libstdc++-v3/include/std/ratio - gcc - Git at Google

 // ratio -*- C++ -*-

 // Copyright (C) 2008-2021 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/>.

 /** @file include/ratio
  *  This is a Standard C++ Library header.
  *  @ingroup ratio
  */

 #ifndef _GLIBCXX_RATIO
 #define _GLIBCXX_RATIO 1

 #pragma GCC system_header

 #if __cplusplus < 201103L
 # include <bits/c++0x_warning.h>
 #else

 #include <type_traits>
 #include <cstdint>		// intmax_t, uintmax_t

 namespace std _GLIBCXX_VISIBILITY(default)
 {
 _GLIBCXX_BEGIN_NAMESPACE_VERSION

   /**
    * @defgroup ratio Rational Arithmetic
    * @ingroup utilities
    *
    * Compile time representation of finite rational numbers.
    * @{
    */

   /// @cond undocumented

   template<intmax_t _Pn>
     struct __static_sign
     : integral_constant<intmax_t, (_Pn < 0) ? -1 : 1>
     { };

   template<intmax_t _Pn>
     struct __static_abs
     : integral_constant<intmax_t, _Pn * __static_sign<_Pn>::value>
     { };

   template<intmax_t _Pn, intmax_t _Qn>
     struct __static_gcd
     : __static_gcd<_Qn, (_Pn % _Qn)>
     { };

   template<intmax_t _Pn>
     struct __static_gcd<_Pn, 0>
     : integral_constant<intmax_t, __static_abs<_Pn>::value>
     { };

   template<intmax_t _Qn>
     struct __static_gcd<0, _Qn>
     : integral_constant<intmax_t, __static_abs<_Qn>::value>
     { };

   // Let c = 2^(half # of bits in an intmax_t)
   // then we find a1, a0, b1, b0 s.t. N = a1*c + a0, M = b1*c + b0
   // The multiplication of N and M becomes,
   // N * M = (a1 * b1)c^2 + (a0 * b1 + b0 * a1)c + a0 * b0
   // Multiplication is safe if each term and the sum of the terms
   // is representable by intmax_t.
   template<intmax_t _Pn, intmax_t _Qn>
     struct __safe_multiply
     {
     private:
       static const uintmax_t __c = uintmax_t(1) << (sizeof(intmax_t) * 4);

       static const uintmax_t __a0 = __static_abs<_Pn>::value % __c;
       static const uintmax_t __a1 = __static_abs<_Pn>::value / __c;
       static const uintmax_t __b0 = __static_abs<_Qn>::value % __c;
       static const uintmax_t __b1 = __static_abs<_Qn>::value / __c;

       static_assert(__a1 == 0 || __b1 == 0,
 		    "overflow in multiplication");
       static_assert(__a0 * __b1 + __b0 * __a1 < (__c >> 1),
 		    "overflow in multiplication");
       static_assert(__b0 * __a0 <= __INTMAX_MAX__,
 		    "overflow in multiplication");
       static_assert((__a0 * __b1 + __b0 * __a1) * __c
 		    <= __INTMAX_MAX__ -  __b0 * __a0,
 		    "overflow in multiplication");

     public:
       static const intmax_t value = _Pn * _Qn;
     };

   // Some double-precision utilities, where numbers are represented as
   // __hi*2^(8*sizeof(uintmax_t)) + __lo.
   template<uintmax_t __hi1, uintmax_t __lo1, uintmax_t __hi2, uintmax_t __lo2>
     struct __big_less
     : integral_constant<bool, (__hi1 < __hi2
 			       || (__hi1 == __hi2 && __lo1 < __lo2))>
     { };

   template<uintmax_t __hi1, uintmax_t __lo1, uintmax_t __hi2, uintmax_t __lo2>
     struct __big_add
     {
       static constexpr uintmax_t __lo = __lo1 + __lo2;
       static constexpr uintmax_t __hi = (__hi1 + __hi2 +
 					 (__lo1 + __lo2 < __lo1)); // carry
     };

   // Subtract a number from a bigger one.
   template<uintmax_t __hi1, uintmax_t __lo1, uintmax_t __hi2, uintmax_t __lo2>
     struct __big_sub
     {
       static_assert(!__big_less<__hi1, __lo1, __hi2, __lo2>::value,
 		    "Internal library error");
       static constexpr uintmax_t __lo = __lo1 - __lo2;
       static constexpr uintmax_t __hi = (__hi1 - __hi2 -
 					 (__lo1 < __lo2)); // carry
     };

