I've written a for_each
for tuple
s:
template <typename Tuple, typename F, size_t begin, size_t end>
enable_if_t<begin == end || tuple_size<Tuple>::value < end> for_each(Tuple&, F&&) {
}
template <typename Tuple, typename F, size_t begin = 0U, size_t end = tuple_size<Tuple>::value>
enable_if_t<begin < end && tuple_size<Tuple>::value >= end> for_each(Tuple& t, F&& f) {
f(get<begin>(t));
for_each<Tuple, F, begin + 1, end>(t, forward<F>(f));
}
But Yakk's answer to this question gives a wonderful example of how to handle running a lambda on all tuple
values non-recursively:
namespace detail {
template<class F, class...Args>
void for_each_arg(F&& f, Args&&...args) {
using detail = int[];
static_cast<void>(detail{((f(std::forward<Args>(args))), void(), 0)..., 0});
}
}
template <typename F, typename Tuple>
void for_each_tuple_element(F&& f, Tuple&& t) {
return experimental::apply([&](auto&&...args) { detail::for_each_arg(forward<F>(f), decltype(args)(args)... ); }, forward<Tuple>(t));
}
This requires apply
. You can see my simplification of Yakk's answer here: http://ideone.com/yAYjmw
My question is this: Is there a way to somehow retrofit for_each_tuple_element
with a range, avoiding the recursion that my code incurs? I've tried constructing the subset of the tuple
defined by the range, but I can't seem to do that without using recursion, and then why not just my for_each
?