src/hb-meta.hh - third_party/harfbuzz - Git at Google

 /*
  * Copyright © 2018  Google, Inc.
  *
  *  This is part of HarfBuzz, a text shaping library.
  *
  * Permission is hereby granted, without written agreement and without
  * license or royalty fees, to use, copy, modify, and distribute this
  * software and its documentation for any purpose, provided that the
  * above copyright notice and the following two paragraphs appear in
  * all copies of this software.
  *
  * IN NO EVENT SHALL THE COPYRIGHT HOLDER BE LIABLE TO ANY PARTY FOR
  * DIRECT, INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES
  * ARISING OUT OF THE USE OF THIS SOFTWARE AND ITS DOCUMENTATION, EVEN
  * IF THE COPYRIGHT HOLDER HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH
  * DAMAGE.
  *
  * THE COPYRIGHT HOLDER SPECIFICALLY DISCLAIMS ANY WARRANTIES, INCLUDING,
  * BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND
  * FITNESS FOR A PARTICULAR PURPOSE.  THE SOFTWARE PROVIDED HEREUNDER IS
  * ON AN "AS IS" BASIS, AND THE COPYRIGHT HOLDER HAS NO OBLIGATION TO
  * PROVIDE MAINTENANCE, SUPPORT, UPDATES, ENHANCEMENTS, OR MODIFICATIONS.
  *
  * Google Author(s): Behdad Esfahbod
  */

 #ifndef HB_META_HH
 #define HB_META_HH

 #include "hb.hh"


 /*
  * C++ template meta-programming & fundamentals used with them.
  */

 /* Void!  For when we need a expression-type of void. */
 struct hb_empty_t {};

 /* https://en.cppreference.com/w/cpp/types/void_t */
 template<typename... Ts> struct _hb_void_t { typedef void type; };
 template<typename... Ts> using hb_void_t = typename _hb_void_t<Ts...>::type;

 template<typename Head, typename... Ts> struct _hb_head_t { typedef Head type; };
 template<typename... Ts> using hb_head_t = typename _hb_head_t<Ts...>::type;

 template <typename T, T v> struct hb_integral_constant { static constexpr T value = v; };
 template <bool b> using hb_bool_constant = hb_integral_constant<bool, b>;
 using hb_true_type = hb_bool_constant<true>;
 using hb_false_type = hb_bool_constant<false>;

 /* Static-assert as expression. */
 template <bool cond> struct static_assert_expr;
 template <> struct static_assert_expr<true> : hb_false_type {};
 #define static_assert_expr(C) static_assert_expr<C>::value

 /* Basic type SFINAE. */

 template <bool B, typename T = void> struct hb_enable_if {};
 template <typename T>                struct hb_enable_if<true, T> { typedef T type; };
 #define hb_enable_if(Cond) typename hb_enable_if<(Cond)>::type* = nullptr
 /* Concepts/Requires alias: */
 #define hb_requires(Cond) hb_enable_if((Cond))

 template <typename T, typename T2> struct hb_is_same : hb_false_type {};
 template <typename T>              struct hb_is_same<T, T> : hb_true_type {};
 #define hb_is_same(T, T2) hb_is_same<T, T2>::value

 /* Function overloading SFINAE and priority. */

 #define HB_RETURN(Ret, E) -> hb_head_t<Ret, decltype ((E))> { return (E); }
 #define HB_AUTO_RETURN(E) -> decltype ((E)) { return (E); }
 #define HB_VOID_RETURN(E) -> hb_void_t<decltype ((E))> { (E); }

 template <unsigned Pri> struct hb_priority : hb_priority<Pri - 1> {};
 template <>             struct hb_priority<0> {};
 #define hb_prioritize hb_priority<16> ()

 #define HB_FUNCOBJ(x) static_const x HB_UNUSED


 template <typename T> struct hb_type_identity_t { typedef T type; };
 template <typename T> using hb_type_identity = typename hb_type_identity_t<T>::type;

 struct
 {
   template <typename T> constexpr T*
   operator () (T& arg) const
   {
 #pragma GCC diagnostic push
 #pragma GCC diagnostic ignored "-Wcast-align"
     /* https://en.cppreference.com/w/cpp/memory/addressof */
     return reinterpret_cast<T*> (
 	     &const_cast<char&> (
 		reinterpret_cast<const volatile char&> (arg)));
 #pragma GCC diagnostic pop
   }
 }
 HB_FUNCOBJ (hb_addressof);

 template <typename T> static inline T hb_declval ();
 #define hb_declval(T) (hb_declval<T> ())