   // Same principle as __safe_multiply.
   template<uintmax_t __x, uintmax_t __y>
     struct __big_mul
     {
     private:
       static constexpr uintmax_t __c = uintmax_t(1) << (sizeof(intmax_t) * 4);
       static constexpr uintmax_t __x0 = __x % __c;
       static constexpr uintmax_t __x1 = __x / __c;
       static constexpr uintmax_t __y0 = __y % __c;
       static constexpr uintmax_t __y1 = __y / __c;
       static constexpr uintmax_t __x0y0 = __x0 * __y0;
       static constexpr uintmax_t __x0y1 = __x0 * __y1;
       static constexpr uintmax_t __x1y0 = __x1 * __y0;
       static constexpr uintmax_t __x1y1 = __x1 * __y1;
       static constexpr uintmax_t __mix = __x0y1 + __x1y0; // possible carry...
       static constexpr uintmax_t __mix_lo = __mix * __c;
       static constexpr uintmax_t __mix_hi
       = __mix / __c + ((__mix < __x0y1) ? __c : 0); // ... added here
       typedef __big_add<__mix_hi, __mix_lo, __x1y1, __x0y0> _Res;
     public:
       static constexpr uintmax_t __hi = _Res::__hi;
       static constexpr uintmax_t __lo = _Res::__lo;
     };

   // Adapted from __udiv_qrnnd_c in longlong.h
   // This version assumes that the high bit of __d is 1.
   template<uintmax_t __n1, uintmax_t __n0, uintmax_t __d>
     struct __big_div_impl
     {
     private:
       static_assert(__d >= (uintmax_t(1) << (sizeof(intmax_t) * 8 - 1)),
 		    "Internal library error");
       static_assert(__n1 < __d, "Internal library error");
       static constexpr uintmax_t __c = uintmax_t(1) << (sizeof(intmax_t) * 4);
       static constexpr uintmax_t __d1 = __d / __c;
       static constexpr uintmax_t __d0 = __d % __c;

       static constexpr uintmax_t __q1x = __n1 / __d1;
       static constexpr uintmax_t __r1x = __n1 % __d1;
       static constexpr uintmax_t __m = __q1x * __d0;
       static constexpr uintmax_t __r1y = __r1x * __c + __n0 / __c;
       static constexpr uintmax_t __r1z = __r1y + __d;
       static constexpr uintmax_t __r1
       = ((__r1y < __m) ? ((__r1z >= __d) && (__r1z < __m))
 	 ? (__r1z + __d) : __r1z : __r1y) - __m;
       static constexpr uintmax_t __q1
       = __q1x - ((__r1y < __m)
 		 ? ((__r1z >= __d) && (__r1z < __m)) ? 2 : 1 : 0);
       static constexpr uintmax_t __q0x = __r1 / __d1;
       static constexpr uintmax_t __r0x = __r1 % __d1;
       static constexpr uintmax_t __n = __q0x * __d0;
       static constexpr uintmax_t __r0y = __r0x * __c + __n0 % __c;
       static constexpr uintmax_t __r0z = __r0y + __d;
       static constexpr uintmax_t __r0
       = ((__r0y < __n) ? ((__r0z >= __d) && (__r0z < __n))
 	 ? (__r0z + __d) : __r0z : __r0y) - __n;
       static constexpr uintmax_t __q0
       = __q0x - ((__r0y < __n) ? ((__r0z >= __d)
 				  && (__r0z < __n)) ? 2 : 1 : 0);

     public:
       static constexpr uintmax_t __quot = __q1 * __c + __q0;
       static constexpr uintmax_t __rem = __r0;

     private:
       typedef __big_mul<__quot, __d> _Prod;
       typedef __big_add<_Prod::__hi, _Prod::__lo, 0, __rem> _Sum;
       static_assert(_Sum::__hi == __n1 && _Sum::__lo == __n0,
 		    "Internal library error");
   };

   template<uintmax_t __n1, uintmax_t __n0, uintmax_t __d>
     struct __big_div
     {
     private:
       static_assert(__d != 0, "Internal library error");
       static_assert(sizeof (uintmax_t) == sizeof (unsigned long long),
 		    "This library calls __builtin_clzll on uintmax_t, which "
 		    "is unsafe on your platform. Please complain to "
 		    "http://gcc.gnu.org/bugzilla/");
       static constexpr int __shift = __builtin_clzll(__d);
       static constexpr int __coshift_ = sizeof(uintmax_t) * 8 - __shift;
       static constexpr int __coshift = (__shift != 0) ? __coshift_ : 0;
       static constexpr uintmax_t __c1 = uintmax_t(1) << __shift;
       static constexpr uintmax_t __c2 = uintmax_t(1) << __coshift;
       static constexpr uintmax_t __new_d = __d * __c1;
       static constexpr uintmax_t __new_n0 = __n0 * __c1;
       static constexpr uintmax_t __n1_shifted = (__n1 % __d) * __c1;
       static constexpr uintmax_t __n0_top = (__shift != 0) ? (__n0 / __c2) : 0;
       static constexpr uintmax_t __new_n1 = __n1_shifted + __n0_top;
       typedef __big_div_impl<__new_n1, __new_n0, __new_d> _Res;

