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I would like to create a function that takes a variable number of template arguments. Later with these arguments the function should pass their position like this:

template<typename R, typename Args...>
R myFunction(Data &data, void *function) {
    auto f = (R (*)(Args...))function;
    return f(read<Args1>(data, 1), read<Args2>(data, 2), ...);// <-- This is the problem

The given code is of course not compilable. Is there any way to fix it? Is there a way to do it without variadic templates without too much code duplication?

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I'm sure you can avoid the object-pointer to function-pointer cast. –  sellibitze Mar 4 '13 at 15:18
@sellibitze: Is that a problem? Because I can only have a void* pointer user data that are passed from a C function. –  Juraj Blaho Mar 4 '13 at 15:40
The data can be a void *. It's the function being a void * that is a concern. –  Vaughn Cato Mar 4 '13 at 15:41
@JurajBlaho: This kind of cast ist highly non-portable. I suggest you explain what problem you intend to solve like that. Chances are that you'll receive more useful answers if you do. It seems to me, we have a bit of an X/Y problem. –  sellibitze Mar 4 '13 at 15:52
@sellibitze: Thanks for the comment, now I see that casting function pointer to void* is UB. I will have to solve it a bit differently, but I am still able to solve the problem using ideas from the accepted answer. –  Juraj Blaho Mar 4 '13 at 21:08

1 Answer 1

up vote 12 down vote accepted

Yes, that is possible:

// we need a compile-time helper to generate indices
template< std::size_t... Ns >
struct indices
  typedef indices< Ns..., sizeof...( Ns ) > next;

template< std::size_t N >
struct make_indices
  typedef typename make_indices< N - 1 >::type::next type;

struct make_indices< 0 >
  typedef indices<> type;

With these helpers, you need one forwarder for your function like this:

template<typename R, typename... Args, std::size_t... Ns>
R myFunctionImpl(void *Data, void *function, indices<Ns...> ) {
    auto f = (R (*)(Args...))function;
    return f(read<Args>(Data, Ns + 1)...);// +1 because indices is zero-based

template<typename R, typename... Args>
R myFunction(void *Data, void *function) {
   return myFunctionImpl< R, Args... >( Data, function, typename make_indices<sizeof...(Args)>::type() );

EDIT: How does it work? First, we determine the size of the argument pack Args through sizeof.... make_indices<N>::type then expands into indices<0,1,2,...,N-1>. It is given as an additional parameter to the implementation function (from the forwarder who just creates a dummy instance), hence argument deduction kicks in on the implementation function's side and puts the generated indices into the argument pack Ns.

The implementation function now has two argument packs with the same size, namely Args and Ns. When expanded through the ellipsis ..., the ellipsis expands the whole expression that it's applied to and it expands all parameter packs in parallel! In the above example that expression is read<Args>(Data, Ns+1), which nicely expands into the OPs pseudo-code.

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can you post a simple example? –  BЈовић Mar 4 '13 at 15:16
I just did. What is missing from the example I gave? –  Daniel Frey Mar 4 '13 at 15:17
What is missing is a real example. With main() and some functions (with 1,2,3 parameters). How do you use these functions and structures? –  BЈовић Mar 4 '13 at 21:09
It took me some time to fully understand the code and it seems that it should work. –  Juraj Blaho Mar 4 '13 at 21:13
I still don't get it. How this: typename make_indices<sizeof...(Args)>::type() compiles? Should be a compilation error. –  BЈовић Mar 5 '13 at 7:03

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