The fundamental ingredient to expanding the `std::tuple<T...>`

is actually omitted from the code: you need to obtain a a second parameter back: in addition to the list of types of the `std::tuple<...>`

you need a parameter pack with indices `0, 1, ..., n`

. Once you have these two parameters packs, you can expand them in tandem:

```
template <typename F, typename... T, int... N>
void call_impl(F&& fun, std::tuple<T...>&& t) {
fun(std::get<N>(t)...);
}
```

The real magic lies in conjuring up the second parameter pack when you just have a `std::tuple<T...>`

. It takes a bit of template programming. Here is an approach to create the list of indices:

```
template <int... Indices> struct indices;
template <> struct indices<-1> { typedef indices<> type; };
template <int... Indices>
struct indices<0, Indices...>
{
typedef indices<0, Indices...> type;
};
template <int Index, int... Indices>
struct indices<Index, Indices...>
{
typedef typename indices<Index - 1, Index, Indices...>::type type;
};
template <typename T>
typename indices<std::tuple_size<T>::value - 1>::type const*
make_indices()
{
return 0;
}
```

So, if you have a function template, let's call it `call()`

which takes a function object and a `std::tuple<T...>`

with the arguments to the function. An easy approach is to rewrite the `call_impl()`

mentioned above to deal with deducing the indices:

```
template <typename F, typename Tuple, int... N>
void call_impl(F&& fun, Tuple&& t, indices<Indices...> const*)
{
fun(std::get<N>(t)...);
}
template <typename F, typename Tuple>
void call(F&& fun, Tuple&& t)
{
call_imle(std::forward<F>(fun), std::forward<Tuple>(t), make_indices<Tuple>());
}
```

What this code doesn't really extend is the correct use of `std::forward<...>()`

with the various `std::tuple<...>`

elements when calling the function. Just using `std::forward<Tuple>(t)`

does **not** work because it possibly moves the entire `std::tuple<...>`

rather than moving the elements. I **think** something like a suitable element-wise move of a `std::tuple<...>`

can be done but I haven't done it, yet.

`get<0>(t), get<1>(t), get<2>(t), ..., get<N>(t)`

– Xeo Sep 24 '13 at 21:23: Never ever useBIG FAT WARNING`std::forward`

or`std::move`

within argument pack expansion - a value (here the tuple`t`

) is only allowed to be movedonce. It might work here because`std::get<N>`

does not actually move, but the above is in itself ananti-patternone should be able to spot and then fix! – Daniel Frey Sep 24 '13 at 21:29`std::forward`

here is perfectly fine, since it extracts only the tuple-elements and thus only moves them. If you know what you're doing, I don't see the problem and I don't think it's an anti-pattern quite like you make it out to be. – Xeo Sep 24 '13 at 21:34`get(tuple<Types...>&& t)`

as equivalent to`return std::forward<typename tuple_element<I, tuple<Types...> >::type&&>(get<I>(t));`

. So the tuple isn'tactuallymoved, only the contained element forwarded. (`forward`

itself is specified as a`static_cast`

) – dyp Sep 24 '13 at 21:59" :) – sehe Sep 24 '13 at 22:21`std::move`

doesn't move and`std::forward<>`

doesn't forward