experimental/bits/numeric_traits.h

// Definition of numeric_limits replacement traits P1841R1 -*- C++ -*-

// Copyright (C) 2020-2021 Free Software Foundation, Inc.
//
// This file is part of the GNU ISO C++ Library.  This library is free
// software; you can redistribute it and/or modify it under the
// terms of the GNU General Public License as published by the
// Free Software Foundation; either version 3, or (at your option)
// any later version.

// This library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
// GNU General Public License for more details.

// Under Section 7 of GPL version 3, you are granted additional
// permissions described in the GCC Runtime Library Exception, version
// 3.1, as published by the Free Software Foundation.

// You should have received a copy of the GNU General Public License and
// a copy of the GCC Runtime Library Exception along with this program;
// see the files COPYING3 and COPYING.RUNTIME respectively.  If not, see
// <http://www.gnu.org/licenses/>.

#include <type_traits>

namespace std {

template <template <typename> class _Trait, typename _Tp, typename = void>
  struct __value_exists_impl : false_type {};

template <template <typename> class _Trait, typename _Tp>
  struct __value_exists_impl<_Trait, _Tp, void_t<decltype(_Trait<_Tp>::value)>>
  : true_type {};

template <typename _Tp, bool = is_arithmetic_v<_Tp>>
  struct __digits_impl {};

template <typename _Tp>
  struct __digits_impl<_Tp, true>
  {
    static inline constexpr int value
      = sizeof(_Tp) * __CHAR_BIT__ - is_signed_v<_Tp>;
  };

template <>
  struct __digits_impl<float, true>
  { static inline constexpr int value = __FLT_MANT_DIG__; };

template <>
  struct __digits_impl<double, true>
  { static inline constexpr int value = __DBL_MANT_DIG__; };

template <>
  struct __digits_impl<long double, true>
  { static inline constexpr int value = __LDBL_MANT_DIG__; };

template <typename _Tp, bool = is_arithmetic_v<_Tp>>
  struct __digits10_impl {};

template <typename _Tp>
  struct __digits10_impl<_Tp, true>
  {
    // The fraction 643/2136 approximates log10(2) to 7 significant digits.
    static inline constexpr int value = __digits_impl<_Tp>::value * 643L / 2136;
  };

template <>
  struct __digits10_impl<float, true>
  { static inline constexpr int value = __FLT_DIG__; };

template <>
  struct __digits10_impl<double, true>
  { static inline constexpr int value = __DBL_DIG__; };

template <>
  struct __digits10_impl<long double, true>
  { static inline constexpr int value = __LDBL_DIG__; };

template <typename _Tp, bool = is_arithmetic_v<_Tp>>
  struct __max_digits10_impl {};

template <typename _Tp>
  struct __max_digits10_impl<_Tp, true>
  {
    static inline constexpr int value
      = is_floating_point_v<_Tp> ? 2 + __digits_impl<_Tp>::value * 643L / 2136
                                 : __digits10_impl<_Tp>::value + 1;
  };

template <typename _Tp>
  struct __max_exponent_impl {};

template <>
  struct __max_exponent_impl<float>
  { static inline constexpr int value = __FLT_MAX_EXP__; };

template <>
  struct __max_exponent_impl<double>
  { static inline constexpr int value = __DBL_MAX_EXP__; };

template <>
  struct __max_exponent_impl<long double>
  { static inline constexpr int value = __LDBL_MAX_EXP__; };

template <typename _Tp>
  struct __max_exponent10_impl {};

template <>
  struct __max_exponent10_impl<float>
  { static inline constexpr int value = __FLT_MAX_10_EXP__; };

template <>
  struct __max_exponent10_impl<double>
  { static inline constexpr int value = __DBL_MAX_10_EXP__; };

template <>
  struct __max_exponent10_impl<long double>
  { static inline constexpr int value = __LDBL_MAX_10_EXP__; };

template <typename _Tp>
  struct __min_exponent_impl {};

template <>
  struct __min_exponent_impl<float>
  { static inline constexpr int value = __FLT_MIN_EXP__; };

template <>
  struct __min_exponent_impl<double>
  { static inline constexpr int value = __DBL_MIN_EXP__; };

template <>
  struct __min_exponent_impl<long double>
  { static inline constexpr int value = __LDBL_MIN_EXP__; };

template <typename _Tp>
  struct __min_exponent10_impl {};

template <>
  struct __min_exponent10_impl<float>
  { static inline constexpr int value = __FLT_MIN_10_EXP__; };

template <>
  struct __min_exponent10_impl<double>
  { static inline constexpr int value = __DBL_MIN_10_EXP__; };

template <>
  struct __min_exponent10_impl<long double>
  { static inline constexpr int value = __LDBL_MIN_10_EXP__; };

template <typename _Tp, bool = is_arithmetic_v<_Tp>>
  struct __radix_impl {};

template <typename _Tp>
  struct __radix_impl<_Tp, true>
  {
    static inline constexpr int value
      = is_floating_point_v<_Tp> ? __FLT_RADIX__ : 2;
  };

