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I don't get the reason for which a parameter pack must be at the end of the parameter list if the latter is bound to a class, while the constraint is relaxed if the parameter list is part of a member method declaration.

In other terms, this one compiles:

class C {
    template<typename T, typename... Args, typename S>
    void fn() { }

The following one does not:

template<typename T, typename... Args, typename S>
class C { };

Why is the first case considered right and the second one is not?
I mean, if it's legal syntax, shouldn't it be in both the cases?

To be clear, the real problem is that I was defining a class similar to the following one:

template<typename T, typename... Args, typename Allocator>
class C { };

Having the allocator type as the last type would be appreciated, but I can work around it somehow (anyway, if you have a suggestion it's appreciated, maybe yours are far more elegant than mine!!).
That said, I got the error:

parameter pack 'Args' must be at the end of the template parameter list

So, I was just curious to fully understand why it's accepted in some cases, but it is not in some others.

Here is a similar question, but it simply explains how to solve the problem and that was quite clear to me.

share|improve this question
You're using a default for the last type parameter -- as far as I recall that changes things a lot. (But I forget the details). Perhaps you should include the defaults in both of your opening examples? – Aaron McDaid Jan 22 at 7:17
Can you give an example of how you plan to call these templates? I'm not sure it's very relevant, but it might help – Aaron McDaid Jan 22 at 7:18
Sorry, the default parameter was an error, no longer there. I plan to use that template as any other: C<int, float, std::allocator<int>>. The issue is in the fact that that syntax is right for a member method, but it is not for a class definition and I don't understand why it is not!! – skypjack Jan 22 at 7:34
up vote 14 down vote accepted

It is valid for function templates but only when argument deduction can help the compiler resolve the template parameters, as it stands your function template example is virtually useless because

template<typename T, typename... Args, typename S> void fn() { }
int main() { fn<int, int, int>(); }
test.cpp: In function 'int main()':
test.cpp:2:32: error: no matching function for call to 'fn()'
 int main() { fn<int, int, int>(); }
test.cpp:1:57: note: candidate: template<class T, class ... Args, class S> void fn()
 template<typename T, typename... Args, typename S> void fn() { }
test.cpp:1:57: note:   template argument deduction/substitution failed:
test.cpp:2:32: note:   couldn't deduce template parameter 'S'
 int main() { fn<int, int, int>(); }

the compiler has no way of determining which template parameters belong to the parameter pack, and which to S. In fact as @T.C. points out it should actually be a syntax error because a function template defined in this manner cannot ever be instantiated.

A more useful function template would be something like

template<typename T, typename... Args, typename S> void fn(S s) { }

as now the compiler is able to unambiguously match the function parameter s with the template type S, with the side effect that S will always be deduced - all explicit template parameters after the first will belong to Args.

None of this works for (primary) class templates, parameters aren't deduced and it's expressly forbidden:

From draft n4567

[temp.param] / 11

[...]If a template-parameter of a primary class template or alias template is a template parameter pack, it shall be the last template-parameter.[...]

(if they were deduced it would be ambiguous as in the function template example).

share|improve this answer
Uhm, OK, it seems that the example in the question has been reduced too much, but good point to point out how one can make it works or not. So it's legal syntax and it's all about deduction, no way to define a class like the one in the question, I've to find a reasonable and usable solution... Any idea? It would be appreciated, as mentioned in the question. :-) – skypjack Jan 22 at 7:45
@skypjack I think you'd need to explain what exactly it is you're trying to do first, for instance why Allocator needs to be at the end. – user657267 Jan 22 at 8:10
For it is there in almost all the classes of the library I've working on, but that's the first time I need to have a parameter pack in the class definition. Quite simple indeed, but if I can't find a solution still I can move it in another position, of course. – skypjack Jan 22 at 8:13
@skypjack behold – user657267 Jan 22 at 8:31
@skypjack If the function type is meaningful to the end user, perhaps template<class F, class Alloc> struct meow; template<class Ret, class... Args, class Alloc> struct meow<Ret(Args...), Alloc> { };? – T.C. Jan 22 at 11:30

The first one is not right. The compiler is just buggy and failed to diagnose it. [temp.param]/11:

A template parameter pack of a function template shall not be followed by another template parameter unless that template parameter can be deduced from the parameter-type-list of the function template or has a default argument (14.8.2).

If the function type T(Args...) is meaningful to the end-user, one way to fix this would be to use a partial specialization instead:

template<class F, class Alloc> class C; //undefined
template<class T, class... Args, class Alloc>
class C<T(Args...), Alloc> {
    // implementation

Depending on the actual requirements, type-erasing the allocator might also be worth considering.

share|improve this answer
The compiler is GCC5, should I open a ticket on their bug tracking system if none exists for this problem? – skypjack Jan 22 at 8:16
As kindly suggested by user657267, can I invite you to update your answer and include the example that uses a partial specialization? I think it would be of help for future users and it is really a nice solution. Thank you. – skypjack Jan 23 at 10:02
Thank you, I'd give you another upvote if it was possible. :-) – skypjack Jan 23 at 10:27
What do you mean with type-erasing the allocator? I know the type erasure as an idiom, but I failed to understand to what you are referring. – skypjack Jan 24 at 8:42
@skypjack Basically, what std::function, std::promise and std::packaged_task do. You take an allocator in a constructor and type-erase it, so that your type doesn't depend on the allocator's type. – T.C. Jan 24 at 8:45

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