I don't think there is any direct way of doing what you want, but here is a C++11 technique that I use in several places of my code. The basic idea is to use a template function which I've called `call_on_tuple`

to take a function argument `f`

as well as a tuple of further arguments, expand the tuple and call the function on the expanded list of arguments:

```
template <typename Fun, typename... Args, unsigned... Is>
typename std::result_of<Fun(Args...)>::type
call_on_tuple(Fun&& f, std::tuple<Args...>&& tup, indices<Is...>)
{ return f(std::get<Is>(tup)...); }
```

So the idea is that instead of calling

```
length(arguments());
```

you would call

```
call_on_tuple(length,arguments());
```

This assumes that `arguments()`

is changed so it returns a `std::tuple<int,int,int>`

(this is basically the idea from the question you cited).

Now the difficult part is how to get the `Is...`

argument pack, which is a pack of integers `0,1,2,...`

used to number the elements of the tuple.

If you are sure you'll always have three arguments, you could use `0,1,2`

literally, but if the ambition is to make this work for any n-ary function, we need another trick, which has been described by other posts, for example in several answers to this post.

It's a trick to transform the number of arguments, i.e. `sizeof...(Args)`

into a *list* of integers `0,1,...,sizeof...(Args)`

:

I'll put this trick and the implementation of `call_on_tuple`

in a namespace `detail`

:

```
namespace detail {
template <unsigned... Is>
struct indices
{ };
template <unsigned N, unsigned... Is>
struct index_maker : index_maker<N-1,N-1,Is...>
{ };
template <unsigned... Is>
struct index_maker<0,Is...>
{ typedef indices<Is...> type; };
template <typename Fun, typename... Args, unsigned... Is>
typename std::enable_if<!std::is_void<typename std::result_of<Fun(Args...)>::type>::value,
typename std::result_of<Fun(Args...)>::type>::type
call_on_tuple(Fun&& f, std::tuple<Args...>&& tup, indices<Is...>)
{ return f(std::get<Is>(tup)...); }
}
```

Now the actual function `call_on_tuple`

is defined in global namespace like this:

```
template <typename Fun, typename... Args>
typename std::enable_if<!std::is_void<typename std::result_of<Fun(Args...)>::type>::value,
typename std::result_of<Fun(Args...)>::type>::type
call_on_tuple(Fun&& f, std::tuple<Args...>&& tup)
{
using std::tuple;
using std::forward;
using detail::index_maker;
return detail::call_on_tuple
(forward<Fun>(f),forward<tuple<Args...>>(tup),typename index_maker<sizeof...(Args)>::type());
}
```

It basically calls `detail::index_maker`

to generate the list of increasing integers and then calls `detail::call_on_tuple`

with that.

As a result, you can do this:

```
int length(int x, int y, int z)
{ return x + y + z; }
std::tuple<int,int,int> arguments()
{ return std::tuple<int,int,int> { 1 , 2 , 3 }; }
int main()
{
std::cout << call_on_tuple(length,arguments()) << std::endl;
return 0;
}
```

which is hopefully close enough to what you needed.

*Note.* I have also added an `enable_if`

to ensure this is only used with functions `f`

that actually return a value. You can readily make another implementation for functions that return `void`

.

Sorry again for closing your question prematurely.

PS. You'll need to add the following include statements to test this:

```
#include <tuple>
#include <type_traits>
#include <iostream>
```