     public:
       static constexpr uintmax_t __quot_hi = __n1 / __d;
       static constexpr uintmax_t __quot_lo = _Res::__quot;
       static constexpr uintmax_t __rem = _Res::__rem / __c1;

     private:
       typedef __big_mul<__quot_lo, __d> _P0;
       typedef __big_mul<__quot_hi, __d> _P1;
       typedef __big_add<_P0::__hi, _P0::__lo, _P1::__lo, __rem> _Sum;
       // No overflow.
       static_assert(_P1::__hi == 0, "Internal library error");
       static_assert(_Sum::__hi >= _P0::__hi, "Internal library error");
       // Matches the input data.
       static_assert(_Sum::__hi == __n1 && _Sum::__lo == __n0,
 		    "Internal library error");
       static_assert(__rem < __d, "Internal library error");
     };

   /// @endcond

   /**
    *  @brief Provides compile-time rational arithmetic.
    *
    *  This class template represents any finite rational number with a
    *  numerator and denominator representable by compile-time constants of
    *  type intmax_t. The ratio is simplified when instantiated.
    *
    *  For example:
    *  @code
    *    std::ratio<7,-21>::num == -1;
    *    std::ratio<7,-21>::den == 3;
    *  @endcode
    *
   */
   template<intmax_t _Num, intmax_t _Den = 1>
     struct ratio
     {
       static_assert(_Den != 0, "denominator cannot be zero");
       static_assert(_Num >= -__INTMAX_MAX__ && _Den >= -__INTMAX_MAX__,
 		    "out of range");

       // Note: sign(N) * abs(N) == N
       static constexpr intmax_t num =
         _Num * __static_sign<_Den>::value / __static_gcd<_Num, _Den>::value;

       static constexpr intmax_t den =
         __static_abs<_Den>::value / __static_gcd<_Num, _Den>::value;

       typedef ratio<num, den> type;
     };

 #if ! __cpp_inline_variables
   template<intmax_t _Num, intmax_t _Den>
     constexpr intmax_t ratio<_Num, _Den>::num;

   template<intmax_t _Num, intmax_t _Den>
     constexpr intmax_t ratio<_Num, _Den>::den;
 #endif

   /// @cond undocumented

   template<typename _R1, typename _R2>
     struct __ratio_multiply
     {
     private:
       static const intmax_t __gcd1 =
         __static_gcd<_R1::num, _R2::den>::value;
       static const intmax_t __gcd2 =
         __static_gcd<_R2::num, _R1::den>::value;

     public:
       typedef ratio<
         __safe_multiply<(_R1::num / __gcd1),
                         (_R2::num / __gcd2)>::value,
         __safe_multiply<(_R1::den / __gcd2),
                         (_R2::den / __gcd1)>::value> type;

       static constexpr intmax_t num = type::num;
       static constexpr intmax_t den = type::den;
     };

 #if ! __cpp_inline_variables
   template<typename _R1, typename _R2>
     constexpr intmax_t __ratio_multiply<_R1, _R2>::num;

   template<typename _R1, typename _R2>
     constexpr intmax_t __ratio_multiply<_R1, _R2>::den;
 #endif

   /// @endcond

   /// ratio_multiply
   template<typename _R1, typename _R2>
     using ratio_multiply = typename __ratio_multiply<_R1, _R2>::type;

   /// @cond undocumented

   template<typename _R1, typename _R2>
     struct __ratio_divide
     {
       static_assert(_R2::num != 0, "division by 0");

       typedef typename __ratio_multiply<
         _R1,
         ratio<_R2::den, _R2::num>>::type type;

       static constexpr intmax_t num = type::num;
       static constexpr intmax_t den = type::den;
     };

 #if ! __cpp_inline_variables
   template<typename _R1, typename _R2>
     constexpr intmax_t __ratio_divide<_R1, _R2>::num;

   template<typename _R1, typename _R2>
     constexpr intmax_t __ratio_divide<_R1, _R2>::den;
 #endif

   /// @endcond

   /// ratio_divide
   template<typename _R1, typename _R2>
     using ratio_divide = typename __ratio_divide<_R1, _R2>::type;

   /// ratio_equal
   template<typename _R1, typename _R2>
     struct ratio_equal
     : integral_constant<bool, _R1::num == _R2::num && _R1::den == _R2::den>
     { };