// [num.traits.util], numeric utility traits
template <template <typename> class _Trait, typename _Tp>
  struct __value_exists : __value_exists_impl<_Trait, _Tp> {};

template <template <typename> class _Trait, typename _Tp>
  inline constexpr bool __value_exists_v = __value_exists<_Trait, _Tp>::value;

template <template <typename> class _Trait, typename _Tp, typename _Up = _Tp>
  inline constexpr _Up
  __value_or(_Up __def = _Up()) noexcept
  {
    if constexpr (__value_exists_v<_Trait, _Tp>)
      return static_cast<_Up>(_Trait<_Tp>::value);
    else
      return __def;
  }

template <typename _Tp, bool = is_arithmetic_v<_Tp>>
  struct __norm_min_impl {};

template <typename _Tp>
  struct __norm_min_impl<_Tp, true>
  { static inline constexpr _Tp value = 1; };

template <>
  struct __norm_min_impl<float, true>
  { static inline constexpr float value = __FLT_MIN__; };

template <>
  struct __norm_min_impl<double, true>
  { static inline constexpr double value = __DBL_MIN__; };

template <>
  struct __norm_min_impl<long double, true>
  { static inline constexpr long double value = __LDBL_MIN__; };

template <typename _Tp>
  struct __denorm_min_impl : __norm_min_impl<_Tp> {};

#if __FLT_HAS_DENORM__
template <>
  struct __denorm_min_impl<float>
  { static inline constexpr float value = __FLT_DENORM_MIN__; };
#endif

#if __DBL_HAS_DENORM__
template <>
  struct __denorm_min_impl<double>
  { static inline constexpr double value = __DBL_DENORM_MIN__; };
#endif

#if __LDBL_HAS_DENORM__
template <>
  struct __denorm_min_impl<long double>
  { static inline constexpr long double value = __LDBL_DENORM_MIN__; };
#endif

template <typename _Tp>
  struct __epsilon_impl {};

template <>
  struct __epsilon_impl<float>
  { static inline constexpr float value = __FLT_EPSILON__; };

template <>
  struct __epsilon_impl<double>
  { static inline constexpr double value = __DBL_EPSILON__; };

template <>
  struct __epsilon_impl<long double>
  { static inline constexpr long double value = __LDBL_EPSILON__; };

template <typename _Tp, bool = is_arithmetic_v<_Tp>>
  struct __finite_min_impl {};

template <typename _Tp>
  struct __finite_min_impl<_Tp, true>
  {
    static inline constexpr _Tp value
      = is_unsigned_v<_Tp> ? _Tp()
                           : -2 * (_Tp(1) << __digits_impl<_Tp>::value - 1);
  };

template <>
  struct __finite_min_impl<float, true>
  { static inline constexpr float value = -__FLT_MAX__; };

template <>
  struct __finite_min_impl<double, true>
  { static inline constexpr double value = -__DBL_MAX__; };

template <>
  struct __finite_min_impl<long double, true>
  { static inline constexpr long double value = -__LDBL_MAX__; };

template <typename _Tp, bool = is_arithmetic_v<_Tp>>
  struct __finite_max_impl {};

template <typename _Tp>
  struct __finite_max_impl<_Tp, true>
  { static inline constexpr _Tp value = ~__finite_min_impl<_Tp>::value; };

template <>
  struct __finite_max_impl<float, true>
  { static inline constexpr float value = __FLT_MAX__; };

template <>
  struct __finite_max_impl<double, true>
  { static inline constexpr double value = __DBL_MAX__; };

template <>
  struct __finite_max_impl<long double, true>
  { static inline constexpr long double value = __LDBL_MAX__; };

template <typename _Tp>
  struct __infinity_impl {};

#if __FLT_HAS_INFINITY__
template <>
  struct __infinity_impl<float>
  { static inline constexpr float value = __builtin_inff(); };
#endif

#if __DBL_HAS_INFINITY__
template <>
  struct __infinity_impl<double>
  { static inline constexpr double value = __builtin_inf(); };
#endif

#if __LDBL_HAS_INFINITY__
template <>
  struct __infinity_impl<long double>
  { static inline constexpr long double value = __builtin_infl(); };
#endif

template <typename _Tp>
  struct __quiet_NaN_impl {};

#if __FLT_HAS_QUIET_NAN__
template <>
  struct __quiet_NaN_impl<float>
  { static inline constexpr float value = __builtin_nanf(""); };
#endif

#if __DBL_HAS_QUIET_NAN__
template <>
  struct __quiet_NaN_impl<double>
  { static inline constexpr double value = __builtin_nan(""); };
#endif