 template <typename T> struct hb_match_const		: hb_type_identity_t<T>, hb_false_type	{};
 template <typename T> struct hb_match_const<const T>	: hb_type_identity_t<T>, hb_true_type	{};
 template <typename T> using hb_remove_const = typename hb_match_const<T>::type;
 template <typename T> using hb_add_const = const T;
 #define hb_is_const(T) hb_match_const<T>::value
 template <typename T> struct hb_match_reference		: hb_type_identity_t<T>, hb_false_type	{};
 template <typename T> struct hb_match_reference<T &>	: hb_type_identity_t<T>, hb_true_type	{};
 template <typename T> struct hb_match_reference<T &&>	: hb_type_identity_t<T>, hb_true_type	{};
 template <typename T> using hb_remove_reference = typename hb_match_reference<T>::type;
 template <typename T> auto _hb_try_add_lvalue_reference (hb_priority<1>) -> hb_type_identity<T&>;
 template <typename T> auto _hb_try_add_lvalue_reference (hb_priority<0>) -> hb_type_identity<T>;
 template <typename T> using hb_add_lvalue_reference = decltype (_hb_try_add_lvalue_reference<T> (hb_prioritize));
 template <typename T> auto _hb_try_add_rvalue_reference (hb_priority<1>) -> hb_type_identity<T&&>;
 template <typename T> auto _hb_try_add_rvalue_reference (hb_priority<0>) -> hb_type_identity<T>;
 template <typename T> using hb_add_rvalue_reference = decltype (_hb_try_add_rvalue_reference<T> (hb_prioritize));
 #define hb_is_reference(T) hb_match_reference<T>::value
 template <typename T> struct hb_match_pointer		: hb_type_identity_t<T>, hb_false_type	{};
 template <typename T> struct hb_match_pointer<T *>	: hb_type_identity_t<T>, hb_true_type	{};
 template <typename T> using hb_remove_pointer = typename hb_match_pointer<T>::type;
 template <typename T> auto _hb_try_add_pointer (hb_priority<1>) -> hb_type_identity<hb_remove_reference<T>*>;
 template <typename T> auto _hb_try_add_pointer (hb_priority<1>) -> hb_type_identity<T>;
 template <typename T> using hb_add_pointer = decltype (_hb_try_add_pointer<T> (hb_prioritize));
 #define hb_is_pointer(T) hb_match_pointer<T>::value


 /* TODO Add feature-parity to std::decay. */
 template <typename T> using hb_decay = hb_remove_const<hb_remove_reference<T>>;


 template<bool B, class T, class F>
 struct _hb_conditional { typedef T type; };
 template<class T, class F>
 struct _hb_conditional<false, T, F> { typedef F type; };
 template<bool B, class T, class F>
 using hb_conditional = typename _hb_conditional<B, T, F>::type;


 template <typename From, typename To>
 struct hb_is_convertible
 {
   private:
   static constexpr bool   from_void = hb_is_same (void, hb_decay<From>);
   static constexpr bool     to_void = hb_is_same (void, hb_decay<To>  );
   static constexpr bool either_void = from_void || to_void;
   static constexpr bool   both_void = from_void && to_void;

   static hb_true_type impl2 (hb_conditional<to_void, int, To>);

   template <typename T>
   static auto impl (hb_priority<1>) -> decltype (impl2 (hb_declval (T)));
   template <typename T>
   static hb_false_type impl (hb_priority<0>);
   public:
   static constexpr bool value = both_void ||
 		       (!either_void &&
 			decltype (impl<hb_conditional<from_void, int, From>> (hb_prioritize))::value);
 };
 #define hb_is_convertible(From,To) hb_is_convertible<From, To>::value

 template <typename Base, typename Derived>
 using hb_is_base_of = hb_is_convertible<hb_decay<Derived> *, hb_decay<Base> *>;
 #define hb_is_base_of(Base,Derived) hb_is_base_of<Base, Derived>::value

 template <typename From, typename To>
 using hb_is_cr_convertible = hb_bool_constant<
   hb_is_same (hb_decay<From>, hb_decay<To>) &&
   (!hb_is_const (From) || hb_is_const (To)) &&
   (!hb_is_reference (To) || hb_is_const (To) || hb_is_reference (To))
 >;
 #define hb_is_cr_convertible(From,To) hb_is_cr_convertible<From, To>::value

 /* std::move and std::forward */

 template <typename T>
 static constexpr hb_remove_reference<T>&& hb_move (T&& t) { return (hb_remove_reference<T>&&) (t); }

 template <typename T>
 static constexpr T&& hb_forward (hb_remove_reference<T>& t) { return (T&&) t; }
 template <typename T>
 static constexpr T&& hb_forward (hb_remove_reference<T>&& t) { return (T&&) t; }

 struct
 {
   template <typename T> constexpr auto
   operator () (T&& v) const HB_AUTO_RETURN (hb_forward<T> (v))

   template <typename T> constexpr auto
   operator () (T *v) const HB_AUTO_RETURN (*v)
 }
 HB_FUNCOBJ (hb_deref);

 struct
 {
   template <typename T> constexpr auto
   operator () (T&& v) const HB_AUTO_RETURN (hb_forward<T> (v))

   template <typename T> constexpr auto
   operator () (T& v) const HB_AUTO_RETURN (hb_addressof (v))
 }
 HB_FUNCOBJ (hb_ref);

 template <typename T>
 struct hb_reference_wrapper
 {
   hb_reference_wrapper (T v) : v (v) {}
   bool operator == (const hb_reference_wrapper& o) const { return v == o.v; }
   bool operator != (const hb_reference_wrapper& o) const { return v != o.v; }
   operator T () const { return v; }
   T get () const { return v; }
   T v;
 };
 template <typename T>
 struct hb_reference_wrapper<T&>
 {
   hb_reference_wrapper (T& v) : v (hb_addressof (v)) {}
   bool operator == (const hb_reference_wrapper& o) const { return v == o.v; }
   bool operator != (const hb_reference_wrapper& o) const { return v != o.v; }
   operator T& () const { return *v; }
   T& get () const { return *v; }
   T* v;
 };


