I’ve never yet used the C++0x variadic templates feature but the following code compiles on G++ 4.5:

```
template <typename... Args>
struct tuple;
template <typename T, typename... Args>
struct tuple<T, Args...> {
T value;
tuple<Args...> inner;
};
template <typename T>
struct tuple<T> {
T value;
};
```

However, initializing them is … weird because we need to *nest* the inner values:

```
int main() {
tuple<int> n1 = { 23 };
tuple<int, float> n2 = { 42, { 0.5f } };
tuple<std::string, double, int> n3 = { "hello, world", { 3.14, { 97 } } };
}
```

Retrieving the values is of course a bit tedious. The simplest method is probably to provide a `get<N>()`

function template.

But we cannot implement `get`

directly since function templates cannot be partially specialized. Either we need to use SFINAE (read: `boost::enable_if`

) or we need to delegate the actual function of `get`

to a type that can be partially specialized.

In the following, I did the latter. But first, we need another helper type trait: `nth_type`

, which returns the appropriate return type of the `get`

function:

```
template <unsigned N, typename... Args>
struct nth_type;
template <unsigned N, typename T, typename... Args>
struct nth_type<N, T, Args...> : nth_type<N - 1, Args...> { };
template <typename T, typename... Args>
struct nth_type<0, T, Args...> {
typedef T type;
};
```

Easy-peasy. Just returns the *n*th type in a list of types.

Now we can write our `get`

function:

```
template <unsigned N, typename... Args>
inline typename nth_type<N, Args...>::type get(tuple<Args...>& tup) {
return get_t<N, Args...>::value(tup);
}
```

Like I said, this just delegates the task. No biggie. In practice, we probably want to have another overload for `const`

tuples (but then, in practice we would use an existing `tuple`

type).

Now for the killing, followed by a light salad:

```
template <unsigned N, typename... Args>
struct get_t;
template <unsigned N, typename T, typename... Args>
struct get_t<N, T, Args...> {
static typename nth_type<N, T, Args...>::type value(tuple<T, Args...>& tup) {
return get_t<N - 1, Args...>::value(tup.inner);
}
};
template <typename T, typename... Args>
struct get_t<0, T, Args...> {
static T value(tuple<T, Args...>& tup) {
return tup.value;
}
};
```

And that’s it. We can test this by printing some values in our previously defined variables:

```
std::cout << get<0>(n1) << std::endl; // 23
std::cout << get<0>(n2) << std::endl; // 42
std::cout << get<0>(n3) << std::endl; // hello, world
std::cout << get<1>(n2) << std::endl; // 0.5
std::cout << get<1>(n3) << std::endl; // 3.14
std::cout << get<2>(n3) << std::endl; // 97
```

Man, it’s *fun* messing with variadic templates.