There is an excellent C++ solution (actually 2 solutions: a recursive and a non-recursive), to a Cartesian Product of a vector of integer vectors. For purposes of illustration/simplicity, let us just focus on the non-recursive version.

My question is, how can one generalize this code with templates to take a std::tuple of homogeneous vectors that looks like this:


and generate a homogeneous vector of tuple


If it makes life any easier, let us assume that the internal vectors in the input are each homogeneous. So inputs like this are not allowed: {{5,"baz"}{'c',-2}}

EDIT changed input from jagged vector to a tuple

  • 2
    This should be doable. Create an index<size> type of size_t (basically an n-tuple of size_t). Create a sequence template type with the values 0 through #vectors-1 in it. Create a template that deduces the type of the returned tuple. Create a recursive function that foreach's over each and every index in the returned cross product (pass in a function to generate the max index for a given depth). Use the seq to index the get()s on the index and on the tuple of vector, and wrap the call in a ()..., directly constructing the resulting tuple of elements. Then bob's your uncle. Dec 11, 2012 at 3:53
  • 1
    I wrote about half of it, but have to go to bed. :) Here is a use of the basic technique of using a sequence to unroll get calls: stackoverflow.com/questions/13447063/… and here is a pile of non-working code that might contain something useful: ideone.com/reaDYi Dec 11, 2012 at 3:58

3 Answers 3


Simpler recursive solution. It takes vectors as function arguments, not as a tuple. This version doesn't build temporary tuples, but uses lambdas instead. Now it makes no unnecessary copies/moves and seems to get optimized successfully.


// cross_imp(f, v...) means "do `f` for each element of cartesian product of v..."
template<typename F>
inline void cross_imp(F f) {
template<typename F, typename H, typename... Ts>
inline void cross_imp(F f, std::vector<H> const& h,
                           std::vector<Ts> const&... t) {
    for(H const& he: h)
        cross_imp([&](Ts const&... ts){
                      f(he, ts...);
                  }, t...);

template<typename... Ts>
std::vector<std::tuple<Ts...>> cross(std::vector<Ts> const&... in) {
    std::vector<std::tuple<Ts...>> res;
    cross_imp([&](Ts const&... ts){
              }, in...);
    return res;


int main() {
    std::vector<int> is = {2,5,9};
    std::vector<char const*> cps = {"foo","bar"};
    std::vector<double> ds = {1.5, 3.14, 2.71};
    auto res = cross(is, cps, ds);
    for(auto& a: res) {
        std::cout << '{' << std::get<0>(a) << ',' <<
                            std::get<1>(a) << ',' <<
                            std::get<2>(a) << "}\n";
  • +1 for a nice, clean answer - so, if I also had a fs (for floats), a cs (for chars), and a ds (for doubles), I should compose it by recursively calling cross(), correct?
    – kfmfe04
    Dec 12, 2012 at 14:57
  • @kfmfe04 It's enough to call cross with more arguments.
    – zch
    Dec 12, 2012 at 15:12
  • PERFECT - I need to dig into your code to understand it better - I'm sure there are lots of techniques I could use in there. ty for taking the time to crank this out.
    – kfmfe04
    Dec 12, 2012 at 15:58
  • @zch Decouple the type of pref and out, replace make_tuple with tie iterate for(auto&& he:h) with magic references, and you'd eliminate a tonne of redundant copies I think. May 15, 2013 at 19:33
  • 1
    @Yakk, I did it slightly differently, by using lambdas, but no redundant copies anymore. I like new version much more.
    – zch
    May 15, 2013 at 20:46

Been a while since I've been doing this, but here's a first attempt. No doubt it can be improved.

template<unsigned fixedIndex, class T>
class DynamicTupleGetter
    typedef typename std::tuple_element<fixedIndex, T>::type RetType;
    static RetType get(unsigned dynIndex, const T& tupleInstance)
        const RetType& ret = std::get<fixedIndex>(tupleInstance);

        if (fixedIndex == dynIndex)
            return ret;
        return DynamicTupleGetter<fixedIndex - 1, T>::get(dynIndex, tupleInstance);


template<class T>
class DynamicTupleGetter<0, T>
    typedef typename std::tuple_element<0, T>::type RetType;
    static RetType get(unsigned dynIndex, const T& tupleInstance)
        assert(dynIndex == 0);
        return std::get<0>(tupleInstance);
template<class Source>
struct Converter
    typedef typename std::tuple_element<0, Source>::type Zeroth;
    typedef typename std::tuple_element<1, Source>::type First;

    static const size_t size0 = std::tuple_size<Zeroth>::value;
    static const size_t size1 = std::tuple_size<First>::value;

    static const size_t  outerProductSize = size0 * size1;

    typedef typename std::tuple_element<0, Zeroth>::type BaseType0;
    typedef typename std::tuple_element<0, First>::type BaseType1;
    typedef typename std::tuple<BaseType0, BaseType1> EntryType;

    typedef std::array<EntryType, outerProductSize> DestinationType;

    DestinationType create(const Source& source)
        Zeroth zeroth = std::get<0>(source);
        First first = std::get<1>(source);
        typedef typename DynamicTupleGetter<size0 -1, Zeroth> ZerothGetter;
        typedef typename DynamicTupleGetter<size1 -1, First> FirstGetter;
        DestinationType result;
        size_t resultIndex = 0;
        for(size_t i = 0; i < size0; ++i)
            for(size_t j = 0; j < size1; ++j)
                std::get<0>(result[resultIndex]) = ZerothGetter::get(i, zeroth) ;        
                std::get<1>(result[resultIndex]) = FirstGetter::get(j, first); 
            return result;


template<class T>
void create(const T& source)
    Converter<T> converter;

    Converter<T>::DestinationType result = converter.create(source);

    std::cout << std::get<0>(std::get<3>(result)) << "," << std::get<1>(std::get<3>(result)) << std::endl;

auto intPart = std::make_tuple(2,5,9);
auto stringPart = std::make_tuple("foo","bar");
auto source = std::make_tuple(intPart, stringPart);

void f()
  • +1 for working code - I had to tweak it a tiny bit to get it to compile on gcc 4.7.2, but it builds and passes the test in the OP.
    – kfmfe04
    Dec 12, 2012 at 6:47
  • will this code work for auto source = std::make_tuple( intPart, stringPart, charPart, floatPart )?
    – kfmfe04
    Dec 12, 2012 at 10:27

In C++23, the easiest solution is std::views::cartesian_product:

std::vector<int> ints{1, 2, 3};
std::vector<std::string_view> strings{"foo","bar"};

for (auto [x, str] : std::views::cartesian_product(ints, strings)) {
    std::println("{} {}", x, str);

This code prints

1 foo
1 bar
2 foo
2 bar
3 foo
3 bar

See live example at Compiler Explorer.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.