 /* Type traits */

 template <typename T>
 using hb_is_integral = hb_bool_constant<
   hb_is_same (hb_decay<T>, char) ||
   hb_is_same (hb_decay<T>, signed char) ||
   hb_is_same (hb_decay<T>, unsigned char) ||
   hb_is_same (hb_decay<T>, signed int) ||
   hb_is_same (hb_decay<T>, unsigned int) ||
   hb_is_same (hb_decay<T>, signed short) ||
   hb_is_same (hb_decay<T>, unsigned short) ||
   hb_is_same (hb_decay<T>, signed long) ||
   hb_is_same (hb_decay<T>, unsigned long) ||
   hb_is_same (hb_decay<T>, signed long long) ||
   hb_is_same (hb_decay<T>, unsigned long long) ||
   false
 >;
 #define hb_is_integral(T) hb_is_integral<T>::value
 template <typename T>
 using hb_is_floating_point = hb_bool_constant<
   hb_is_same (hb_decay<T>, float) ||
   hb_is_same (hb_decay<T>, double) ||
   hb_is_same (hb_decay<T>, long double) ||
   false
 >;
 #define hb_is_floating_point(T) hb_is_floating_point<T>::value
 template <typename T>
 using hb_is_arithmetic = hb_bool_constant<
   hb_is_integral (T) ||
   hb_is_floating_point (T) ||
   false
 >;
 #define hb_is_arithmetic(T) hb_is_arithmetic<T>::value


 template <typename T, bool is_arithmetic> struct hb_is_signed_;
 template <typename T> struct hb_is_signed_<T, false>	: hb_false_type {};
 template <typename T> struct hb_is_signed_<T, true>	: hb_bool_constant<(T) -1 < (T) 0> {};
 template <typename T> struct hb_is_signed : hb_is_signed_<T, hb_is_arithmetic (T)> {};
 #define hb_is_signed(T) hb_is_signed<T>::value
 template <typename T, bool is_arithmetic> struct hb_is_unsigned_;
 template <typename T> struct hb_is_unsigned_<T, false>	: hb_false_type {};
 template <typename T> struct hb_is_unsigned_<T, true>	: hb_bool_constant<(T) 0 < (T) -1> {};
 template <typename T> struct hb_is_unsigned : hb_is_unsigned_<T, hb_is_arithmetic (T)> {};
 #define hb_is_unsigned(T) hb_is_unsigned<T>::value

 template <typename T> struct hb_int_min;
 template <> struct hb_int_min<char>			: hb_integral_constant<char,			CHAR_MIN>	{};
 template <> struct hb_int_min<signed char>		: hb_integral_constant<signed char,		SCHAR_MIN>	{};
 template <> struct hb_int_min<unsigned char>		: hb_integral_constant<unsigned char,		0>		{};
 template <> struct hb_int_min<signed short>		: hb_integral_constant<signed short,		SHRT_MIN>	{};
 template <> struct hb_int_min<unsigned short>		: hb_integral_constant<unsigned short,		0>		{};
 template <> struct hb_int_min<signed int>		: hb_integral_constant<signed int,		INT_MIN>	{};
 template <> struct hb_int_min<unsigned int>		: hb_integral_constant<unsigned int,		0>		{};
 template <> struct hb_int_min<signed long>		: hb_integral_constant<signed long,		LONG_MIN>	{};
 template <> struct hb_int_min<unsigned long>		: hb_integral_constant<unsigned long,		0>		{};
 template <> struct hb_int_min<signed long long>		: hb_integral_constant<signed long long,	LLONG_MIN>	{};
 template <> struct hb_int_min<unsigned long long>	: hb_integral_constant<unsigned long long,	0>		{};
 template <typename T> struct hb_int_min<T *>		: hb_integral_constant<T *,			nullptr>	{};
 #define hb_int_min(T) hb_int_min<T>::value
 template <typename T> struct hb_int_max;
 template <> struct hb_int_max<char>			: hb_integral_constant<char,			CHAR_MAX>	{};
 template <> struct hb_int_max<signed char>		: hb_integral_constant<signed char,		SCHAR_MAX>	{};
 template <> struct hb_int_max<unsigned char>		: hb_integral_constant<unsigned char,		UCHAR_MAX>	{};
 template <> struct hb_int_max<signed short>		: hb_integral_constant<signed short,		SHRT_MAX>	{};
 template <> struct hb_int_max<unsigned short>		: hb_integral_constant<unsigned short,		USHRT_MAX>	{};
 template <> struct hb_int_max<signed int>		: hb_integral_constant<signed int,		INT_MAX>	{};
 template <> struct hb_int_max<unsigned int>		: hb_integral_constant<unsigned int,		UINT_MAX>	{};
 template <> struct hb_int_max<signed long>		: hb_integral_constant<signed long,		LONG_MAX>	{};
 template <> struct hb_int_max<unsigned long>		: hb_integral_constant<unsigned long,		ULONG_MAX>	{};
 template <> struct hb_int_max<signed long long>		: hb_integral_constant<signed long long,	LLONG_MAX>	{};
 template <> struct hb_int_max<unsigned long long>	: hb_integral_constant<unsigned long long,	ULLONG_MAX>	{};
 #define hb_int_max(T) hb_int_max<T>::value