#if __LDBL_HAS_QUIET_NAN__
template <>
  struct __quiet_NaN_impl<long double>
  { static inline constexpr long double value = __builtin_nanl(""); };
#endif

template <typename _Tp, bool = is_floating_point_v<_Tp>>
  struct __reciprocal_overflow_threshold_impl {};

template <typename _Tp>
  struct __reciprocal_overflow_threshold_impl<_Tp, true>
  {
    // This typically yields a subnormal value. Is this incorrect for
    // flush-to-zero configurations?
    static constexpr _Tp _S_search(_Tp __ok, _Tp __overflows)
    {
      const _Tp __mid = (__ok + __overflows) / 2;
      // 1/__mid without -ffast-math is not a constant expression if it
      // overflows. Therefore divide 1 by the radix before division.
      // Consequently finite_max (the threshold) must be scaled by the
      // same value.
      if (__mid == __ok || __mid == __overflows)
        return __ok;
      else if (_Tp(1) / (__radix_impl<_Tp>::value * __mid)
               <= __finite_max_impl<_Tp>::value / __radix_impl<_Tp>::value)
        return _S_search(__mid, __overflows);
      else
        return _S_search(__ok, __mid);
    }

    static inline constexpr _Tp value
      = _S_search(_Tp(1.01) / __finite_max_impl<_Tp>::value,
                  _Tp(0.99) / __finite_max_impl<_Tp>::value);
  };

template <typename _Tp, bool = is_floating_point_v<_Tp>>
  struct __round_error_impl {};

template <typename _Tp>
  struct __round_error_impl<_Tp, true>
  { static inline constexpr _Tp value = 0.5; };

template <typename _Tp>
  struct __signaling_NaN_impl {};

#if __FLT_HAS_QUIET_NAN__
template <>
  struct __signaling_NaN_impl<float>
  { static inline constexpr float value = __builtin_nansf(""); };
#endif

#if __DBL_HAS_QUIET_NAN__
template <>
  struct __signaling_NaN_impl<double>
  { static inline constexpr double value = __builtin_nans(""); };
#endif

#if __LDBL_HAS_QUIET_NAN__
template <>
  struct __signaling_NaN_impl<long double>
  { static inline constexpr long double value = __builtin_nansl(""); };
#endif

// [num.traits.val], numeric distinguished value traits
template <typename _Tp>
  struct __denorm_min : __denorm_min_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  struct __epsilon : __epsilon_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  struct __finite_max : __finite_max_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  struct __finite_min : __finite_min_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  struct __infinity : __infinity_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  struct __norm_min : __norm_min_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  struct __quiet_NaN : __quiet_NaN_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  struct __reciprocal_overflow_threshold
  : __reciprocal_overflow_threshold_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  struct __round_error : __round_error_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  struct __signaling_NaN : __signaling_NaN_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  inline constexpr auto __denorm_min_v = __denorm_min<_Tp>::value;

template <typename _Tp>
  inline constexpr auto __epsilon_v = __epsilon<_Tp>::value;

template <typename _Tp>
  inline constexpr auto __finite_max_v = __finite_max<_Tp>::value;

template <typename _Tp>
  inline constexpr auto __finite_min_v = __finite_min<_Tp>::value;

template <typename _Tp>
  inline constexpr auto __infinity_v = __infinity<_Tp>::value;

template <typename _Tp>
  inline constexpr auto __norm_min_v = __norm_min<_Tp>::value;

template <typename _Tp>
  inline constexpr auto __quiet_NaN_v = __quiet_NaN<_Tp>::value;

template <typename _Tp>
  inline constexpr auto __reciprocal_overflow_threshold_v
    = __reciprocal_overflow_threshold<_Tp>::value;

template <typename _Tp>
  inline constexpr auto __round_error_v = __round_error<_Tp>::value;

template <typename _Tp>
  inline constexpr auto __signaling_NaN_v = __signaling_NaN<_Tp>::value;

// [num.traits.char], numeric characteristics traits
template <typename _Tp>
  struct __digits : __digits_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  struct __digits10 : __digits10_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  struct __max_digits10 : __max_digits10_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  struct __max_exponent : __max_exponent_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  struct __max_exponent10 : __max_exponent10_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  struct __min_exponent : __min_exponent_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  struct __min_exponent10 : __min_exponent10_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  struct __radix : __radix_impl<remove_cv_t<_Tp>> {};

template <typename _Tp>
  inline constexpr auto __digits_v = __digits<_Tp>::value;

template <typename _Tp>
  inline constexpr auto __digits10_v = __digits10<_Tp>::value;

template <typename _Tp>
  inline constexpr auto __max_digits10_v = __max_digits10<_Tp>::value;

template <typename _Tp>
  inline constexpr auto __max_exponent_v = __max_exponent<_Tp>::value;

template <typename _Tp>
  inline constexpr auto __max_exponent10_v = __max_exponent10<_Tp>::value;

template <typename _Tp>
  inline constexpr auto __min_exponent_v = __min_exponent<_Tp>::value;

template <typename _Tp>
  inline constexpr auto __min_exponent10_v = __min_exponent10<_Tp>::value;

template <typename _Tp>
  inline constexpr auto __radix_v = __radix<_Tp>::value;

