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I would like to allow use of the class I'm writing to specify as a template parameters a list of types along with a list of allocators of those types in a manner that types are at odd positions and allocators are at even ones:

template<typename... T>
class MyClass {
  // Stuff inside
}

int main() {
  MyClass<SomeType1, AllocatorOfSomeType1> c1;
  MyClass<SomeType1, AllocatorOfSomeType1, 
          SomeType2, AllocatorOfSomeType2> c2;
  MyClass<SomeType1, AllocatorOfSomeType1, 
          SomeType2, AllocatorOfSomeType2,
          SomeType3, AllocatorOfSomeType3> c3;
  // And so on....
}

Internally it would make sense to have a tuple of vectors of types for storage:

std::tuple<std::vector<EveryOddTypeInParameterPack>...> m_storage_;

and a tuple of allocators for usage:

std::tuple<std::vector<EveryEvenTypeInParameterPack>...> m_storage_;

How can I actually declare those tuples in code? In theory I need to somehow select every odd/even type in parameter pack - is that possible?

share|improve this question
    
Why? Why? Why? Why? –  Cheers and hth. - Alf Jun 25 '11 at 3:10
1  
@Alf Could you elaborate a bit more on the whole "why" thing? If you are asking why I want this interface - because I need to provide users of this class with a convenient way to specify allocators. I'm open to (reasonable) alternatives tho. –  Bartłomiej Siwek Jun 25 '11 at 3:16
4  
You could just use the allocators as your template arglist, and use allocator::value_type for the types... –  Chris Dodd Jun 25 '11 at 3:40
    
I'm tempted to try something like the old isEven(n) { return isOdd(n-1); } routine... Maybe see this answer for packing arguments in a tuple for transport. –  Kerrek SB Jun 25 '11 at 11:05
    
@Kerrek: To use that you also need an isOdd(n) { return isEven(n - 1); }, right? :-) –  James McNellis Jun 26 '11 at 7:09

3 Answers 3

up vote 1 down vote accepted

Though the code got a little lengthy, I suppose the mechanism doesn't have unnecessary peculiarities.
If I understand the question correctly, probably the following code will meet the purpose:

// push front for tuple
template< class, class > struct PFT;

template< class A, class... T > struct PFT< A, tuple< T... > > {
  typedef tuple< A, T... > type;
};

// for even
template< class... > struct even_tuple;

template< class A, class B > struct even_tuple< A, B > {
  typedef tuple< A > type;
};
template< class A, class B, class... T > struct even_tuple< A, B, T... > {
  typedef typename PFT< A, typename even_tuple< T... >::type >::type type;
};
// As for odd elements, in the same way as even(please see the test on ideone)

// objective type
template< class > struct storage_type;

template< class... T > struct storage_type< tuple< T... > > {
  typedef tuple< vector< T >... > type;
};

template< class... T >
struct MyClass {
  typename storage_type< typename even_tuple< T... >::type >::type
    m_storage_even_;
  typename storage_type< typename  odd_tuple< T... >::type >::type
    m_storage_odd_;
};

Here is a test on ideone.

share|improve this answer
    
Works great. Thanks :) –  Bartłomiej Siwek Jun 27 '11 at 15:03
    
Oh not at all. Glad it helped :-) –  Ise Wisteria Jun 27 '11 at 18:01

Perhaps something like this:

#include <tuple>

// Example receptacle    
template <typename ...Args> struct MyContainer;

// Tuple concatenator
template<typename PackR, typename PackL> struct cat;
template<typename ...R, typename ...L>
struct cat<std::tuple<R...>, std::tuple<L...>>
{
  typedef std::tuple<R..., L...> type;
};

// Even/Odd extractors
template <typename ...Args> struct GetEven;
template <typename ...Args> struct GetOdd;

template <typename E1, typename O1, typename ...Args>
struct GetEven<E1, O1, Args...>
{
  typedef typename cat<std::tuple<E1>, typename GetEven<Args...>::value>::type value;
};
template <typename E1, typename O1>
struct GetEven<E1, O1>
{
  typedef std::tuple<E1> value;
};

template <typename E1, typename O1, typename ...Args>
struct GetOdd<E1, O1, Args...>
{
  typedef typename cat<std::tuple<O1>, typename GetEven<Args...>::value>::type value;
};
template <typename E1, typename O1>
struct GetOdd<E1, O1>
{
  typedef std::tuple<O1> value;
};

// Tuple-to-Receptacle mover
template <typename Pack, template <typename ...T> class Receiver> struct Unpack;
template <typename ...Args, template <typename ...T> class Receiver>
struct Unpack<std::tuple<Args...>, Receiver>
{
  typedef Receiver<Args...> type;
};

// Example consumer
template <typename ...Args>
struct Foo
{
  typedef typename Unpack<typename GetEven<Args...>::value, MyContainer>::type EvenVector;
  typedef typename Unpack<typename GetOdd<Args...>::value, MyContainer>::type OddVector;

  EvenVector x;
  OddVector y;
};

You still have to define your MyContainer class to do something useful with the variadic parameters, e.g. implement your tuple of vectors... (why not a vector of tuples, though?)

Credits to brunocodutra for the tuple trick.

share|improve this answer
    
This "almost" works. The problem with this approach is that General cases of GetEven and GetOdd declare a tuple of a type and a tuple. This can be eaisly fixed by using cat from the question you linked to. I will accept this answer as soon as its fixed. P.S. I can actually paste my fixed code here but it is you who should get the credit for answering. –  Bartłomiej Siwek Jun 26 '11 at 0:50
    
@Bartłomiej: Could you explain what you need concatenated? I thought you wanted to separate out the evens and the odds? I don't mind who you accept, but I'd be happy to amend the answer to your needs. –  Kerrek SB Jun 26 '11 at 19:14
    
What I mean is that the code in its current state does not work as expected. If you declare Foo<C1, C2, C3, C4, C5, C6> say then GetEven<Args...>::value will resolve to std::tuple<C2, std::tuple<C4, std::tuple<C6>>>. What you want/need is std::tuple<C2, C4, C6> and this is where you need the Cat template from the other answer. –  Bartłomiej Siwek Jun 27 '11 at 15:00
    
@Bartłomiej: Oh yes, indeed. Cheers. You got the answer already, though, so I'll just keep that in mind for next time. –  Kerrek SB Jun 27 '11 at 15:21

this is just a try

template<typename... T> class Myclass;

template<typename T1, typename allocT1>
class MyClass <T1, allocT1> {
  std::pair<T1, allocT1> myFirstArglist;
//and you have to do a check that allocT1::value_type is same as T1 or not
//or may be alloT1 is an allocator type or not(i'm thinking concepts, may be)
//this idea is inspired from Chris's comment
};

template<typename T1, typename allocT1, typename... T>
class Myclass<T1, allocT1, T...> {
std::pair<T1, allocT1> myFirstArglist;
Myclass<T>; //something like this
};

template<>
class Myclass<> {
//probably you would like some error message here
//when there are no types and containers
};

may be i'm not clear enough, you'd probably like to read http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2006/n2080.pdf

Also there is a good post related to design of allocator types... you would like to have a look at: C++ Design Pattern for allocator type arguments

share|improve this answer
1  
Specialization syntax needs to be: MyClass<T1, allocT1> and MyClass<T1, allocT1, T...>, and don't forget to stick the base template declaration somewhere. –  Luc Danton Jun 25 '11 at 10:14
    
@Luc thanks for the correction. i have updated now –  A. K. Jun 25 '11 at 18:39

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