 /* Class traits. */

 #define HB_DELETE_COPY_ASSIGN(TypeName) \
   TypeName(const TypeName&) = delete; \
   void operator=(const TypeName&) = delete
 #define HB_DELETE_CREATE_COPY_ASSIGN(TypeName) \
   TypeName() = delete; \
   TypeName(const TypeName&) = delete; \
   void operator=(const TypeName&) = delete

 template <typename T, typename>
 struct _hb_is_destructible : hb_false_type {};
 template <typename T>
 struct _hb_is_destructible<T, hb_void_t<decltype (hb_declval (T).~T ())>> : hb_true_type {};
 template <typename T>
 using hb_is_destructible = _hb_is_destructible<T, void>;
 #define hb_is_destructible(T) hb_is_destructible<T>::value

 template <typename T, typename, typename ...Ts>
 struct _hb_is_constructible : hb_false_type {};
 template <typename T, typename ...Ts>
 struct _hb_is_constructible<T, hb_void_t<decltype (T (hb_declval (Ts)...))>, Ts...> : hb_true_type {};
 template <typename T, typename ...Ts>
 using hb_is_constructible = _hb_is_constructible<T, void, Ts...>;
 #define hb_is_constructible(...) hb_is_constructible<__VA_ARGS__>::value

 template <typename T>
 using hb_is_default_constructible = hb_is_constructible<T>;
 #define hb_is_default_constructible(T) hb_is_default_constructible<T>::value

 template <typename T>
 using hb_is_copy_constructible = hb_is_constructible<T, hb_add_lvalue_reference<hb_add_const<T>>>;
 #define hb_is_copy_constructible(T) hb_is_copy_constructible<T>::value

 template <typename T>
 using hb_is_move_constructible = hb_is_constructible<T, hb_add_rvalue_reference<hb_add_const<T>>>;
 #define hb_is_move_constructible(T) hb_is_move_constructible<T>::value

 template <typename T, typename U, typename>
 struct _hb_is_assignable : hb_false_type {};
 template <typename T, typename U>
 struct _hb_is_assignable<T, U, hb_void_t<decltype (hb_declval (T) = hb_declval (U))>> : hb_true_type {};
 template <typename T, typename U>
 using hb_is_assignable = _hb_is_assignable<T, U, void>;
 #define hb_is_assignable(T,U) hb_is_assignable<T, U>::value

 template <typename T>
 using hb_is_copy_assignable = hb_is_assignable<hb_add_lvalue_reference<T>,
 					       hb_add_lvalue_reference<hb_add_const<T>>>;
 #define hb_is_copy_assignable(T) hb_is_copy_assignable<T>::value

 template <typename T>
 using hb_is_move_assignable = hb_is_assignable<hb_add_lvalue_reference<T>,
 					       hb_add_rvalue_reference<T>>;
 #define hb_is_move_assignable(T) hb_is_move_assignable<T>::value

 /* Trivial versions. */

 template <typename T> union hb_trivial { T value; };

 template <typename T>
 using hb_is_trivially_destructible= hb_is_destructible<hb_trivial<T>>;
 #define hb_is_trivially_destructible(T) hb_is_trivially_destructible<T>::value

 /* Don't know how to do the following. */
 //template <typename T, typename ...Ts>
 //using hb_is_trivially_constructible= hb_is_constructible<hb_trivial<T>, hb_trivial<Ts>...>;
 //#define hb_is_trivially_constructible(...) hb_is_trivially_constructible<__VA_ARGS__>::value

 template <typename T>
 using hb_is_trivially_default_constructible= hb_is_default_constructible<hb_trivial<T>>;
 #define hb_is_trivially_default_constructible(T) hb_is_trivially_default_constructible<T>::value

 template <typename T>
 using hb_is_trivially_copy_constructible= hb_is_copy_constructible<hb_trivial<T>>;
 #define hb_is_trivially_copy_constructible(T) hb_is_trivially_copy_constructible<T>::value

 template <typename T>
 using hb_is_trivially_move_constructible= hb_is_move_constructible<hb_trivial<T>>;
 #define hb_is_trivially_move_constructible(T) hb_is_trivially_move_constructible<T>::value

 /* Don't know how to do the following. */
 //template <typename T, typename U>
 //using hb_is_trivially_assignable= hb_is_assignable<hb_trivial<T>, hb_trivial<U>>;
 //#define hb_is_trivially_assignable(T,U) hb_is_trivially_assignable<T, U>::value

 template <typename T>
 using hb_is_trivially_copy_assignable= hb_is_copy_assignable<hb_trivial<T>>;
 #define hb_is_trivially_copy_assignable(T) hb_is_trivially_copy_assignable<T>::value

 template <typename T>
 using hb_is_trivially_move_assignable= hb_is_move_assignable<hb_trivial<T>>;
 #define hb_is_trivially_move_assignable(T) hb_is_trivially_move_assignable<T>::value

 template <typename T>
 using hb_is_trivially_copyable= hb_bool_constant<
   hb_is_trivially_destructible (T) &&
   (!hb_is_move_assignable (T) || hb_is_trivially_move_assignable (T)) &&
   (!hb_is_move_constructible (T) || hb_is_trivially_move_constructible (T)) &&
   (!hb_is_copy_assignable (T) || hb_is_trivially_copy_assignable (T)) &&
   (!hb_is_copy_constructible (T) || hb_is_trivially_copy_constructible (T)) &&
   true
 >;
 #define hb_is_trivially_copyable(T) hb_is_trivially_copyable<T>::value

 template <typename T>
 using hb_is_trivial= hb_bool_constant<
   hb_is_trivially_copyable (T) &&
   hb_is_trivially_default_constructible (T)
 >;
 #define hb_is_trivial(T) hb_is_trivial<T>::value

 /* hb_unwrap_type (T)
  * If T has no T::type, returns T. Otherwise calls itself on T::type recursively.
  */

 template <typename T, typename>
 struct _hb_unwrap_type : hb_type_identity_t<T> {};
 template <typename T>
 struct _hb_unwrap_type<T, hb_void_t<typename T::type>> : _hb_unwrap_type<typename T::type, void> {};
 template <typename T>
 using hb_unwrap_type = _hb_unwrap_type<T, void>;
 #define hb_unwrap_type(T) typename hb_unwrap_type<T>::type