   /// ratio_not_equal
   template<typename _R1, typename _R2>
     struct ratio_not_equal
     : integral_constant<bool, !ratio_equal<_R1, _R2>::value>
     { };

   /// @cond undocumented

   // Both numbers are positive.
   template<typename _R1, typename _R2,
            typename _Left = __big_mul<_R1::num,_R2::den>,
            typename _Right = __big_mul<_R2::num,_R1::den> >
     struct __ratio_less_impl_1
     : integral_constant<bool, __big_less<_Left::__hi, _Left::__lo,
            _Right::__hi, _Right::__lo>::value>
     { };

   template<typename _R1, typename _R2,
 	   bool = (_R1::num == 0 || _R2::num == 0
 		   || (__static_sign<_R1::num>::value
 		       != __static_sign<_R2::num>::value)),
 	   bool = (__static_sign<_R1::num>::value == -1
 		   && __static_sign<_R2::num>::value == -1)>
     struct __ratio_less_impl
     : __ratio_less_impl_1<_R1, _R2>::type
     { };

   template<typename _R1, typename _R2>
     struct __ratio_less_impl<_R1, _R2, true, false>
     : integral_constant<bool, _R1::num < _R2::num>
     { };

   template<typename _R1, typename _R2>
     struct __ratio_less_impl<_R1, _R2, false, true>
     : __ratio_less_impl_1<ratio<-_R2::num, _R2::den>,
            ratio<-_R1::num, _R1::den> >::type
     { };

   /// @endcond

   /// ratio_less
   template<typename _R1, typename _R2>
     struct ratio_less
     : __ratio_less_impl<_R1, _R2>::type
     { };

   /// ratio_less_equal
   template<typename _R1, typename _R2>
     struct ratio_less_equal
     : integral_constant<bool, !ratio_less<_R2, _R1>::value>
     { };

   /// ratio_greater
   template<typename _R1, typename _R2>
     struct ratio_greater
     : integral_constant<bool, ratio_less<_R2, _R1>::value>
     { };

   /// ratio_greater_equal
   template<typename _R1, typename _R2>
     struct ratio_greater_equal
     : integral_constant<bool, !ratio_less<_R1, _R2>::value>
     { };

 #if __cplusplus > 201402L
   template <typename _R1, typename _R2>
     inline constexpr bool ratio_equal_v = ratio_equal<_R1, _R2>::value;
   template <typename _R1, typename _R2>
     inline constexpr bool ratio_not_equal_v = ratio_not_equal<_R1, _R2>::value;
   template <typename _R1, typename _R2>
     inline constexpr bool ratio_less_v = ratio_less<_R1, _R2>::value;
   template <typename _R1, typename _R2>
     inline constexpr bool ratio_less_equal_v =
       ratio_less_equal<_R1, _R2>::value;
   template <typename _R1, typename _R2>
     inline constexpr bool ratio_greater_v = ratio_greater<_R1, _R2>::value;
   template <typename _R1, typename _R2>
     inline constexpr bool ratio_greater_equal_v
     = ratio_greater_equal<_R1, _R2>::value;
 #endif // C++17

   /// @cond undocumented

   template<typename _R1, typename _R2,
       bool = (_R1::num >= 0),
       bool = (_R2::num >= 0),
       bool = ratio_less<ratio<__static_abs<_R1::num>::value, _R1::den>,
         ratio<__static_abs<_R2::num>::value, _R2::den> >::value>
     struct __ratio_add_impl
     {
     private:
       typedef typename __ratio_add_impl<
         ratio<-_R1::num, _R1::den>,
         ratio<-_R2::num, _R2::den> >::type __t;
     public:
       typedef ratio<-__t::num, __t::den> type;
     };

   // True addition of nonnegative numbers.
   template<typename _R1, typename _R2, bool __b>
     struct __ratio_add_impl<_R1, _R2, true, true, __b>
     {
     private:
       static constexpr uintmax_t __g = __static_gcd<_R1::den, _R2::den>::value;
       static constexpr uintmax_t __d2 = _R2::den / __g;
       typedef __big_mul<_R1::den, __d2> __d;
       typedef __big_mul<_R1::num, _R2::den / __g> __x;
       typedef __big_mul<_R2::num, _R1::den / __g> __y;
       typedef __big_add<__x::__hi, __x::__lo, __y::__hi, __y::__lo> __n;
       static_assert(__n::__hi >= __x::__hi, "Internal library error");
       typedef __big_div<__n::__hi, __n::__lo, __g> __ng;
       static constexpr uintmax_t __g2 = __static_gcd<__ng::__rem, __g>::value;
       typedef __big_div<__n::__hi, __n::__lo, __g2> __n_final;
       static_assert(__n_final::__rem == 0, "Internal library error");
       static_assert(__n_final::__quot_hi == 0 &&
         __n_final::__quot_lo <= __INTMAX_MAX__, "overflow in addition");
       typedef __big_mul<_R1::den / __g2, __d2> __d_final;
       static_assert(__d_final::__hi == 0 &&
         __d_final::__lo <= __INTMAX_MAX__, "overflow in addition");
     public:
       typedef ratio<__n_final::__quot_lo, __d_final::__lo> type;
     };

