. See this issue report, which is currently being worked on.

Possibly the final C++0x Standard won't change the meaning of your decltype application in the return type before the function name. You would need to move it to after the parameter list using -> decltype(f(c)), which hopefully will do The Right thing in final C++0x.

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Do note that C++11 does incorporate the fix, so you can use the trailing syntax to get proper const correctness. –  Nicol Bolas Apr 12 '12 at 23:44

No, decltype is not supposed to take into account whether the function is const or not, because it can't. The same could have been written differently:

typedef decltype(f(c)) return_type;

return_type get_c() const { return f(c); }

Correction: decltype(f(c)) shouldn't even compile, because c is not static.

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Yes it should compile. In unevaluated contexts you can access non-static data-members. –  Johannes Schaub - litb Feb 8 '11 at 21:32
@Johannes, I might be wrong, but as far as I remember access to non-static members only allowed inside the function body. If the function above is modified to use trailing return type, then you can have access to non-static members. –  Gene Bushuyev Feb 8 '11 at 21:52
Yes, I think you're wrong. See my answer to a related quesition here: stackoverflow.com/questions/4849556/… –  TonyK Feb 8 '11 at 21:59
@TonyK, the fact that it compiles under g++ 4.4 isn't a proof of standard conformance. The standard specifies in 9.3.1/3 that access to non-static members is allowed only from inside the function body, so trailing return type is necessary in this case. –  Gene Bushuyev Feb 8 '11 at 22:27
N3225 does not say that. Read it closely, then you will see that it doesn't. Also cf 5.1.1/10. –  Johannes Schaub - litb Feb 8 '11 at 22:44

f needs to take an rvalue reference, not an lvalue reference.

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I don't think you're allowed to use decltype on anything you wouldn't normally be able to call. I haven't been able to find anything in the standard that would allow you to access c, even within a decltype expression, outside of anywhere you could use c. Since you don't have a this pointer at the point you're trying to do your thing, I don't think you can do what you're trying to do. Doing so doesn't work in MSVC 2010 at least, and it has nothing to do with const.

I considered using declval to get one but you can't access A&&.c because A is an incomplete type at that point. I can't see anyway to do what you're trying to do other than something like so:

decltype(f(declval<C const>())) get_c() const { ... }
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The respective text is at 5.1.1/10 last bullet. –  Johannes Schaub - litb Feb 8 '11 at 21:40
MSVC does not have this because it's working to an earlier Standard draft. –  Puppy Feb 8 '11 at 22:01

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