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class A {
    virtual A* foo() = 0;

template<class T>
class B : public A {
    virtual T* foo() { return nullptr; }

class C : public B<C> {


This is a simplified implementation for Possibility to mix composite pattern and curiously recurring template pattern. I get the following error:

Return type of virtual function 'foo' is not covariant with the return type of the function it overrides ('C *' is not derived from 'A *')

Tested on clang 3.0, gcc 4.7 and visual studio 2008.

First solution:

class C : public A, public B<C> {}

compiles under visual studio with a warning that B is already a child of A and does not compile under clang with initial error.

Another workaround:

class D : public A {}
class C : public B<D> {}

solves the incompleteness issue, but I can't figure out how many A instances will I have. Intuition tells me that A is virtual, thus there should be only one.

Also this workaround creates unreadable code.

What does the standard states about this situation? Should this code compile? If not, why?

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It's always good to keep in mind that C is incomplete in its list of bases. –  Luc Danton Mar 22 '13 at 12:32

1 Answer 1

Your virtual function A::foo() returns an A*, while function B<C>::foo(), which is meant to override it, returns a C*.

This in theory does respect the principle of covariance, since C is indeed a specialization of (derives from) A, but at the point of instantiation, this is not known, because C is an incomplete type.

One possible way to re-think your design is to make A a class template as well, and let B propagate the template argument for T up to A:

template<typename T>
class A {
    virtual T* foo() = 0;

template<class T>
class B : public A<T> {
    virtual T* foo() { return nullptr; }

Concerning your workaround:

What does the standard states about this situation? Should this code compile? If not, why?

It shouldn't compile, because the mere fact of making C also derive from A explicitly (notice, that you would end up with two distinct base sub-objects of type A inside C) does not make C a complete type when instantiating B<C>. Per Paragraph 9.2/2 of the C++11 Standard:

A class is considered a completely-defined object type (3.9) (or complete type) at the closing } of the class-specifier. Within the class member-specification, the class is regarded as complete within function bodies, default arguments, and brace-or-equal-initializers for non-static data members (including such things in nested classes). Otherwise it is regarded as incomplete within its own class member-specification.

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Unfortunately this breaks the sole purpose of this code: to create polymorphic base class A. –  Vytis Valentinavičius Mar 22 '13 at 12:48
function B<C>::foo(), which is meant to override it, returns a B<C>* – am I reading it wrong, or does B<C>::foo() return C* instead? –  ulidtko Mar 22 '13 at 12:56
@ulidtko: Correct, that was a mistake of mine. Thank you. –  Andy Prowl Mar 22 '13 at 12:56
Also, what I'd like to see in the answer is why C isn't a complete type. (It looks to be completely defined, so uhh... what the hell.) –  ulidtko Mar 22 '13 at 12:59
@ulidtko: That is because of the paragraph from the standard I quoted. A class type is complete only after the closing }. Here, B<C> is instantiated before the closing } is met. Therefore, C is incomplete and the compiler has the right not to know that it derives from A. This is the reason for the error saying covariance is not respected. –  Andy Prowl Mar 22 '13 at 13:01

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