   template<typename _R1, typename _R2>
     struct __ratio_add_impl<_R1, _R2, false, true, true>
     : __ratio_add_impl<_R2, _R1>
     { };

   // True subtraction of nonnegative numbers yielding a nonnegative result.
   template<typename _R1, typename _R2>
     struct __ratio_add_impl<_R1, _R2, true, false, false>
     {
     private:
       static constexpr uintmax_t __g = __static_gcd<_R1::den, _R2::den>::value;
       static constexpr uintmax_t __d2 = _R2::den / __g;
       typedef __big_mul<_R1::den, __d2> __d;
       typedef __big_mul<_R1::num, _R2::den / __g> __x;
       typedef __big_mul<-_R2::num, _R1::den / __g> __y;
       typedef __big_sub<__x::__hi, __x::__lo, __y::__hi, __y::__lo> __n;
       typedef __big_div<__n::__hi, __n::__lo, __g> __ng;
       static constexpr uintmax_t __g2 = __static_gcd<__ng::__rem, __g>::value;
       typedef __big_div<__n::__hi, __n::__lo, __g2> __n_final;
       static_assert(__n_final::__rem == 0, "Internal library error");
       static_assert(__n_final::__quot_hi == 0 &&
         __n_final::__quot_lo <= __INTMAX_MAX__, "overflow in addition");
       typedef __big_mul<_R1::den / __g2, __d2> __d_final;
       static_assert(__d_final::__hi == 0 &&
         __d_final::__lo <= __INTMAX_MAX__, "overflow in addition");
     public:
       typedef ratio<__n_final::__quot_lo, __d_final::__lo> type;
     };

   template<typename _R1, typename _R2>
     struct __ratio_add
     {
       typedef typename __ratio_add_impl<_R1, _R2>::type type;
       static constexpr intmax_t num = type::num;
       static constexpr intmax_t den = type::den;
     };

 #if ! __cpp_inline_variables
   template<typename _R1, typename _R2>
     constexpr intmax_t __ratio_add<_R1, _R2>::num;

   template<typename _R1, typename _R2>
     constexpr intmax_t __ratio_add<_R1, _R2>::den;
 #endif

   /// @endcond

   /// ratio_add
   template<typename _R1, typename _R2>
     using ratio_add = typename __ratio_add<_R1, _R2>::type;

   /// @cond undocumented

   template<typename _R1, typename _R2>
     struct __ratio_subtract
     {
       typedef typename __ratio_add<
         _R1,
         ratio<-_R2::num, _R2::den>>::type type;

       static constexpr intmax_t num = type::num;
       static constexpr intmax_t den = type::den;
     };

 #if ! __cpp_inline_variables
   template<typename _R1, typename _R2>
     constexpr intmax_t __ratio_subtract<_R1, _R2>::num;

   template<typename _R1, typename _R2>
     constexpr intmax_t __ratio_subtract<_R1, _R2>::den;
 #endif

   /// @endcond

   /// ratio_subtract
   template<typename _R1, typename _R2>
     using ratio_subtract = typename __ratio_subtract<_R1, _R2>::type;


   typedef ratio<1,       1000000000000000000> atto;
   typedef ratio<1,          1000000000000000> femto;
   typedef ratio<1,             1000000000000> pico;
   typedef ratio<1,                1000000000> nano;
   typedef ratio<1,                   1000000> micro;
   typedef ratio<1,                      1000> milli;
   typedef ratio<1,                       100> centi;
   typedef ratio<1,                        10> deci;
   typedef ratio<                       10, 1> deca;
   typedef ratio<                      100, 1> hecto;
   typedef ratio<                     1000, 1> kilo;
   typedef ratio<                  1000000, 1> mega;
   typedef ratio<               1000000000, 1> giga;
   typedef ratio<            1000000000000, 1> tera;
   typedef ratio<         1000000000000000, 1> peta;
   typedef ratio<      1000000000000000000, 1> exa;

   /// @} group ratio
 _GLIBCXX_END_NAMESPACE_VERSION
 } // namespace

 #endif // C++11

 #endif //_GLIBCXX_RATIO
	// ratio -- C++ --

	// Copyright (C) 2008-2021 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/>.