 #endif /* HB_META_HH */
	/*
	* Copyright © 2018 Google, Inc.
	*
	* This is part of HarfBuzz, a text shaping library.
	*
	* Permission is hereby granted, without written agreement and without
	* license or royalty fees, to use, copy, modify, and distribute this
	* software and its documentation for any purpose, provided that the
	* above copyright notice and the following two paragraphs appear in
	* all copies of this software.
	*
	* IN NO EVENT SHALL THE COPYRIGHT HOLDER BE LIABLE TO ANY PARTY FOR
	* DIRECT, INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES
	* ARISING OUT OF THE USE OF THIS SOFTWARE AND ITS DOCUMENTATION, EVEN
	* IF THE COPYRIGHT HOLDER HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH
	* DAMAGE.
	*
	* THE COPYRIGHT HOLDER SPECIFICALLY DISCLAIMS ANY WARRANTIES, INCLUDING,
	* BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND
	* FITNESS FOR A PARTICULAR PURPOSE. THE SOFTWARE PROVIDED HEREUNDER IS
	* ON AN "AS IS" BASIS, AND THE COPYRIGHT HOLDER HAS NO OBLIGATION TO
	* PROVIDE MAINTENANCE, SUPPORT, UPDATES, ENHANCEMENTS, OR MODIFICATIONS.
	*
	* Google Author(s): Behdad Esfahbod
	*/

	#ifndef HB_META_HH
	#define HB_META_HH

	#include "hb.hh"


	/*
	* C++ template meta-programming & fundamentals used with them.
	*/

	/* Void! For when we need a expression-type of void. */
	struct hb_empty_t {};

	/* https://en.cppreference.com/w/cpp/types/void_t */
	template<typename... Ts> struct _hb_void_t { typedef void type; };
	template<typename... Ts> using hb_void_t = typename _hb_void_t<Ts...>::type;

	template<typename Head, typename... Ts> struct _hb_head_t { typedef Head type; };
	template<typename... Ts> using hb_head_t = typename _hb_head_t<Ts...>::type;

	template <typename T, T v> struct hb_integral_constant { static constexpr T value = v; };
	template <bool b> using hb_bool_constant = hb_integral_constant<bool, b>;
	using hb_true_type = hb_bool_constant<true>;
	using hb_false_type = hb_bool_constant<false>;

	/* Static-assert as expression. */
	template <bool cond> struct static_assert_expr;
	template <> struct static_assert_expr<true> : hb_false_type {};
	#define static_assert_expr(C) static_assert_expr<C>::value

	/* Basic type SFINAE. */

	template <bool B, typename T = void> struct hb_enable_if {};
	template <typename T> struct hb_enable_if<true, T> { typedef T type; };
	#define hb_enable_if(Cond) typename hb_enable_if<(Cond)>::type* = nullptr
	/* Concepts/Requires alias: */
	#define hb_requires(Cond) hb_enable_if((Cond))

	template <typename T, typename T2> struct hb_is_same : hb_false_type {};
	template <typename T> struct hb_is_same<T, T> : hb_true_type {};
	#define hb_is_same(T, T2) hb_is_same<T, T2>::value

	/* Function overloading SFINAE and priority. */

	#define HB_RETURN(Ret, E) -> hb_head_t<Ret, decltype ((E))> { return (E); }
	#define HB_AUTO_RETURN(E) -> decltype ((E)) { return (E); }
	#define HB_VOID_RETURN(E) -> hb_void_t<decltype ((E))> { (E); }

	template <unsigned Pri> struct hb_priority : hb_priority<Pri - 1> {};
	template <> struct hb_priority<0> {};
	#define hb_prioritize hb_priority<16> ()

	#define HB_FUNCOBJ(x) static_const x HB_UNUSED


	template <typename T> struct hb_type_identity_t { typedef T type; };
	template <typename T> using hb_type_identity = typename hb_type_identity_t<T>::type;

	struct
	{
	template <typename T> constexpr T*
	operator () (T& arg) const
	{
	#pragma GCC diagnostic push
	#pragma GCC diagnostic ignored "-Wcast-align"
	/* https://en.cppreference.com/w/cpp/memory/addressof */
	return reinterpret_cast<T*> (
	&const_cast<char&> (
	reinterpret_cast<const volatile char&> (arg)));
	#pragma GCC diagnostic pop
	}
	}
	HB_FUNCOBJ (hb_addressof);

	template <typename T> static inline T hb_declval ();
	#define hb_declval(T) (hb_declval<T> ())