// mkretz's extensions
// TODO: does GCC tell me? __GCC_IEC_559 >= 2 is not the right answer
template <typename _Tp>
  struct __has_iec559_storage_format : true_type {};

template <typename _Tp>
  inline constexpr bool __has_iec559_storage_format_v
    = __has_iec559_storage_format<_Tp>::value;

/* To propose:
   If __has_iec559_behavior<__quiet_NaN, T> is true the following holds:
     - nan == nan is false
     - isnan(nan) is true
     - isnan(nan + x) is true
     - isnan(inf/inf) is true
     - isnan(0/0) is true
     - isunordered(nan, x) is true

   If __has_iec559_behavior<__infinity, T> is true the following holds (x is
   neither nan nor inf):
     - isinf(inf) is true
     - isinf(inf + x) is true
     - isinf(1/0) is true
 */
template <template <typename> class _Trait, typename _Tp>
  struct __has_iec559_behavior : false_type {};

template <template <typename> class _Trait, typename _Tp>
  inline constexpr bool __has_iec559_behavior_v
    = __has_iec559_behavior<_Trait, _Tp>::value;

#if !__FINITE_MATH_ONLY__
#if __FLT_HAS_QUIET_NAN__
template <>
  struct __has_iec559_behavior<__quiet_NaN, float> : true_type {};
#endif

#if __DBL_HAS_QUIET_NAN__
template <>
  struct __has_iec559_behavior<__quiet_NaN, double> : true_type {};
#endif

#if __LDBL_HAS_QUIET_NAN__
template <>
  struct __has_iec559_behavior<__quiet_NaN, long double> : true_type {};
#endif

#if __FLT_HAS_INFINITY__
template <>
  struct __has_iec559_behavior<__infinity, float> : true_type {};
#endif

#if __DBL_HAS_INFINITY__
template <>
  struct __has_iec559_behavior<__infinity, double> : true_type {};
#endif

#if __LDBL_HAS_INFINITY__
template <>
  struct __has_iec559_behavior<__infinity, long double> : true_type {};
#endif

#ifdef __SUPPORT_SNAN__
#if __FLT_HAS_QUIET_NAN__
template <>
  struct __has_iec559_behavior<__signaling_NaN, float> : true_type {};
#endif

#if __DBL_HAS_QUIET_NAN__
template <>
  struct __has_iec559_behavior<__signaling_NaN, double> : true_type {};
#endif

#if __LDBL_HAS_QUIET_NAN__
template <>
  struct __has_iec559_behavior<__signaling_NaN, long double> : true_type {};
#endif

