Ok, got it. It's not pretty but it works:

```
template<class ... T>
struct type_list{};
struct somestructA{};
struct somestructB{};
using type_list_1 = type_list<int, somestructA, char>;
using type_list_2 = type_list<somestructB>;
using type_list_3 = type_list<double, short, float>;
template<class TL1, class TL2>
struct add;
template<class ... T1s, class ... T2s>
struct add<type_list<T1s...>, type_list<T2s...>>
{
using type = type_list<T1s..., T2s...>;
};
template<class ... TL>
struct concat;
template<class TL, class ... TLs>
struct concat<TL, TLs...>
{
using type = typename add<TL, typename concat<TLs...>::type>::type;
};
template<class TL>
struct concat<TL>
{
using type = TL;
};
static_assert(std::is_same_v<type_list<int, somestructA, char, double, short, float>, typename add<type_list_1, type_list_3>::type>);
template<class TL1, class TL2>
struct multiply_one;
// Prepends each element of T1 to the list T2.
template<class ... T1s, class ... T2s>
struct multiply_one<type_list<T1s...>, type_list<T2s...>>
{
using type = typename concat<type_list<type_list<T1s, T2s...>...>>::type;
};
static_assert(std::is_same_v<
type_list<
type_list<int, double, short, float>,
type_list<somestructA, double, short, float>,
type_list<char, double, short, float>
>,
typename multiply_one<type_list_1, type_list_3>::type>);
// Prepends each element of TL to all type lists in TLL.
template<class TL, class TLL>
struct multiply_all;
template<class TL, class ... TLs>
struct multiply_all<TL, type_list<TLs...>>
{
using type = typename concat<typename multiply_one<TL, TLs>::type...>::type;
};
static_assert(std::is_same_v<
type_list<
type_list<int, double, short, float>,
type_list<somestructA, double, short, float>,
type_list<char, double, short, float>
>,
typename multiply_all<type_list_1, type_list<type_list_3>>::type>);
static_assert(std::is_same_v<
type_list<
type_list<int, somestructB>,
type_list<somestructA, somestructB>,
type_list<char, somestructB>,
type_list<int, double, short, float>,
type_list<somestructA, double, short, float>,
type_list<char, double, short, float>
>,
typename multiply_all<type_list_1, type_list<type_list_2, type_list_3>>::type>);
template<class TL, class ... TLs>
struct cartesian_product
{
using type = typename multiply_all<TL, typename cartesian_product<TLs...>::type>::type;
};
template<class ... Ts>
struct cartesian_product<type_list<Ts...>>
{
using type = type_list<type_list<Ts>...>;
};
using expected_result = type_list<
type_list<int, somestructB, double>,
type_list<somestructA, somestructB, double>,
type_list<char, somestructB, double>,
type_list<int, somestructB, short>,
type_list<somestructA, somestructB, short>,
type_list<char, somestructB, short>,
type_list<int, somestructB, float>,
type_list<somestructA, somestructB, float>,
type_list<char, somestructB, float>
>;
static_assert(std::is_same_v<expected_result,
cartesian_product<type_list_1, type_list_2, type_list_3>::type>);
```

https://godbolt.org/z/L5eamT

I left my own `static_assert`

tests in there for... Well, I hope they help.

Also, I'm sure there has to be a nicer solution. But this was the obvious "I know this will eventually lead to the goal" path. I eventually had to resort to adding a `concat`

or sorts, I'm sure that it could be used much earlier to skip most of the cruft.

`cartesian_product`

is a list of type lists, and at each recursion step you want to append stuff to each inner type list. Getting into that second packing level of pack takes some deduction...A cartesian product of tuples in C++17"?1more comment