	template <typename T> struct hb_match_const : hb_type_identity_t<T>, hb_false_type {};
	template <typename T> struct hb_match_const<const T> : hb_type_identity_t<T>, hb_true_type {};
	template <typename T> using hb_remove_const = typename hb_match_const<T>::type;
	template <typename T> using hb_add_const = const T;
	#define hb_is_const(T) hb_match_const<T>::value
	template <typename T> struct hb_match_reference : hb_type_identity_t<T>, hb_false_type {};
	template <typename T> struct hb_match_reference<T &> : hb_type_identity_t<T>, hb_true_type {};
	template <typename T> struct hb_match_reference<T &&> : hb_type_identity_t<T>, hb_true_type {};
	template <typename T> using hb_remove_reference = typename hb_match_reference<T>::type;
	template <typename T> auto _hb_try_add_lvalue_reference (hb_priority<1>) -> hb_type_identity<T&>;
	template <typename T> auto _hb_try_add_lvalue_reference (hb_priority<0>) -> hb_type_identity<T>;
	template <typename T> using hb_add_lvalue_reference = decltype (_hb_try_add_lvalue_reference<T> (hb_prioritize));
	template <typename T> auto _hb_try_add_rvalue_reference (hb_priority<1>) -> hb_type_identity<T&&>;
	template <typename T> auto _hb_try_add_rvalue_reference (hb_priority<0>) -> hb_type_identity<T>;
	template <typename T> using hb_add_rvalue_reference = decltype (_hb_try_add_rvalue_reference<T> (hb_prioritize));
	#define hb_is_reference(T) hb_match_reference<T>::value
	template <typename T> struct hb_match_pointer : hb_type_identity_t<T>, hb_false_type {};
	template <typename T> struct hb_match_pointer<T *> : hb_type_identity_t<T>, hb_true_type {};
	template <typename T> using hb_remove_pointer = typename hb_match_pointer<T>::type;
	template <typename T> auto _hb_try_add_pointer (hb_priority<1>) -> hb_type_identity<hb_remove_reference<T>*>;
	template <typename T> auto _hb_try_add_pointer (hb_priority<1>) -> hb_type_identity<T>;
	template <typename T> using hb_add_pointer = decltype (_hb_try_add_pointer<T> (hb_prioritize));
	#define hb_is_pointer(T) hb_match_pointer<T>::value


	/* TODO Add feature-parity to std::decay. */
	template <typename T> using hb_decay = hb_remove_const<hb_remove_reference<T>>;


	template<bool B, class T, class F>
	struct _hb_conditional { typedef T type; };
	template<class T, class F>
	struct _hb_conditional<false, T, F> { typedef F type; };
	template<bool B, class T, class F>
	using hb_conditional = typename _hb_conditional<B, T, F>::type;


	template <typename From, typename To>
	struct hb_is_convertible
	{
	private:
	static constexpr bool from_void = hb_is_same (void, hb_decay<From>);
	static constexpr bool to_void = hb_is_same (void, hb_decay<To> );
	static constexpr bool either_void = from_void \|\| to_void;
	static constexpr bool both_void = from_void && to_void;

	static hb_true_type impl2 (hb_conditional<to_void, int, To>);

	template <typename T>
	static auto impl (hb_priority<1>) -> decltype (impl2 (hb_declval (T)));
	template <typename T>
	static hb_false_type impl (hb_priority<0>);
	public:
	static constexpr bool value = both_void \|\|
	(!either_void &&
	decltype (impl<hb_conditional<from_void, int, From>> (hb_prioritize))::value);
	};
	#define hb_is_convertible(From,To) hb_is_convertible<From, To>::value

	template <typename Base, typename Derived>
	using hb_is_base_of = hb_is_convertible<hb_decay<Derived> , hb_decay<Base> >;
	#define hb_is_base_of(Base,Derived) hb_is_base_of<Base, Derived>::value

	template <typename From, typename To>
	using hb_is_cr_convertible = hb_bool_constant<
	hb_is_same (hb_decay<From>, hb_decay<To>) &&
	(!hb_is_const (From) \|\| hb_is_const (To)) &&
	(!hb_is_reference (To) \|\| hb_is_const (To) \|\| hb_is_reference (To))
	>;
	#define hb_is_cr_convertible(From,To) hb_is_cr_convertible<From, To>::value

	/* std::move and std::forward */

	template <typename T>
	static constexpr hb_remove_reference<T>&& hb_move (T&& t) { return (hb_remove_reference<T>&&) (t); }

	template <typename T>
	static constexpr T&& hb_forward (hb_remove_reference<T>& t) { return (T&&) t; }
	template <typename T>
	static constexpr T&& hb_forward (hb_remove_reference<T>&& t) { return (T&&) t; }

	struct
	{
	template <typename T> constexpr auto
	operator () (T&& v) const HB_AUTO_RETURN (hb_forward<T> (v))

	template <typename T> constexpr auto
	operator () (T v) const HB_AUTO_RETURN (v)
	}
	HB_FUNCOBJ (hb_deref);

	struct
	{
	template <typename T> constexpr auto
	operator () (T&& v) const HB_AUTO_RETURN (hb_forward<T> (v))

	template <typename T> constexpr auto
	operator () (T& v) const HB_AUTO_RETURN (hb_addressof (v))
	}
	HB_FUNCOBJ (hb_ref);

	template <typename T>
	struct hb_reference_wrapper
	{
	hb_reference_wrapper (T v) : v (v) {}
	bool operator == (const hb_reference_wrapper& o) const { return v == o.v; }
	bool operator != (const hb_reference_wrapper& o) const { return v != o.v; }
	operator T () const { return v; }
	T get () const { return v; }
	T v;
	};
	template <typename T>
	struct hb_reference_wrapper<T&>
	{
	hb_reference_wrapper (T& v) : v (hb_addressof (v)) {}
	bool operator == (const hb_reference_wrapper& o) const { return v == o.v; }
	bool operator != (const hb_reference_wrapper& o) const { return v != o.v; }
	operator T& () const { return *v; }
	T& get () const { return *v; }
	T* v;
	};