#endif
#endif // __FINITE_MATH_ONLY__

} // namespace std
Revision:	1166
Committed:	Tue Oct 26 14:22:36 2021 UTC (4 years ago) by rossy
Content type:	text/x-chdr
File size:	16452 byte(s)
Log Message:	Daodan: Replace MinGW build env with an up-to-date MSYS2 env
#	Content
1	// Definition of numeric_limits replacement traits P1841R1 -- C++ --
2
3	// Copyright (C) 2020-2021 Free Software Foundation, Inc.
4	//
5	// This file is part of the GNU ISO C++ Library. This library is free
6	// software; you can redistribute it and/or modify it under the
7	// terms of the GNU General Public License as published by the
8	// Free Software Foundation; either version 3, or (at your option)
9	// any later version.
10
11	// This library is distributed in the hope that it will be useful,
12	// but WITHOUT ANY WARRANTY; without even the implied warranty of
13	// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14	// GNU General Public License for more details.
15
16	// Under Section 7 of GPL version 3, you are granted additional
17	// permissions described in the GCC Runtime Library Exception, version
18	// 3.1, as published by the Free Software Foundation.
19
20	// You should have received a copy of the GNU General Public License and
21	// a copy of the GCC Runtime Library Exception along with this program;
22	// see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
23	// <http://www.gnu.org/licenses/>.
24
25	#include <type_traits>
26
27	namespace std {
28
29	template <template <typename> class _Trait, typename _Tp, typename = void>
30	struct __value_exists_impl : false_type {};
31
32	template <template <typename> class _Trait, typename _Tp>
33	struct __value_exists_impl<_Trait, _Tp, void_t<decltype(_Trait<_Tp>::value)>>
34	: true_type {};
35
36	template <typename _Tp, bool = is_arithmetic_v<_Tp>>
37	struct __digits_impl {};
38
39	template <typename _Tp>
40	struct __digits_impl<_Tp, true>
41	{
42	static inline constexpr int value
43	= sizeof(_Tp) * __CHAR_BIT__ - is_signed_v<_Tp>;
44	};
45
46	template <>
47	struct __digits_impl<float, true>
48	{ static inline constexpr int value = __FLT_MANT_DIG__; };
49
50	template <>
51	struct __digits_impl<double, true>
52	{ static inline constexpr int value = __DBL_MANT_DIG__; };
53
54	template <>
55	struct __digits_impl<long double, true>
56	{ static inline constexpr int value = __LDBL_MANT_DIG__; };
57
58	template <typename _Tp, bool = is_arithmetic_v<_Tp>>
59	struct __digits10_impl {};
60
61	template <typename _Tp>
62	struct __digits10_impl<_Tp, true>
63	{
64	// The fraction 643/2136 approximates log10(2) to 7 significant digits.
65	static inline constexpr int value = __digits_impl<_Tp>::value * 643L / 2136;
66	};
67
68	template <>
69	struct __digits10_impl<float, true>
70	{ static inline constexpr int value = __FLT_DIG__; };
71
72	template <>
73	struct __digits10_impl<double, true>
74	{ static inline constexpr int value = __DBL_DIG__; };
75
76	template <>
77	struct __digits10_impl<long double, true>
78	{ static inline constexpr int value = __LDBL_DIG__; };
79
80	template <typename _Tp, bool = is_arithmetic_v<_Tp>>
81	struct __max_digits10_impl {};
82
83	template <typename _Tp>
84	struct __max_digits10_impl<_Tp, true>
85	{
86	static inline constexpr int value
87	= is_floating_point_v<_Tp> ? 2 + __digits_impl<_Tp>::value * 643L / 2136
88	: __digits10_impl<_Tp>::value + 1;
89	};
90
91	template <typename _Tp>
92	struct __max_exponent_impl {};
93
94	template <>
95	struct __max_exponent_impl<float>
96	{ static inline constexpr int value = __FLT_MAX_EXP__; };
97
98	template <>
99	struct __max_exponent_impl<double>
100	{ static inline constexpr int value = __DBL_MAX_EXP__; };
101
102	template <>
103	struct __max_exponent_impl<long double>
104	{ static inline constexpr int value = __LDBL_MAX_EXP__; };
105
106	template <typename _Tp>
107	struct __max_exponent10_impl {};
108
109	template <>
110	struct __max_exponent10_impl<float>
111	{ static inline constexpr int value = __FLT_MAX_10_EXP__; };
112
113	template <>
114	struct __max_exponent10_impl<double>
115	{ static inline constexpr int value = __DBL_MAX_10_EXP__; };
116
117	template <>
118	struct __max_exponent10_impl<long double>
119	{ static inline constexpr int value = __LDBL_MAX_10_EXP__; };
120
121	template <typename _Tp>
122	struct __min_exponent_impl {};
123
124	template <>
125	struct __min_exponent_impl<float>
126	{ static inline constexpr int value = __FLT_MIN_EXP__; };
127
128	template <>
129	struct __min_exponent_impl<double>
130	{ static inline constexpr int value = __DBL_MIN_EXP__; };
