# How to make a function that zips two tuples in C++11 (STL)?

I recently ran across this puzzle, was finally able to struggle out a hacky answer (using index arrays), and wanted to share it (answer below). I am sure there are answers that use template recursion and answers that use `boost`; if you're interested, please share other ways to do this. I think having these all in one place may benefit others and be useful for learning some of the cool C++11 template metaprogramming tricks.

Problem: Given two tuples of equal length:

``````auto tup1 = std::make_tuple(1, 'b', -10);
auto tup2 = std::make_tuple(2.5, 2, std::string("even strings?!"));
``````

How do you create a function that will "zip" the two tuples into a heterogeneous tuple of pairs?

``````std::tuple<
std::pair<int, double>,
std::pair<char, int>,
std::pair<int, std::string> > result =
tuple_zip( tup1, tup2 );
``````

Where

``````std::get<0>(result) == std::make_pair(1, 2.5);
std::get<1>(result) == std::make_pair('b', 2);
std::get<2>(result) == std::make_pair(-10, std::string("even strings?!"));
``````
-
And now for the bonus: 1/ Can you make it work even for tuples of unequal lengths (padding with `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 6:25
What do you mean with zip two tuples? Can you post expected result? –  BЈовић Jul 4 '12 at 8:59
@BЈовић I've added the desired output of the final `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
@MatthieuM. Voila! Edit below has padding for tuples of different sizes. :) –  Oliver Jul 4 '12 at 10:32

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:

``````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) ) {
}

template <template <typename ...> class Tup1, template <typename ...> class Tup2, typename ...A, typename ...B>
auto diff_size_tuple_zip(Tup1<A...> t1, Tup2<B...> t2) ->
}
``````

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;
}
``````
-
Nice overall solution. I'll only have a couple of remarks. 1/ I would use `unsigned` as indexes (at the very least), because you don't expect negatives indexes, do you ? 2/ A `static_assert` instead of the `assert` would be welcome. 3/ The pair should probably be taken by `const&` in the `operator<<` overload. –  Matthieu M. Jul 4 '12 at 6:23
+1 All good ideas. Will update. –  Oliver Jul 4 '12 at 6:33
Generalizing `tuple_zip` to operate on an arbitrary number of tuples left as an exercise to the reader ? :) –  Luc Danton Jul 4 '12 at 7:54
@LucDanton ...as a quine. :) –  Oliver Jul 4 '12 at 10:31
For the unequal ones, I think I'd use `decltype(std::ignore)` instead of `std::nullptr_t`, because I think it plays nicer: it allows distinction from an actual tuple with `std::nullptr_t`, and still works ok with tuples of references. Also, it's a pity that the standard tuple_cat is not required to work with arrays (even when `std::get` overloads exist for them) forcing extra copies :( I had to resort to implementing my own tuple_cat. –  R. Martinho Fernandes Jul 4 '12 at 10:52