	/** @file include/ratio
	* This is a Standard C++ Library header.
	* @ingroup ratio
	*/

	#ifndef _GLIBCXX_RATIO
	#define _GLIBCXX_RATIO 1

	#pragma GCC system_header

	#if __cplusplus < 201103L
	# include <bits/c++0x_warning.h>
	#else

	#include <type_traits>
	#include <cstdint> // intmax_t, uintmax_t

	namespace std _GLIBCXX_VISIBILITY(default)
	{
	_GLIBCXX_BEGIN_NAMESPACE_VERSION

	/**
	* @defgroup ratio Rational Arithmetic
	* @ingroup utilities
	*
	* Compile time representation of finite rational numbers.
	* @{
	*/

	/// @cond undocumented

	template<intmax_t _Pn>
	struct __static_sign
	: integral_constant<intmax_t, (_Pn < 0) ? -1 : 1>
	{ };

	template<intmax_t _Pn>
	struct __static_abs
	: integral_constant<intmax_t, _Pn * __static_sign<_Pn>::value>
	{ };

	template<intmax_t _Pn, intmax_t _Qn>
	struct __static_gcd
	: __static_gcd<_Qn, (_Pn % _Qn)>
	{ };

	template<intmax_t _Pn>
	struct __static_gcd<_Pn, 0>
	: integral_constant<intmax_t, __static_abs<_Pn>::value>
	{ };

	template<intmax_t _Qn>
	struct __static_gcd<0, _Qn>
	: integral_constant<intmax_t, __static_abs<_Qn>::value>
	{ };

	// Let c = 2^(half # of bits in an intmax_t)
	// then we find a1, a0, b1, b0 s.t. N = a1c + a0, M = b1c + b0
	// The multiplication of N and M becomes,
	// N * M = (a1 * b1)c^2 + (a0 * b1 + b0 * a1)c + a0 * b0
	// Multiplication is safe if each term and the sum of the terms
	// is representable by intmax_t.
	template<intmax_t _Pn, intmax_t _Qn>
	struct __safe_multiply
	{
	private:
	static const uintmax_t __c = uintmax_t(1) << (sizeof(intmax_t) * 4);

	static const uintmax_t __a0 = __static_abs<_Pn>::value % __c;
	static const uintmax_t __a1 = __static_abs<_Pn>::value / __c;
	static const uintmax_t __b0 = __static_abs<_Qn>::value % __c;
	static const uintmax_t __b1 = __static_abs<_Qn>::value / __c;

	static_assert(__a1 == 0 \|\| __b1 == 0,
	"overflow in multiplication");
	static_assert(__a0 * __b1 + __b0 * __a1 < (__c >> 1),
	"overflow in multiplication");
	static_assert(__b0 * __a0 <= __INTMAX_MAX__,
	"overflow in multiplication");
	static_assert((__a0 * __b1 + __b0 * __a1) * __c
	<= __INTMAX_MAX__ - __b0 * __a0,
	"overflow in multiplication");

	public:
	static const intmax_t value = _Pn * _Qn;
	};

	// Some double-precision utilities, where numbers are represented as
	// __hi2^(8sizeof(uintmax_t)) + __lo.
	template<uintmax_t __hi1, uintmax_t __lo1, uintmax_t __hi2, uintmax_t __lo2>
	struct __big_less
	: integral_constant<bool, (__hi1 < __hi2
	\|\| (__hi1 == __hi2 && __lo1 < __lo2))>
	{ };

	template<uintmax_t __hi1, uintmax_t __lo1, uintmax_t __hi2, uintmax_t __lo2>
	struct __big_add
	{
	static constexpr uintmax_t __lo = __lo1 + __lo2;
	static constexpr uintmax_t __hi = (__hi1 + __hi2 +
	(__lo1 + __lo2 < __lo1)); // carry
	};

	// Subtract a number from a bigger one.
	template<uintmax_t __hi1, uintmax_t __lo1, uintmax_t __hi2, uintmax_t __lo2>
	struct __big_sub
	{
	static_assert(!__big_less<__hi1, __lo1, __hi2, __lo2>::value,
	"Internal library error");
	static constexpr uintmax_t __lo = __lo1 - __lo2;
	static constexpr uintmax_t __hi = (__hi1 - __hi2 -
	(__lo1 < __lo2)); // carry
	};

