Suppose I want to create a compile-time heterogenous container of unique types from some sequence of non-unique types. In order to do this I need to iterate over the source type (some kind of tuple) and check whether each type already exists in my "unique" tuple.
My question is: How can I check whether a tuple (or a boost::fusion container) contains a type?
I'm open to using either the STL or boost.
#include <tuple>
#include <type_traits>
template <typename T, typename Tuple>
struct has_type;
template <typename T>
struct has_type<T, std::tuple<>> : std::false_type {};
template <typename T, typename U, typename... Ts>
struct has_type<T, std::tuple<U, Ts...>> : has_type<T, std::tuple<Ts...>> {};
template <typename T, typename... Ts>
struct has_type<T, std::tuple<T, Ts...>> : std::true_type {};
And an additional alias, if the trait itself should be std::true_type or std::false_type :
template <typename T, typename Tuple>
using tuple_contains_type = typename has_type<T, Tuple>::type;
T (then it eventually inherits from true_type stopping recursion), or the tuple has no more types (then it ends up with inheritance from false_type). Note there are specialized cases for <T, tuple<T, ...>> (T is same as head T) and <T, tuple<U, ...>> (T is different than head U). This is very similar to the way the tuple is defined itself.
Sep 21, 2014 at 11:38
tuple<T, Ts...> privately inherits from tuple<Ts...>
Sep 21, 2014 at 11:44
template <class T, class Tuple> inline constexpr bool tuple_contains_v = has_type<T, Tuple>::value;
In C++17 you can do it like this:
template <typename T, typename Tuple>
struct has_type;
template <typename T, typename... Us>
struct has_type<T, std::tuple<Us...>> : std::disjunction<std::is_same<T, Us>...> {};
In C++11 you have to roll your own or / disjunction. Here's a full C++11 version, with tests:
#include <tuple>
#include <type_traits>
template<typename... Conds>
struct or_ : std::false_type {};
template<typename Cond, typename... Conds>
struct or_<Cond, Conds...> : std::conditional<Cond::value, std::true_type, or_<Conds...>>::type
{};
/*
// C++17 version:
template<class... B>
using or_ = std::disjunction<B...>;
*/
template <typename T, typename Tuple>
struct has_type;
template <typename T, typename... Us>
struct has_type<T, std::tuple<Us...>> : or_<std::is_same<T, Us>...> {};
// Tests
static_assert(has_type<int, std::tuple<>>::value == false, "test");
static_assert(has_type<int, std::tuple<int>>::value == true, "test");
static_assert(has_type<int, std::tuple<float>>::value == false, "test");
static_assert(has_type<int, std::tuple<float, int>>::value == true, "test");
static_assert(has_type<int, std::tuple<int, float>>::value == true, "test");
static_assert(has_type<int, std::tuple<char, float, int>>::value == true, "test");
static_assert(has_type<int, std::tuple<char, float, bool>>::value == false, "test");
static_assert(has_type<const int, std::tuple<int>>::value == false, "test"); // we're using is_same so cv matters
static_assert(has_type<int, std::tuple<const int>>::value == false, "test"); // we're using is_same so cv matters
C++17 and up solution using fold expressions:
template<typename U, typename... T>
constexpr bool contains(std::tuple<T...>) {
return (std::is_same_v<U, T> || ...);
}
assert( contains<int >(std::declval<std::tuple<int, float>>()));
assert( contains<float >(std::declval<std::tuple<int, float>>()));
assert(!contains<double>(std::declval<std::tuple<int, float>>()));
//// In case std::declval ever becomes constexpr, the following should work as well:
// template<typename U, typename Tuple>
// constexpr inline bool contains_v = contains<U>(std::declval<Tuple>());
std::declval<Tuple>(), I updated my answer accordingly
Jan 8 at 23:25
Constexpr variable 'contains_v<int, std::tuple<>>' must be initialized by a constant expression
Because nobody posted it, I'm adding one more solution based on the bool trick I've learned about here on SO:
#include<type_traits>
#include<tuple>
template<bool...>
struct check {};
template<typename U, typename... T>
constexpr bool contains(std::tuple<T...>) {
return not std::is_same<
check<false, std::is_same<U, T>::value...>,
check<std::is_same<U, T>::value..., false>
>::value;
}
int main() {
static_assert(contains<int>(std::tuple<int, char, double>{}), "!");
static_assert(contains<char>(std::tuple<int, char, double>{}), "!");
static_assert(contains<double>(std::tuple<int, char, double>{}), "!");
static_assert(not contains<float>(std::tuple<int, char, double>{}), "!");
static_assert(not contains<void>(std::tuple<int, char, double>{}), "!");
}
In terms of compile-time performance it's slower than the accepted solution, but it's worth to mention it.