	/* Type traits */

	template <typename T>
	using hb_is_integral = hb_bool_constant<
	hb_is_same (hb_decay<T>, char) \|\|
	hb_is_same (hb_decay<T>, signed char) \|\|
	hb_is_same (hb_decay<T>, unsigned char) \|\|
	hb_is_same (hb_decay<T>, signed int) \|\|
	hb_is_same (hb_decay<T>, unsigned int) \|\|
	hb_is_same (hb_decay<T>, signed short) \|\|
	hb_is_same (hb_decay<T>, unsigned short) \|\|
	hb_is_same (hb_decay<T>, signed long) \|\|
	hb_is_same (hb_decay<T>, unsigned long) \|\|
	hb_is_same (hb_decay<T>, signed long long) \|\|
	hb_is_same (hb_decay<T>, unsigned long long) \|\|
	false
	>;
	#define hb_is_integral(T) hb_is_integral<T>::value
	template <typename T>
	using hb_is_floating_point = hb_bool_constant<
	hb_is_same (hb_decay<T>, float) \|\|
	hb_is_same (hb_decay<T>, double) \|\|
	hb_is_same (hb_decay<T>, long double) \|\|
	false
	>;
	#define hb_is_floating_point(T) hb_is_floating_point<T>::value
	template <typename T>
	using hb_is_arithmetic = hb_bool_constant<
	hb_is_integral (T) \|\|
	hb_is_floating_point (T) \|\|
	false
	>;
	#define hb_is_arithmetic(T) hb_is_arithmetic<T>::value


	template <typename T, bool is_arithmetic> struct hb_is_signed_;
	template <typename T> struct hb_is_signed_<T, false> : hb_false_type {};
	template <typename T> struct hb_is_signed_<T, true> : hb_bool_constant<(T) -1 < (T) 0> {};
	template <typename T> struct hb_is_signed : hb_is_signed_<T, hb_is_arithmetic (T)> {};
	#define hb_is_signed(T) hb_is_signed<T>::value
	template <typename T, bool is_arithmetic> struct hb_is_unsigned_;
	template <typename T> struct hb_is_unsigned_<T, false> : hb_false_type {};
	template <typename T> struct hb_is_unsigned_<T, true> : hb_bool_constant<(T) 0 < (T) -1> {};
	template <typename T> struct hb_is_unsigned : hb_is_unsigned_<T, hb_is_arithmetic (T)> {};
	#define hb_is_unsigned(T) hb_is_unsigned<T>::value

	template <typename T> struct hb_int_min;
	template <> struct hb_int_min<char> : hb_integral_constant<char, CHAR_MIN> {};
	template <> struct hb_int_min<signed char> : hb_integral_constant<signed char, SCHAR_MIN> {};
	template <> struct hb_int_min<unsigned char> : hb_integral_constant<unsigned char, 0> {};
	template <> struct hb_int_min<signed short> : hb_integral_constant<signed short, SHRT_MIN> {};
	template <> struct hb_int_min<unsigned short> : hb_integral_constant<unsigned short, 0> {};
	template <> struct hb_int_min<signed int> : hb_integral_constant<signed int, INT_MIN> {};
	template <> struct hb_int_min<unsigned int> : hb_integral_constant<unsigned int, 0> {};
	template <> struct hb_int_min<signed long> : hb_integral_constant<signed long, LONG_MIN> {};
	template <> struct hb_int_min<unsigned long> : hb_integral_constant<unsigned long, 0> {};
	template <> struct hb_int_min<signed long long> : hb_integral_constant<signed long long, LLONG_MIN> {};
	template <> struct hb_int_min<unsigned long long> : hb_integral_constant<unsigned long long, 0> {};
	template <typename T> struct hb_int_min<T > : hb_integral_constant<T , nullptr> {};
	#define hb_int_min(T) hb_int_min<T>::value
	template <typename T> struct hb_int_max;
	template <> struct hb_int_max<char> : hb_integral_constant<char, CHAR_MAX> {};
	template <> struct hb_int_max<signed char> : hb_integral_constant<signed char, SCHAR_MAX> {};
	template <> struct hb_int_max<unsigned char> : hb_integral_constant<unsigned char, UCHAR_MAX> {};
	template <> struct hb_int_max<signed short> : hb_integral_constant<signed short, SHRT_MAX> {};
	template <> struct hb_int_max<unsigned short> : hb_integral_constant<unsigned short, USHRT_MAX> {};
	template <> struct hb_int_max<signed int> : hb_integral_constant<signed int, INT_MAX> {};
	template <> struct hb_int_max<unsigned int> : hb_integral_constant<unsigned int, UINT_MAX> {};
	template <> struct hb_int_max<signed long> : hb_integral_constant<signed long, LONG_MAX> {};
	template <> struct hb_int_max<unsigned long> : hb_integral_constant<unsigned long, ULONG_MAX> {};
	template <> struct hb_int_max<signed long long> : hb_integral_constant<signed long long, LLONG_MAX> {};
	template <> struct hb_int_max<unsigned long long> : hb_integral_constant<unsigned long long, ULLONG_MAX> {};
	#define hb_int_max(T) hb_int_max<T>::value


