It's probably simplest to use an existing tuple pack generator:

```
// Idiomatic tuple pack generator using successor method
template<int... I> struct tuple_pack {
using succ = tuple_pack<I..., sizeof...(I)>;
};
template<int N> struct make_tuple_pack {
using type = typename make_tuple_pack<N - 1>::type::succ;
};
template<> struct make_tuple_pack<0> {
using type = tuple_pack<>;
};
```

Now we can apply the tuple pack generator, delegating to an implementation function:

```
template<int N, int M, typename T> struct foo_impl {};
template<int N, int M, int... I> struct foo_impl<N, M, tuple_pack<I...>> {
static void foo() {
int arr[M] = { myFunction<N, M - I>()... };
}
};
template<int N, int M> void foo() {
foo_impl<N, M, typename make_tuple_pack<M>::type>::foo();
}
```

If you prefer function parameter inference to class template specialisation this could also be written as:

```
template<int N, int M, int... I> void foo_impl(tuple_pack<I...>) {
int arr[M] = { myFunction<N, M - I>()... };
}
template<int N, int M> void foo() {
foo_impl<N, M>(typename make_tuple_pack<M>::type{});
}
```

I had to specify the array size as `int arr[M]`

; not sure whether that's required by the standard for pack expansion initializers or whether it's a bug in gcc; either way it's no big hassle.

`myFunction<N, 3>`

means nothing without parenthesis.A more elaborated example with use case would be helpful – Mr.Anubis Sep 5 '12 at 20:58