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struct VectorOfMaps {
            > tuple;

I want to generalize this into a template, so the above class would be produced by something like

VectorOfMaps<3, std::string,double,

Can this, or something similar, be done?

I know I could just put the map types directly into the template, but wouldn't such repetition of "std::map" considered a bit ugly? What do you think?

(I thought about whether I could specify std::pair types in the template, but I was not sure if those could be used directly to create the std::map types) ..

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Yes, with a variadic template. You won't need the numeric argument. – n.m. May 4 '13 at 23:23

4 Answers 4

up vote 3 down vote accepted

Since you mention passing specializations of pairs to the class template:

template<typename... Pairs>
struct VectorOfMaps {
        typename Pairs::first_type
        , typename Pairs::second_type
    >...> tuple;

This is effectively using std::pair as a type-list -- you could use something like template<typename T, typename U> struct pair { using first_type = T; using second_type = U; }; just as well.

It is possible to pass the types without the a pair as well, but this requires some metacomputations. A possible solution:

// First argument is accumulator, supposed to be an empty tuple
template<typename Acc, typename... T> struct compute_tuple
    // Only triggered when the primary template is instantiated, which should
    // only happen if sizeof...(T) is odd -- it's possible to assert on that
    // instead, too.
    static_assert( !sizeof(Acc), "An even number of arguments is required" );

// Recursive case
template<typename... Acc, typename First, typename Second, typename... Rest>
struct compute_tuple<std::tuple<Acc...>, First, Second, Rest...>
: compute_tuple<std::tuple<Acc..., std::map<First, Second>>, Rest...> {};

// Terminal case
template<typename Acc>
struct compute_tuple<Acc> { using type = Acc; };

template<typename... T>
struct VectorOfMaps {
     * You can assert that sizeof...(T) is even here; it might be more
     * helpful than an error deeper inside compute_tuple.
    using tuple_type = typename compute_tuple<std::tuple<>, T...>::type;
    tuple_type tuple;
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How would you static_assert (assert at compile time) that sizeof...(T) is even? Also question: I understand your code after the fact, but I'd never have known where to even begin myself! Here some books on the subject were recommended but these books may be outdated now at C++11. Do you recommended any resources? – 7cows May 5 '13 at 1:08
@7cows sizeof...(T) % 2 == 0 checks for the right parity. ISTR to recall having read Modern C++ Design by Alexandrescu but that was a long time ago. If it helps, behind the bizarre, verbose syntax there is a pure functional programming language of sorts where e.g. partial template specialization plays the role of pattern matching. – Luc Danton May 5 '13 at 1:18

The first_of_pair metafunction is unnecessary as pair has first_type and second_type members. Here is the solution with variadic template argument:

template<class... pairtypes>
struct VectorOfMaps
            typename pairtypes::first_type,
            typename pairtypes::second_type
    > tuple;

int main()
    > v;
    return 0;
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any reason for posting the answer twice? :) – Bill May 4 '13 at 23:58

If you can accept an upper limit on the number of maps to store, you can do it with template specializations for different values of n:

template<int n, class key0, class value0, class key1 = void, class value1 = void>
struct VectorOfMaps;

template<class key0, class value0>
struct VectorOfMaps<1,key0,value0>
// ...

template<class key0, class value0, class key1, class value1>
struct VectorOfMaps<2,key0,value0,key1,value1>
// ...

A nicer approach would be using a variadic template parameter.

From a pair argument you can extract the types with helper metafunctions:

template<class T>
struct first_of_pair;

template<class First, class Second>
struct first_of_pair<std::pair<First,Second>>
   typedef First type;

// usage in a template where T is an std::pair: typename first_of_pair<T>::type
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Editing is usually the preferred way to amend an existing answer. – Luc Danton May 4 '13 at 23:58

I think using std::tuple provides a simpler and cleaner way (but it might be slower...).

template<int pos,typename... Args> struct TypeTransformer_ {
     using ValueType =  typename std::tuple_element<1,std::tuple<Args...>>::type;
     using KeyType =  typename std::tuple_element<0,std::tuple<Args...>>::type ;
     using Type =  decltype(std::tuple_cat(std::tuple<std::map<KeyType,ValueType>>(),
                    typename TypeTransformer_<pos - 2,Args...>::Type()));

//Base case with two elements...
template<typename... Args>
struct TypeTransformer_<2,Args...> {
   using ValueType  = typename std::tuple_element<1,std::tuple<Args...>>::type ;
   using KeyType =  typename std::tuple_element<0,std::tuple<Args...>>::type ;
   using Type =  std::tuple<std::map<KeyType,ValueType>> ;

//Handling the case of an odd number of parms
template<typename... Args> struct TypeTransformer_<1,Args...> ;

//Nicer interface so we don't have to specify the number of variadic param
template <typename... Args> struct SomeStruct{
using  TupleType = typename TypeTransformer_<sizeof...(Args),Args...>::Type;
TupleType tp ;
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