**First, a quick overview of index arrays:**

```
template<std::size_t ...S>
struct seq { };
// And now an example of how index arrays are used to print a tuple:
template <typename ...T, std::size_t ...S>
void print_helper(std::tuple<T...> tup, seq<S...> s) {
// this trick is exceptionally useful:
// ((std::cout << std::get<S>(tup) << " "), 0) executes the cout
// and returns 0.
// { 0... } expands (because the expression has an S in it),
// returning an array of length sizeof...(S) full of zeros.
// The array isn't used, but it's a great hack to do one operation
// for each std::size_t in S.
int garbage[] = { ((std::cout << std::get<S>(tup) << " "), 0)... };
std::cout << std::endl;
}
```

And now to use our print_helper function:

```
int main() {
print_helper(std::make_tuple(10, 0.66, 'h'), seq<0,1,2>() );
return 0;
}
```

Typing `seq<0,1,2>`

can be a bit of a pain, though. So we can use template recursion to create a class to generate `seq`

s, so that `gens<3>::type`

is the same as `seq<0,1,2>`

:

```
template<std::size_t N, std::size_t ...S>
struct gens : gens<N-1, N-1, S...> { };
template<std::size_t ...S>
struct gens<0, S...> {
typedef seq<S...> type;
};
int main() {
print_helper(std::make_tuple(10, 0.66, 'h'), gens<3>::type() );
return 0;
}
```

Since the `N`

in `gens<N>::type`

will always be the number of elements in the tuple, you can wrap `print_helper`

to make it easier:

```
template <typename ...T>
void print(std::tuple<T...> tup) {
print_helper(tup, typename gens<sizeof...(T)>::type() );
}
int main() {
print(std::make_tuple(10, 0.66, 'h'));
return 0;
}
```

Note that the template arguments can be deduced automatically (typing all of that out would be a pain wouldn't it?).

**Now, the **`tuple_zip`

function:

As before, start with the helper function:

```
template <template <typename ...> class Tup1,
template <typename ...> class Tup2,
typename ...A, typename ...B,
std::size_t ...S>
auto tuple_zip_helper(Tup1<A...> t1, Tup2<B...> t2, seq<S...> s) ->
decltype(std::make_tuple(std::make_pair(std::get<S>(t1),std::get<S>(t2))...)) {
return std::make_tuple( std::make_pair( std::get<S>(t1), std::get<S>(t2) )...);
}
```

The code is a little tricky, particularly the trailing return type (the return type is declared as `auto`

and provided with `->`

after the parameters are defined). This lets us avoid the problem of even *defining* what the return type will be, by simply declaring it returns the expression used in the function body (if `x`

and `y`

are `int`

s, `delctype(x+y)`

is resolved at compile time as `int`

).

Now wrap it in a function that provides the appropriate `seq<0, 1...N>`

using `gens<N>::type`

:

```
template <template <typename ...> class Tup1,
template <typename ...> class Tup2,
typename ...A, typename ...B>
auto tuple_zip(Tup1<A...> t1, Tup2<B...> t2) ->
decltype(tuple_zip_helper(t1, t2, typename gens<sizeof...(A)>::type() )) {
static_assert(sizeof...(A) == sizeof...(B), "The tuple sizes must be the same");
return tuple_zip_helper( t1, t2, typename gens<sizeof...(A)>::type() );
}
```

Now you can use it as specified in the question:

```
int main() {
auto tup1 = std::make_tuple(1, 'b', -10);
auto tup2 = std::make_tuple(2.5, 2, std::string("even strings?!"));
std::tuple<
std::pair<int, double>,
std::pair<char, int>,
std::pair<int, std::string> > x = tuple_zip( tup1, tup2 );
// this is also equivalent:
// auto x = tuple_zip( tup1, tup2 );
return 0;
}
```

And finally, if you provide a `<<`

operator for `std::pair`

you can use the print function we defined above to print the zipped result:

```
template <typename A, typename B>
std::ostream & operator << (std::ostream & os, const std::pair<A, B> & pair) {
os << "pair("<< pair.first << "," << pair.second << ")";
return os;
}
int main() {
auto tup1 = std::make_tuple(1, 'b', -10);
auto tup2 = std::make_tuple(2.5, 2, std::string("even strings?!"));
auto x = tuple_zip( tup1, tup2 );
std::cout << "zipping: ";
print(tup1);
std::cout << "with : ";
print(tup2);
std::cout << "yields : ";
print(x);
return 0;
}
```

The output is:

zipping: 1 b 10

with : 2.5 2 even strings?!

yields : pair(1,2.5) pair(b,2) pair(10,even strings?!)

Like `std::array`

, `std::tuple`

is defined at compile time, and so it can be used to generate more optimizable code (more information is known at compile time compared to containers like `std::vector`

and `std::list`

). So even though it's sometimes a bit of work, you can sometimes use it to make fast and clever code. Happy hacking!

**Edit:**

As requested, allowing tuples of different sizes and padding with null pointers:

```
template <typename T, std::size_t N, std::size_t ...S>
auto array_to_tuple_helper(const std::array<T, N> & arr, seq<S...> s) -> decltype(std::make_tuple(arr[S]...)) {
return std::make_tuple(arr[S]...);
}
template <typename T, std::size_t N>
auto array_to_tuple(const std::array<T, N> & arr) -> decltype( array_to_tuple_helper(arr, typename gens<N>::type()) ) {
return array_to_tuple_helper(arr, typename gens<N>::type());
}
template <std::size_t N, template <typename ...> class Tup, typename ...A>
auto pad(Tup<A...> tup) -> decltype(tuple_cat(tup, array_to_tuple(std::array<std::nullptr_t, N>()) )) {
return tuple_cat(tup, array_to_tuple(std::array<std::nullptr_t, N>()) );
}
#define EXTENSION_TO_FIRST(first,second) ((first)>(second) ? (first)-(second) : 0)
template <template <typename ...> class Tup1, template <typename ...> class Tup2, typename ...A, typename ...B>
auto pad_first(Tup1<A...> t1, Tup2<B...> t2) -> decltype( pad<EXTENSION_TO_FIRST(sizeof...(B), sizeof...(A)), Tup1, A...>(t1) ) {
return pad<EXTENSION_TO_FIRST(sizeof...(B), sizeof...(A)), Tup1, A...>(t1);
}
template <template <typename ...> class Tup1, template <typename ...> class Tup2, typename ...A, typename ...B>
auto diff_size_tuple_zip(Tup1<A...> t1, Tup2<B...> t2) ->
decltype( tuple_zip( pad_first(t1, t2), pad_first(t2, t1) ) ) {
return tuple_zip( pad_first(t1, t2), pad_first(t2, t1) );
}
```

And BTW, you're going to need this now to use our handy `print`

function:

```
std::ostream & operator << (std::ostream & os, std::nullptr_t) {
os << "null_ptr";
return os;
}
```

`nullptr_t`

for example) ? and more involved 2/ Can you make it work with an arbitrary number of tuples ? – Matthieu M. Jul 4 '12 at 6:25zip two tuples? Can you post expected result? – BЈовић Jul 4 '12 at 8:59`main`

routine to the answer below. By zip, I mean take the two tuples above (`tup1`

and`tup2`

) and create a tuple of 3 elements in this case, where the first is`make_pair(1, 2.5)`

, etc. – Oliver Jul 4 '12 at 9:11