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Let's say that I have a parameter pack I'm unrolling, e.g.

template<typename... P> void f(P...&& args) {
    some_other_func(std::forward<P>(args)...);
}

Now let's say that I have some other minor function that these objects need to go through.

template<typename T> T&& some_func(T&& ref) {
    // replace with actual logic
    return std::forward<T>(ref);
}

I would normally just replace with

template<typename... P> void f(P...&& args) {
    some_other_func(some_func(args)...);
}

But what do I do if some_func requires more information about the parameter than just it's type, like for example, it's position numerically in the parameter pack? So that instead of expanding to

some_other_func(some_func(arg1), some_func(arg2));

I could mke it expand to

some_other_func(some_func(arg1, 1), some_func(arg2, 2));

for example?

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2 Answers 2

up vote 2 down vote accepted

I know I've solved this before but can't recall how. Oh well, here's a fresh look.

The sequence of numbers can be translated into the argument sequence using std::get, so it is more fundamental. So, assuming that I need to implement some kind of custom tool, a number pack generator seems like a good choice.

(Gah, this was incredibly tedious. I did peek at Howard's answer and learned about forward_as_tuple, but that function doesn't even exist yet on my compiler or ideone.com, so blah. There are a lot of things I still need to get straight, and this is certainly one of the worst functional languages ever invented.)

http://ideone.com/u5noV

#include <tuple>

// Generic pack array (metacontainer)
template< typename T, T ... seq > struct value_sequence {
    // Append a value to the array (metafunction)
    template< T val > struct append
        { typedef value_sequence< T, seq..., val > type; };
};

// Generate a sequential array (metafunction)
template< size_t N >
struct index_sequence {
    typedef typename index_sequence< N - 1 >::type
                      ::template append< N - 1 >::type type;
};

template<>
struct index_sequence< 0 >
    { typedef value_sequence< size_t > type; };

// Generate indexes up to size of given tuple (metafunction)
template< typename T >
struct index_tuple {
    typedef typename index_sequence< std::tuple_size< T >::value
                                   >::type type;
};

// The magic function: passes indexes, makes all the function calls
template< typename F, typename G,
          typename T, size_t ... N >
void compose_with_indexes_helper( F f, G g, T args,
        value_sequence< size_t, N ... > ) {
    f( g( std::get< N >( args ), N ) ... );
}

template< typename F, typename G, typename ... T >
void compose_with_indexes( F f, G g, T && ... args ) {
    typedef std::tuple< T && ... > tuple_t;
    compose_with_indexes_helper
//        forwarding seems broken on ideone.com/GCC 4.5.1, work around.
//        ( f, g, std::forward_as_tuple( std::forward( args ) ... ) );
        ( f, g, tuple_t( args ... ), typename index_tuple< tuple_t >::type() );
}
share|improve this answer
    
Thanks for this one. Certainly not going to use libstdc++ private internals. –  Puppy Apr 26 '11 at 11:18
    
The only thing I can think of that is more tedious than C++ with tuple and variadic templates is C++ without tuple and variadic templates. ;-) I strongly suspect that over time we (the C++ community) will defacto-standardize on helpful utilities similar to those you show above, or to what I took advantage of in libc++. And then hopefully things won't be so tedious. –  Howard Hinnant Apr 26 '11 at 13:07
    
@Howard: tuple I like, it's the parameter pack interface that seems to resist encapsulation. –  Potatoswatter Apr 26 '11 at 13:19

It is a little convoluted. But here is a working prototype of your code using several private utilities of libc++, found in <__tuple>, and <tuple>.

#include <iostream>
#include <tuple>

template<typename T>
int
some_func(T&& ref, size_t I)
{
    std::cout << "ref = " << ref << ", I = " << I << '\n';
    return 0;
}

template<typename... T, size_t ...Indx>
void
some_other_func(std::tuple<T...> ref, std::__tuple_indices<Indx...>) {
    // replace with actual logic
    std::__swallow(some_func(std::get<Indx>(ref), Indx)...);
}


template<typename... P>
void
f(P&&... args)
{
    some_other_func(std::forward_as_tuple<P...>(std::forward<P>(args)...),
                    typename std::__make_tuple_indices<sizeof...(P)>::type());
}

int main()
{
    f("zero", "one", "two", "three");
}

ref = zero, I = 0
ref = one, I = 1
ref = two, I = 2
ref = three, I = 3
share|improve this answer
2  
Word of advice, don’t google for std::__swallow. –  Konrad Rudolph Apr 26 '11 at 11:18
    
Big laugh, not even going to try! :-) –  Howard Hinnant Apr 26 '11 at 12:57

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