	/* Class traits. */

	#define HB_DELETE_COPY_ASSIGN(TypeName) \
	TypeName(const TypeName&) = delete; \
	void operator=(const TypeName&) = delete
	#define HB_DELETE_CREATE_COPY_ASSIGN(TypeName) \
	TypeName() = delete; \
	TypeName(const TypeName&) = delete; \
	void operator=(const TypeName&) = delete

	template <typename T, typename>
	struct _hb_is_destructible : hb_false_type {};
	template <typename T>
	struct _hb_is_destructible<T, hb_void_t<decltype (hb_declval (T).~T ())>> : hb_true_type {};
	template <typename T>
	using hb_is_destructible = _hb_is_destructible<T, void>;
	#define hb_is_destructible(T) hb_is_destructible<T>::value

	template <typename T, typename, typename ...Ts>
	struct _hb_is_constructible : hb_false_type {};
	template <typename T, typename ...Ts>
	struct _hb_is_constructible<T, hb_void_t<decltype (T (hb_declval (Ts)...))>, Ts...> : hb_true_type {};
	template <typename T, typename ...Ts>
	using hb_is_constructible = _hb_is_constructible<T, void, Ts...>;
	#define hb_is_constructible(...) hb_is_constructible<__VA_ARGS__>::value

	template <typename T>
	using hb_is_default_constructible = hb_is_constructible<T>;
	#define hb_is_default_constructible(T) hb_is_default_constructible<T>::value

	template <typename T>
	using hb_is_copy_constructible = hb_is_constructible<T, hb_add_lvalue_reference<hb_add_const<T>>>;
	#define hb_is_copy_constructible(T) hb_is_copy_constructible<T>::value

	template <typename T>
	using hb_is_move_constructible = hb_is_constructible<T, hb_add_rvalue_reference<hb_add_const<T>>>;
	#define hb_is_move_constructible(T) hb_is_move_constructible<T>::value

	template <typename T, typename U, typename>
	struct _hb_is_assignable : hb_false_type {};
	template <typename T, typename U>
	struct _hb_is_assignable<T, U, hb_void_t<decltype (hb_declval (T) = hb_declval (U))>> : hb_true_type {};
	template <typename T, typename U>
	using hb_is_assignable = _hb_is_assignable<T, U, void>;
	#define hb_is_assignable(T,U) hb_is_assignable<T, U>::value

	template <typename T>
	using hb_is_copy_assignable = hb_is_assignable<hb_add_lvalue_reference<T>,
	hb_add_lvalue_reference<hb_add_const<T>>>;
	#define hb_is_copy_assignable(T) hb_is_copy_assignable<T>::value

	template <typename T>
	using hb_is_move_assignable = hb_is_assignable<hb_add_lvalue_reference<T>,
	hb_add_rvalue_reference<T>>;
	#define hb_is_move_assignable(T) hb_is_move_assignable<T>::value

	/* Trivial versions. */

	template <typename T> union hb_trivial { T value; };

	template <typename T>
	using hb_is_trivially_destructible= hb_is_destructible<hb_trivial<T>>;
	#define hb_is_trivially_destructible(T) hb_is_trivially_destructible<T>::value

	/* Don't know how to do the following. */
	//template <typename T, typename ...Ts>
	//using hb_is_trivially_constructible= hb_is_constructible<hb_trivial<T>, hb_trivial<Ts>...>;
	//#define hb_is_trivially_constructible(...) hb_is_trivially_constructible<__VA_ARGS__>::value

	template <typename T>
	using hb_is_trivially_default_constructible= hb_is_default_constructible<hb_trivial<T>>;
	#define hb_is_trivially_default_constructible(T) hb_is_trivially_default_constructible<T>::value

	template <typename T>
	using hb_is_trivially_copy_constructible= hb_is_copy_constructible<hb_trivial<T>>;
	#define hb_is_trivially_copy_constructible(T) hb_is_trivially_copy_constructible<T>::value

	template <typename T>
	using hb_is_trivially_move_constructible= hb_is_move_constructible<hb_trivial<T>>;
	#define hb_is_trivially_move_constructible(T) hb_is_trivially_move_constructible<T>::value

	/* Don't know how to do the following. */
	//template <typename T, typename U>
	//using hb_is_trivially_assignable= hb_is_assignable<hb_trivial<T>, hb_trivial<U>>;
	//#define hb_is_trivially_assignable(T,U) hb_is_trivially_assignable<T, U>::value

	template <typename T>
	using hb_is_trivially_copy_assignable= hb_is_copy_assignable<hb_trivial<T>>;
	#define hb_is_trivially_copy_assignable(T) hb_is_trivially_copy_assignable<T>::value

	template <typename T>
	using hb_is_trivially_move_assignable= hb_is_move_assignable<hb_trivial<T>>;
	#define hb_is_trivially_move_assignable(T) hb_is_trivially_move_assignable<T>::value

	template <typename T>
	using hb_is_trivially_copyable= hb_bool_constant<
	hb_is_trivially_destructible (T) &&
	(!hb_is_move_assignable (T) \|\| hb_is_trivially_move_assignable (T)) &&
	(!hb_is_move_constructible (T) \|\| hb_is_trivially_move_constructible (T)) &&
	(!hb_is_copy_assignable (T) \|\| hb_is_trivially_copy_assignable (T)) &&
	(!hb_is_copy_constructible (T) \|\| hb_is_trivially_copy_constructible (T)) &&
	true
	>;
	#define hb_is_trivially_copyable(T) hb_is_trivially_copyable<T>::value

	template <typename T>
	using hb_is_trivial= hb_bool_constant<
	hb_is_trivially_copyable (T) &&
	hb_is_trivially_default_constructible (T)
	>;
	#define hb_is_trivial(T) hb_is_trivial<T>::value

	/* hb_unwrap_type (T)
	* If T has no T::type, returns T. Otherwise calls itself on T::type recursively.
	*/

	template <typename T, typename>
	struct _hb_unwrap_type : hb_type_identity_t<T> {};
	template <typename T>
	struct _hb_unwrap_type<T, hb_void_t<typename T::type>> : _hb_unwrap_type<typename T::type, void> {};
	template <typename T>
	using hb_unwrap_type = _hb_unwrap_type<T, void>;
	#define hb_unwrap_type(T) typename hb_unwrap_type<T>::type

	#endif /* HB_META_HH */