131
132	template <>
133	struct __min_exponent_impl<long double>
134	{ static inline constexpr int value = __LDBL_MIN_EXP__; };
135
136	template <typename _Tp>
137	struct __min_exponent10_impl {};
138
139	template <>
140	struct __min_exponent10_impl<float>
141	{ static inline constexpr int value = __FLT_MIN_10_EXP__; };
142
143	template <>
144	struct __min_exponent10_impl<double>
145	{ static inline constexpr int value = __DBL_MIN_10_EXP__; };
146
147	template <>
148	struct __min_exponent10_impl<long double>
149	{ static inline constexpr int value = __LDBL_MIN_10_EXP__; };
150
151	template <typename _Tp, bool = is_arithmetic_v<_Tp>>
152	struct __radix_impl {};
153
154	template <typename _Tp>
155	struct __radix_impl<_Tp, true>
156	{
157	static inline constexpr int value
158	= is_floating_point_v<_Tp> ? __FLT_RADIX__ : 2;
159	};
160
161	// [num.traits.util], numeric utility traits
162	template <template <typename> class _Trait, typename _Tp>
163	struct __value_exists : __value_exists_impl<_Trait, _Tp> {};
164
165	template <template <typename> class _Trait, typename _Tp>
166	inline constexpr bool __value_exists_v = __value_exists<_Trait, _Tp>::value;
167
168	template <template <typename> class _Trait, typename _Tp, typename _Up = _Tp>
169	inline constexpr _Up
170	__value_or(_Up __def = _Up()) noexcept
171	{
172	if constexpr (__value_exists_v<_Trait, _Tp>)
173	return static_cast<_Up>(_Trait<_Tp>::value);
174	else
175	return __def;
176	}
177
178	template <typename _Tp, bool = is_arithmetic_v<_Tp>>
179	struct __norm_min_impl {};
180
181	template <typename _Tp>
182	struct __norm_min_impl<_Tp, true>
183	{ static inline constexpr _Tp value = 1; };
184
185	template <>
186	struct __norm_min_impl<float, true>
187	{ static inline constexpr float value = __FLT_MIN__; };
188
189	template <>
190	struct __norm_min_impl<double, true>
191	{ static inline constexpr double value = __DBL_MIN__; };
192
193	template <>
194	struct __norm_min_impl<long double, true>
195	{ static inline constexpr long double value = __LDBL_MIN__; };
196
197	template <typename _Tp>
198	struct __denorm_min_impl : __norm_min_impl<_Tp> {};
199
200	#if __FLT_HAS_DENORM__
201	template <>
202	struct __denorm_min_impl<float>
203	{ static inline constexpr float value = __FLT_DENORM_MIN__; };
204	#endif
205
206	#if __DBL_HAS_DENORM__
207	template <>
208	struct __denorm_min_impl<double>
209	{ static inline constexpr double value = __DBL_DENORM_MIN__; };
210	#endif
211
212	#if __LDBL_HAS_DENORM__
213	template <>
214	struct __denorm_min_impl<long double>
215	{ static inline constexpr long double value = __LDBL_DENORM_MIN__; };
216	#endif
217
218	template <typename _Tp>
219	struct __epsilon_impl {};
220
221	template <>
222	struct __epsilon_impl<float>
223	{ static inline constexpr float value = __FLT_EPSILON__; };
224
225	template <>
226	struct __epsilon_impl<double>
227	{ static inline constexpr double value = __DBL_EPSILON__; };
228
229	template <>
230	struct __epsilon_impl<long double>
231	{ static inline constexpr long double value = __LDBL_EPSILON__; };
232
233	template <typename _Tp, bool = is_arithmetic_v<_Tp>>
234	struct __finite_min_impl {};
235
236	template <typename _Tp>
237	struct __finite_min_impl<_Tp, true>
238	{
239	static inline constexpr _Tp value
240	= is_unsigned_v<_Tp> ? _Tp()
241	: -2 * (_Tp(1) << __digits_impl<_Tp>::value - 1);
242	};
243
244	template <>
245	struct __finite_min_impl<float, true>
246	{ static inline constexpr float value = -__FLT_MAX__; };
247
248	template <>
249	struct __finite_min_impl<double, true>
250	{ static inline constexpr double value = -__DBL_MAX__; };
251
252	template <>
253	struct __finite_min_impl<long double, true>
254	{ static inline constexpr long double value = -__LDBL_MAX__; };
255
256	template <typename _Tp, bool = is_arithmetic_v<_Tp>>
257	struct __finite_max_impl {};
258
259	template <typename _Tp>
260	struct __finite_max_impl<_Tp, true>
261	{ static inline constexpr _Tp value = ~__finite_min_impl<_Tp>::value; };
262
263	template <>
264	struct __finite_max_impl<float, true>
265	{ static inline constexpr float value = __FLT_MAX__; };
266
267	template <>
268	struct __finite_max_impl<double, true>
269	{ static inline constexpr double value = __DBL_MAX__; };
270
271	template <>
272	struct __finite_max_impl<long double, true>
273	{ static inline constexpr long double value = __LDBL_MAX__; };
274
275	template <typename _Tp>
276	struct __infinity_impl {};
277
278	#if __FLT_HAS_INFINITY__
279	template <>
280	struct __infinity_impl<float>