	// Same principle as __safe_multiply.
	template<uintmax_t __x, uintmax_t __y>
	struct __big_mul
	{
	private:
	static constexpr uintmax_t __c = uintmax_t(1) << (sizeof(intmax_t) * 4);
	static constexpr uintmax_t __x0 = __x % __c;
	static constexpr uintmax_t __x1 = __x / __c;
	static constexpr uintmax_t __y0 = __y % __c;
	static constexpr uintmax_t __y1 = __y / __c;
	static constexpr uintmax_t __x0y0 = __x0 * __y0;
	static constexpr uintmax_t __x0y1 = __x0 * __y1;
	static constexpr uintmax_t __x1y0 = __x1 * __y0;
	static constexpr uintmax_t __x1y1 = __x1 * __y1;
	static constexpr uintmax_t __mix = __x0y1 + __x1y0; // possible carry...
	static constexpr uintmax_t __mix_lo = __mix * __c;
	static constexpr uintmax_t __mix_hi
	= __mix / __c + ((__mix < __x0y1) ? __c : 0); // ... added here
	typedef __big_add<__mix_hi, __mix_lo, __x1y1, __x0y0> _Res;
	public:
	static constexpr uintmax_t __hi = _Res::__hi;
	static constexpr uintmax_t __lo = _Res::__lo;
	};

	// Adapted from __udiv_qrnnd_c in longlong.h
	// This version assumes that the high bit of __d is 1.
	template<uintmax_t __n1, uintmax_t __n0, uintmax_t __d>
	struct __big_div_impl
	{
	private:
	static_assert(__d >= (uintmax_t(1) << (sizeof(intmax_t) * 8 - 1)),
	"Internal library error");
	static_assert(__n1 < __d, "Internal library error");
	static constexpr uintmax_t __c = uintmax_t(1) << (sizeof(intmax_t) * 4);
	static constexpr uintmax_t __d1 = __d / __c;
	static constexpr uintmax_t __d0 = __d % __c;

	static constexpr uintmax_t __q1x = __n1 / __d1;
	static constexpr uintmax_t __r1x = __n1 % __d1;
	static constexpr uintmax_t __m = __q1x * __d0;
	static constexpr uintmax_t __r1y = __r1x * __c + __n0 / __c;
	static constexpr uintmax_t __r1z = __r1y + __d;
	static constexpr uintmax_t __r1
	= ((__r1y < __m) ? ((__r1z >= __d) && (__r1z < __m))
	? (__r1z + __d) : __r1z : __r1y) - __m;
	static constexpr uintmax_t __q1
	= __q1x - ((__r1y < __m)
	? ((__r1z >= __d) && (__r1z < __m)) ? 2 : 1 : 0);
	static constexpr uintmax_t __q0x = __r1 / __d1;
	static constexpr uintmax_t __r0x = __r1 % __d1;
	static constexpr uintmax_t __n = __q0x * __d0;
	static constexpr uintmax_t __r0y = __r0x * __c + __n0 % __c;
	static constexpr uintmax_t __r0z = __r0y + __d;
	static constexpr uintmax_t __r0
	= ((__r0y < __n) ? ((__r0z >= __d) && (__r0z < __n))
	? (__r0z + __d) : __r0z : __r0y) - __n;
	static constexpr uintmax_t __q0
	= __q0x - ((__r0y < __n) ? ((__r0z >= __d)
	&& (__r0z < __n)) ? 2 : 1 : 0);

	public:
	static constexpr uintmax_t __quot = __q1 * __c + __q0;
	static constexpr uintmax_t __rem = __r0;

	private:
	typedef __big_mul<__quot, __d> _Prod;
	typedef __big_add<_Prod::__hi, _Prod::__lo, 0, __rem> _Sum;
	static_assert(_Sum::__hi == __n1 && _Sum::__lo == __n0,
	"Internal library error");
	};

	template<uintmax_t __n1, uintmax_t __n0, uintmax_t __d>
	struct __big_div
	{
	private:
	static_assert(__d != 0, "Internal library error");
	static_assert(sizeof (uintmax_t) == sizeof (unsigned long long),
	"This library calls __builtin_clzll on uintmax_t, which "
	"is unsafe on your platform. Please complain to "
	"http://gcc.gnu.org/bugzilla/");
	static constexpr int __shift = __builtin_clzll(__d);
	static constexpr int __coshift_ = sizeof(uintmax_t) * 8 - __shift;
	static constexpr int __coshift = (__shift != 0) ? __coshift_ : 0;
	static constexpr uintmax_t __c1 = uintmax_t(1) << __shift;
	static constexpr uintmax_t __c2 = uintmax_t(1) << __coshift;
	static constexpr uintmax_t __new_d = __d * __c1;
	static constexpr uintmax_t __new_n0 = __n0 * __c1;
	static constexpr uintmax_t __n1_shifted = (__n1 % __d) * __c1;
	static constexpr uintmax_t __n0_top = (__shift != 0) ? (__n0 / __c2) : 0;
	static constexpr uintmax_t __new_n1 = __n1_shifted + __n0_top;
	typedef __big_div_impl<__new_n1, __new_n0, __new_d> _Res;

