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I want to instantiate a variadic template class Store<TArgs...> that has a std::vector for each type in the TArgs... pack.

template<typename... TArgs> class Store {
    // obviously not valid code
    // assuming each type of TArgs... has a `unsigned int` id that can be
    // retrieved with getId<T>()
    std::array<sizeof...(TArgs), std::vector<TArgs...>> bags;

    template<typename T> void add(T mValue) { 
        bags[getId<T>()].push_back(mValue); 
    }

    template<typename T> std::vector<T>& get() { 
        return bags[getId<T>()]; 
    }
};

Let's say I have a Store<int, float, double>. I obviously know, at compile time, that it will be able to store int, float and double values.

I could use template specializations:

template<> class Store<int, float, double> {
    std::vector<int> vi;
    std::vector<float> vf;
    std::vector<double> vd;

    template<typename T> void add(T);
    template<> void add<int>(int mValue) { vi.push_back(mValue); }
    template<> void add<float>(float mValue) { vf.push_back(mValue); }
    template<> void add<double>(double mValue) { vd.push_back(mValue); }
    // ...
};

...but that would require hand-writing every possible combination of types, and would not work with user-defined types.

I'm confident the compiler knows everything that's required to generate a class like Store<int, float, double> using variadic templates - is there a way to actually express this intent?

share|improve this question
    
You'll need a std::tuple to do this, std::vector isn't suitable. –  πάντα ῥεῖ Oct 19 '13 at 7:52
    
Here >> std::array<sizeof...(TArgs), std::vector<TArgs...>>, the order of template arguments is wrong. It should be std::array<Type, Size>, not std::array<Size, Type>. Also, I think you need std::tuple, not std::vector (I'm not sure though). –  Nawaz Oct 19 '13 at 8:28

2 Answers 2

up vote 6 down vote accepted

The following should do what you want:

#include <type_traits>
#include <vector>
#include <tuple>
#include <iostream>

// indices are a classic
template< std::size_t... Ns >
struct indices
{
    using next = indices< Ns..., sizeof...( Ns ) >;
};

template< std::size_t N >
struct make_indices
{
    using type = typename make_indices< N - 1 >::type::next;
};

template<>
struct make_indices< 0 >
{
    using type = indices<>;
};

// we need something to find a type's index within a list of types
template<typename T, typename U, std::size_t=0>
struct index {};

template<typename T, typename... Us, std::size_t N>
struct index<T,std::tuple<T,Us...>,N>
: std::integral_constant<std::size_t, N> {};

template<typename T, typename U, typename... Us, std::size_t N>
struct index<T,std::tuple<U,Us...>,N>
: index<T,std::tuple<Us...>,N+1> {};

// we need a way to remove duplicate types from a list of types
template<typename T,typename I=void> struct unique;

// step 1: generate indices
template<typename... Ts>
struct unique< std::tuple<Ts...>, void >
: unique< std::tuple<Ts...>, typename make_indices<sizeof...(Ts)>::type >
{
};

// step 2: remove duplicates. Note: No recursion here!
template<typename... Ts, std::size_t... Is>
struct unique< std::tuple<Ts...>, indices<Is...> >
{
    using type = decltype( std::tuple_cat( std::declval<
        typename std::conditional<index<Ts,std::tuple<Ts...>>::value==Is,std::tuple<Ts>,std::tuple<>>::type
>()... ) );
};

// a helper to turn Ts... into std::vector<Ts>...
template<typename> struct vectorize;

template<typename... Ts>
struct vectorize<std::tuple<Ts...>>
{
    using type = std::tuple< std::vector<Ts>... >;
};

// now you can easily use it to define your Store
template<typename... Ts> class Store
{
    using Storage = typename vectorize<typename unique<std::tuple<Ts...>>::type>::type;
    Storage storage;

    template<typename T>
    decltype(std::get<index<T,typename unique<std::tuple<Ts...>>::type>::value>(storage))
    slot()
    {
        return std::get<index<T,typename unique<std::tuple<Ts...>>::type>::value>(storage);
    }

public:
    template<typename T> void add(T mValue) { 
        slot<T>().push_back(mValue); 
    }

    template<typename T> std::vector<T>& get() { 
        return slot<T>();
    }    
};

int main()
{
    Store<int,int,double,int,double> store;
    store.add(42);
    store.add(3.1415);
    store.add(21);
    std::cout << store.get<int>().size() << std::endl; 
    std::cout << store.get<double>().size() << std::endl; 
}

Live example (without the comments)

share|improve this answer
    
@VittorioRomeo Rereading your question, the above probably does more than you asked for: It handles duplicate types by providing only one vector, hence Store<int,double> behaves the same as Store<int,int,double,int,double>. But all the cases you asked for are also automatically covered :) –  Daniel Frey Oct 19 '13 at 8:49
    
Thank you very much. Clever and effective solution! –  Vittorio Romeo Oct 19 '13 at 9:19

In the next version of the C++ standard, the elements of std::tuple are accessible by type provided there are not several elements of the type. Therefore, you should soon be able to write it this way:

template<typename... TArgs>
struct Store {

    std::tuple<std::vector<TArgs>...> bags;

    template<typename T>
    void add(T mValue) { 
        get<T>().push_back(mValue); 
    }

    template<typename T>
    std::vector<T>& get() { 
        return std::get<std::vector<T>>(bags); 
    }
};
share|improve this answer
    
Looks great, can't wait for C++14 :) –  Vittorio Romeo Oct 19 '13 at 9:18

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