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Would any one knows according to what rules code below doesn't compile?

template <class T>
struct B
    typedef T type;

template<class T>
struct X
template<class T>

Please see comment inside the code.

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3 Answers 3

How do you think that will work? The compiler will look to see if there is a class T somewhere that has a typedef "type" to your class?

It just won't. Even though it's a pointer.

Remember that presumably your B template is presumably specialised in places so that type is not always T*, but it can't deduce it with reverse engineering.

For those who did not understand my answer fully, what you are asking the compiler to do is find a class U such that B::type is the class you pass in as a parameter.

class Foo;
class Bar;

template<> struct B<Foo>
  typedef int type;

template<> struct B<Bar>
  typedef int type;

X<int*> // ambiguous, T is Foo or Bar?

It is difficult to know exactly why you are trying to do what you are. You can do a partial specialization on all pointers and then a total specialization on specific pointers, which could be implement in terms of another template.

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I don’t really understand this answer. The compiler knows which class to use – B<T>. Whenever X is instantiated, the compiler is absolutely capable of searching through all partial specializations of X for the most specific. In fact, that’s what it always does. Consequently, Nawaz’ answer is correct. –  Konrad Rudolph Mar 6 '11 at 15:15
@CashCow just like Kondrad I really see no problem for compiler... –  There is nothing we can do Mar 6 '11 at 15:20
(Continued) Or rather, I’d expect Nawaz’ answer to be correct. Clearly it doesn’t work but I fail to understand the compiler’s complaint (GCC’s message is similar to VS 2010’s). –  Konrad Rudolph Mar 6 '11 at 15:22
@Kondrad Nawaz's answer cannot be correct if it doesn't compile, that's what I would think anyway. –  There is nothing we can do Mar 6 '11 at 15:23
@Kondrad to your last comment: That exactly what I'm stuck with. According to which "bullet" in std this doesn't compile? –  There is nothing we can do Mar 6 '11 at 15:25

You need to use typename keyword as,

template<class T>
struct X<typename B<T>::type*>

It's because B<T>::type is a dependent name. So typename is required!



Even after putting typename, it isn't compiling. I think it's because deduction of type T in B<T> from X<U> is difficult, or possibly impossible, for the compiler. So I believe its non-deduced context.

See a similar example here and the discussion:

Template parameters in non-deduced contexts in partial specializations

However, if you change the specialization to this:

template<class T>
struct X<B<T> >

Then it becomes the deducible context, and so would compile.

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@Navaz I did as you proposed and I've got: Error 1 error C2764: 'T' : template parameter not used or deducible in partial specialization 'X<B<T>::type*>' from VS 2010 –  There is nothing we can do Mar 6 '11 at 15:11
@There is nothing. Because it can't. What you are trying to do is beyond the scope of the compiler. –  CashCow Mar 6 '11 at 15:13
@CashCow what do you mean by beyond the scope of compiler (and please, I'm not trying to have a go with you or with anyone here, I'm just trying to understand) –  There is nothing we can do Mar 6 '11 at 15:23
@There is nothing we can do: Please see my edit. And the link to a good topic discussing the same problem! –  Nawaz Mar 6 '11 at 15:52
It should compile, I think. It just should never match that specialization. –  Johannes Schaub - litb Mar 6 '11 at 19:38

Assuming you already added typename as suggested by Nawaz.

The problem is exactly explained in the error message you encounter: "template parameter is not deducible in partial specialization B<T>::type*. The problem is that B<T>::type and T is exactly the same for all types T. Consider the following example:

class MyClass1 {};
typedef typename B<MyClass>::type MyClass2; //(*)

X<MyClass*> obj1;
X<MyClass2*> obj2;

The result of line (*) is a type MyClass2 which is essentially MyClass1. So, obj1 and obj2 should be objects of the same class. Now, which version of template X should they use?

If you would expect the specialised version of X, tell me if the answer should be the same if line (*) is removed (and obviously obj2 as well). Still obj1 should be the specialised version of X as line (*) has nothing to do with it.

But now we expect the compiler to detect that some type can be potentially declared as B<T>::type although we never do this. We expect the compiler to verify all possible template instantiations to check if there is no strange typedef in one of them.

I hope this clarifies why such specialisation cannot be handled by the compiler.

An alternative that might help

I believe your problem could be attacked by creating a trait class for explicitly marking types that should be handled in a special way. Something like this:

template <bool v>
struct boolean_value {
  static const bool value=v;

template <typename T>
struct is_my_interesting_type : public boolean_value<false> {};

class MyClass {

template <>
struct is_my_interesting_type<MyClass> : public boolean_value<true> {};

template <typename T, bool special>
class  InternalX {
  ... //generic version of your template X

template <typename T>
class InternalX<T,true> {
  ... //special version of your template X

template <typename T>
class X : public InternalX<T,is_my_interesting_type<T>::value> {};

Also, you might be interesting how it is done in boost library, in particular Boost.Type_Traits

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“The problem is that B<T>::type and T is exactly the same for all types T” – No. That is not a problem (or should not be). “Now, which version of template X should they use?” – Obviously the specialized version because your types are both pointers. The usage of B<T>::type instead of just T here is completely irrelevant. What’s relevant is that the specialization is a pointer. –  Konrad Rudolph Mar 6 '11 at 16:16
If you want to have specialised version for all pointeres you should have X<T*> and not X<B<T>::type*>. The latter suggests that you want the specialisation only for some pointers but not all of them. That, and not the fact that you have a pointer, is a problem. You will get exactly the same error if you remove *. –  CygnusX1 Mar 6 '11 at 16:26
"The usage of B<T>::type instead of just T here is completely irrelevant" -> it is relevant and crucial for the compiler. It cannot deduct what B<T> is needed to get a match with current type that you want instantiate with. Morover, he doesn't even know that he should actually look into template class B when searching for a match. –  CygnusX1 Mar 6 '11 at 16:34
Why is it a problem though? Why can it not deduce B<T>? (In fact, there is no deduction, it’s a straightforward replacing). –  Konrad Rudolph Mar 6 '11 at 17:53
Imagine you have 1000 template classes which have typedefs inside. Do you think the compiler will check all of them for a match? And what if there are more than one match? –  CygnusX1 Mar 6 '11 at 22:46

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