281	{ static inline constexpr float value = __builtin_inff(); };
282	#endif
283
284	#if __DBL_HAS_INFINITY__
285	template <>
286	struct __infinity_impl<double>
287	{ static inline constexpr double value = __builtin_inf(); };
288	#endif
289
290	#if __LDBL_HAS_INFINITY__
291	template <>
292	struct __infinity_impl<long double>
293	{ static inline constexpr long double value = __builtin_infl(); };
294	#endif
295
296	template <typename _Tp>
297	struct __quiet_NaN_impl {};
298
299	#if __FLT_HAS_QUIET_NAN__
300	template <>
301	struct __quiet_NaN_impl<float>
302	{ static inline constexpr float value = __builtin_nanf(""); };
303	#endif
304
305	#if __DBL_HAS_QUIET_NAN__
306	template <>
307	struct __quiet_NaN_impl<double>
308	{ static inline constexpr double value = __builtin_nan(""); };
309	#endif
310
311	#if __LDBL_HAS_QUIET_NAN__
312	template <>
313	struct __quiet_NaN_impl<long double>
314	{ static inline constexpr long double value = __builtin_nanl(""); };
315	#endif
316
317	template <typename _Tp, bool = is_floating_point_v<_Tp>>
318	struct __reciprocal_overflow_threshold_impl {};
319
320	template <typename _Tp>
321	struct __reciprocal_overflow_threshold_impl<_Tp, true>
322	{
323	// This typically yields a subnormal value. Is this incorrect for
324	// flush-to-zero configurations?
325	static constexpr _Tp _S_search(_Tp __ok, _Tp __overflows)
326	{
327	const _Tp __mid = (__ok + __overflows) / 2;
328	// 1/__mid without -ffast-math is not a constant expression if it
329	// overflows. Therefore divide 1 by the radix before division.
330	// Consequently finite_max (the threshold) must be scaled by the
331	// same value.
332	if (__mid == __ok \|\| __mid == __overflows)
333	return __ok;
334	else if (_Tp(1) / (__radix_impl<_Tp>::value * __mid)
335	<= __finite_max_impl<_Tp>::value / __radix_impl<_Tp>::value)
336	return _S_search(__mid, __overflows);
337	else
338	return _S_search(__ok, __mid);
339	}
340
341	static inline constexpr _Tp value
342	= _S_search(_Tp(1.01) / __finite_max_impl<_Tp>::value,
343	_Tp(0.99) / __finite_max_impl<_Tp>::value);
344	};
345
346	template <typename _Tp, bool = is_floating_point_v<_Tp>>
347	struct __round_error_impl {};
348
349	template <typename _Tp>
350	struct __round_error_impl<_Tp, true>
351	{ static inline constexpr _Tp value = 0.5; };
352
353	template <typename _Tp>
354	struct __signaling_NaN_impl {};
355
356	#if __FLT_HAS_QUIET_NAN__
357	template <>
358	struct __signaling_NaN_impl<float>
359	{ static inline constexpr float value = __builtin_nansf(""); };
360	#endif
361
362	#if __DBL_HAS_QUIET_NAN__
363	template <>
364	struct __signaling_NaN_impl<double>
365	{ static inline constexpr double value = __builtin_nans(""); };
366	#endif
367
368	#if __LDBL_HAS_QUIET_NAN__
369	template <>
370	struct __signaling_NaN_impl<long double>
371	{ static inline constexpr long double value = __builtin_nansl(""); };
372	#endif
373
374	// [num.traits.val], numeric distinguished value traits
375	template <typename _Tp>
376	struct __denorm_min : __denorm_min_impl<remove_cv_t<_Tp>> {};
377
378	template <typename _Tp>
379	struct __epsilon : __epsilon_impl<remove_cv_t<_Tp>> {};
380
381	template <typename _Tp>
382	struct __finite_max : __finite_max_impl<remove_cv_t<_Tp>> {};
383
384	template <typename _Tp>
385	struct __finite_min : __finite_min_impl<remove_cv_t<_Tp>> {};
386
387	template <typename _Tp>
388	struct __infinity : __infinity_impl<remove_cv_t<_Tp>> {};
389
390	template <typename _Tp>
391	struct __norm_min : __norm_min_impl<remove_cv_t<_Tp>> {};
392
393	template <typename _Tp>
394	struct __quiet_NaN : __quiet_NaN_impl<remove_cv_t<_Tp>> {};
395
396	template <typename _Tp>
397	struct __reciprocal_overflow_threshold
398	: __reciprocal_overflow_threshold_impl<remove_cv_t<_Tp>> {};
399
400	template <typename _Tp>
401	struct __round_error : __round_error_impl<remove_cv_t<_Tp>> {};
402
403	template <typename _Tp>
404	struct __signaling_NaN : __signaling_NaN_impl<remove_cv_t<_Tp>> {};
405
406	template <typename _Tp>
407	inline constexpr auto __denorm_min_v = __denorm_min<_Tp>::value;
408
409	template <typename _Tp>
410	inline constexpr auto __epsilon_v = __epsilon<_Tp>::value;
411
412	template <typename _Tp>
413	inline constexpr auto __finite_max_v = __finite_max<_Tp>::value;
414
415	template <typename _Tp>
416	inline constexpr auto __finite_min_v = __finite_min<_Tp>::value;
417
418	template <typename _Tp>
419	inline constexpr auto __infinity_v = __infinity<_Tp>::value;
420
421	template <typename _Tp>
422	inline constexpr auto __norm_min_v = __norm_min<_Tp>::value;