In C++14 it would be even easier to write. The standard template offers already all what you need to do that in the <utility> header:
template<typename U, typename... T>
constexpr auto contains(std::tuple<T...>) {
return not std::is_same<
std::integer_sequence<bool, false, std::is_same<U, T>::value...>,
std::integer_sequence<bool, std::is_same<U, T>::value..., false>
>::value;
}
This is not far conceptually from what std::get does (available since C++14 for types), but note that the latter fails to compile if the type U is present more than once in T....
If it fits with your requirements mostly depends on the actual problem.
I actually needed something like this for a project. This was my solution:
#include <tuple>
#include <type_traits>
namespace detail {
struct null { };
}
template <typename T, typename Tuple>
struct tuple_contains;
template <typename T, typename... Ts>
struct tuple_contains<T, std::tuple<Ts...>> :
std::integral_constant<
bool,
!std::is_same<
std::tuple<typename std::conditional<std::is_same<T, Ts>::value, detail::null, Ts>::type...>,
std::tuple<Ts...>
>::value
>
{ };
The main advantage of this method is that it's one instantiation, no recursion required.
Here is a version that does not recursively instantiate the template to check for a matching type. Instead it uses SFINAE with indices-based meta-programming:
#include <type_traits>
#include <tuple>
template <std::size_t... Indices>
struct index_sequence {
typedef index_sequence<Indices..., sizeof...(Indices)> next;
};
template <std::size_t Start>
struct make_index_sequence {
typedef typename make_index_sequence<Start - 1>::type::next type;
};
template <>
struct make_index_sequence<0> {
typedef index_sequence<> type;
};
template <int n>
using make_index_sequence_t = typename make_index_sequence<n>::type;
template <typename Value, typename Sequence>
struct lookup;
template <typename Value, std::size_t... index>
struct lookup<Value, index_sequence<index...>>
{
private:
struct null;
template <typename... Args>
static std::false_type
apply(std::conditional_t<std::is_convertible<Args, Value>::value, null, Args>...);
template <typename...>
static std::true_type apply(...);
template <typename... Args>
static auto apply_helper(Args&&...) ->
decltype(apply<std::remove_reference_t<Args>...>(std::declval<Args>()...));
public:
template <typename Tuple>
using value = decltype(
apply_helper(
std::declval<
typename std::tuple_element<index, Tuple>::type
>()...
)
);
};
template <typename Value, typename Tuple>
using has_type = decltype(
typename lookup<Value,
make_index_sequence_t<std::tuple_size<Tuple>::value>
>::template value<Tuple>{}
);
Since you asked for it, here is a boost::mpl version:
#include <boost/mpl/unique.hpp>
#include <boost/mpl/sort.hpp>
#include <boost/mpl/vector.hpp>
#include <boost/type_traits/is_same.hpp>
using namespace boost;
template<typename Seq>
struct unique_concat :
mpl::unique<typename mpl::sort<Seq, is_same<mpl::_1,mpl::_2>>::type,
is_same<mpl::_1,mpl::_2>> {};
template<typename T>
struct print;
int main()
{
typedef mpl::vector<int, float, float, char, int, double, int> input;
print<unique_concat<input>::type> asdf;
return 0;
}
g++ -Wall -Wextra -pedantic -Wno-sign-compare -Wno-long-long -o tpl_b tuple_boost.cpp yields an error: tuple_boost.cpp:19:37: error: aggregate ‘print<boost::mpl::v_item<double, boost::mpl::v_item<char, boost::mpl::v_item<float, boost::mpl::v_item<int, boost::mpl::vector0<mpl_::na>, 0>, 0>, 0>, 0> > asdf’ has incomplete type and cannot be defined The specific error: print<unique_concat<input>::type> asdf;
Sep 24, 2014 at 1:26
gcc 4.9.1-1 and boost 1.55.0-6.
Sep 24, 2014 at 1:42
mpl::has_key. isn't it what OP wants ?
boostwhy not use the MPL? This would be a trivial task.c++tag just refers to the current version?