423
424	template <typename _Tp>
425	inline constexpr auto __quiet_NaN_v = __quiet_NaN<_Tp>::value;
426
427	template <typename _Tp>
428	inline constexpr auto __reciprocal_overflow_threshold_v
429	= __reciprocal_overflow_threshold<_Tp>::value;
430
431	template <typename _Tp>
432	inline constexpr auto __round_error_v = __round_error<_Tp>::value;
433
434	template <typename _Tp>
435	inline constexpr auto __signaling_NaN_v = __signaling_NaN<_Tp>::value;
436
437	// [num.traits.char], numeric characteristics traits
438	template <typename _Tp>
439	struct __digits : __digits_impl<remove_cv_t<_Tp>> {};
440
441	template <typename _Tp>
442	struct __digits10 : __digits10_impl<remove_cv_t<_Tp>> {};
443
444	template <typename _Tp>
445	struct __max_digits10 : __max_digits10_impl<remove_cv_t<_Tp>> {};
446
447	template <typename _Tp>
448	struct __max_exponent : __max_exponent_impl<remove_cv_t<_Tp>> {};
449
450	template <typename _Tp>
451	struct __max_exponent10 : __max_exponent10_impl<remove_cv_t<_Tp>> {};
452
453	template <typename _Tp>
454	struct __min_exponent : __min_exponent_impl<remove_cv_t<_Tp>> {};
455
456	template <typename _Tp>
457	struct __min_exponent10 : __min_exponent10_impl<remove_cv_t<_Tp>> {};
458
459	template <typename _Tp>
460	struct __radix : __radix_impl<remove_cv_t<_Tp>> {};
461
462	template <typename _Tp>
463	inline constexpr auto __digits_v = __digits<_Tp>::value;
464
465	template <typename _Tp>
466	inline constexpr auto __digits10_v = __digits10<_Tp>::value;
467
468	template <typename _Tp>
469	inline constexpr auto __max_digits10_v = __max_digits10<_Tp>::value;
470
471	template <typename _Tp>
472	inline constexpr auto __max_exponent_v = __max_exponent<_Tp>::value;
473
474	template <typename _Tp>
475	inline constexpr auto __max_exponent10_v = __max_exponent10<_Tp>::value;
476
477	template <typename _Tp>
478	inline constexpr auto __min_exponent_v = __min_exponent<_Tp>::value;
479
480	template <typename _Tp>
481	inline constexpr auto __min_exponent10_v = __min_exponent10<_Tp>::value;
482
483	template <typename _Tp>
484	inline constexpr auto __radix_v = __radix<_Tp>::value;
485
486	// mkretz's extensions
487	// TODO: does GCC tell me? __GCC_IEC_559 >= 2 is not the right answer
488	template <typename _Tp>
489	struct __has_iec559_storage_format : true_type {};
490
491	template <typename _Tp>
492	inline constexpr bool __has_iec559_storage_format_v
493	= __has_iec559_storage_format<_Tp>::value;
494
495	/* To propose:
496	If __has_iec559_behavior<__quiet_NaN, T> is true the following holds:
497	- nan == nan is false
498	- isnan(nan) is true
499	- isnan(nan + x) is true
500	- isnan(inf/inf) is true
501	- isnan(0/0) is true
502	- isunordered(nan, x) is true
503
504	If __has_iec559_behavior<__infinity, T> is true the following holds (x is
505	neither nan nor inf):
506	- isinf(inf) is true
507	- isinf(inf + x) is true
508	- isinf(1/0) is true
509	*/
510	template <template <typename> class _Trait, typename _Tp>
511	struct __has_iec559_behavior : false_type {};
512
513	template <template <typename> class _Trait, typename _Tp>
514	inline constexpr bool __has_iec559_behavior_v
515	= __has_iec559_behavior<_Trait, _Tp>::value;
516
517	#if !__FINITE_MATH_ONLY__
518	#if __FLT_HAS_QUIET_NAN__
519	template <>
520	struct __has_iec559_behavior<__quiet_NaN, float> : true_type {};
521	#endif
522
523	#if __DBL_HAS_QUIET_NAN__
524	template <>
525	struct __has_iec559_behavior<__quiet_NaN, double> : true_type {};
526	#endif
527
528	#if __LDBL_HAS_QUIET_NAN__
529	template <>
530	struct __has_iec559_behavior<__quiet_NaN, long double> : true_type {};
531	#endif
532
533	#if __FLT_HAS_INFINITY__
534	template <>
535	struct __has_iec559_behavior<__infinity, float> : true_type {};
536	#endif
537
538	#if __DBL_HAS_INFINITY__
539	template <>
540	struct __has_iec559_behavior<__infinity, double> : true_type {};
541	#endif
542
543	#if __LDBL_HAS_INFINITY__
544	template <>
545	struct __has_iec559_behavior<__infinity, long double> : true_type {};
546	#endif
547
548	#ifdef __SUPPORT_SNAN__
549	#if __FLT_HAS_QUIET_NAN__
550	template <>
551	struct __has_iec559_behavior<__signaling_NaN, float> : true_type {};
552	#endif
553
554	#if __DBL_HAS_QUIET_NAN__
555	template <>
556	struct __has_iec559_behavior<__signaling_NaN, double> : true_type {};
557	#endif
558
559	#if __LDBL_HAS_QUIET_NAN__
560	template <>
561	struct __has_iec559_behavior<__signaling_NaN, long double> : true_type {};
562	#endif
563
564	#endif
565	#endif // __FINITE_MATH_ONLY__
566
567	} // namespace std