	public:
	static constexpr uintmax_t __quot_hi = __n1 / __d;
	static constexpr uintmax_t __quot_lo = _Res::__quot;
	static constexpr uintmax_t __rem = _Res::__rem / __c1;

	private:
	typedef __big_mul<__quot_lo, __d> _P0;
	typedef __big_mul<__quot_hi, __d> _P1;
	typedef __big_add<_P0::__hi, _P0::__lo, _P1::__lo, __rem> _Sum;
	// No overflow.
	static_assert(_P1::__hi == 0, "Internal library error");
	static_assert(_Sum::__hi >= _P0::__hi, "Internal library error");
	// Matches the input data.
	static_assert(_Sum::__hi == __n1 && _Sum::__lo == __n0,
	"Internal library error");
	static_assert(__rem < __d, "Internal library error");
	};

	/// @endcond

	/**
	* @brief Provides compile-time rational arithmetic.
	*
	* This class template represents any finite rational number with a
	* numerator and denominator representable by compile-time constants of
	* type intmax_t. The ratio is simplified when instantiated.
	*
	* For example:
	* @code
	* std::ratio<7,-21>::num == -1;
	* std::ratio<7,-21>::den == 3;
	* @endcode
	*
	*/
	template<intmax_t _Num, intmax_t _Den = 1>
	struct ratio
	{
	static_assert(_Den != 0, "denominator cannot be zero");
	static_assert(_Num >= -__INTMAX_MAX__ && _Den >= -__INTMAX_MAX__,
	"out of range");

	// Note: sign(N) * abs(N) == N
	static constexpr intmax_t num =
	_Num * __static_sign<_Den>::value / __static_gcd<_Num, _Den>::value;

	static constexpr intmax_t den =
	__static_abs<_Den>::value / __static_gcd<_Num, _Den>::value;

	typedef ratio<num, den> type;
	};

	#if ! __cpp_inline_variables
	template<intmax_t _Num, intmax_t _Den>
	constexpr intmax_t ratio<_Num, _Den>::num;

	template<intmax_t _Num, intmax_t _Den>
	constexpr intmax_t ratio<_Num, _Den>::den;
	#endif

	/// @cond undocumented

	template<typename _R1, typename _R2>
	struct __ratio_multiply
	{
	private:
	static const intmax_t __gcd1 =
	__static_gcd<_R1::num, _R2::den>::value;
	static const intmax_t __gcd2 =
	__static_gcd<_R2::num, _R1::den>::value;

	public:
	typedef ratio<
	__safe_multiply<(_R1::num / __gcd1),
	(_R2::num / __gcd2)>::value,
	__safe_multiply<(_R1::den / __gcd2),
	(_R2::den / __gcd1)>::value> type;

	static constexpr intmax_t num = type::num;
	static constexpr intmax_t den = type::den;
	};

	#if ! __cpp_inline_variables
	template<typename _R1, typename _R2>
	constexpr intmax_t __ratio_multiply<_R1, _R2>::num;

	template<typename _R1, typename _R2>
	constexpr intmax_t __ratio_multiply<_R1, _R2>::den;
	#endif

	/// @endcond

	/// ratio_multiply
	template<typename _R1, typename _R2>
	using ratio_multiply = typename __ratio_multiply<_R1, _R2>::type;

	/// @cond undocumented

	template<typename _R1, typename _R2>
	struct __ratio_divide
	{
	static_assert(_R2::num != 0, "division by 0");

	typedef typename __ratio_multiply<
	_R1,
	ratio<_R2::den, _R2::num>>::type type;

	static constexpr intmax_t num = type::num;
	static constexpr intmax_t den = type::den;
	};

	#if ! __cpp_inline_variables
	template<typename _R1, typename _R2>
	constexpr intmax_t __ratio_divide<_R1, _R2>::num;

	template<typename _R1, typename _R2>
	constexpr intmax_t __ratio_divide<_R1, _R2>::den;
	#endif

	/// @endcond

	/// ratio_divide
	template<typename _R1, typename _R2>
	using ratio_divide = typename __ratio_divide<_R1, _R2>::type;

	/// ratio_equal
	template<typename _R1, typename _R2>
	struct ratio_equal
	: integral_constant<bool, _R1::num == _R2::num && _R1::den == _R2::den>
	{ };

	/// ratio_not_equal
	template<typename _R1, typename _R2>
	struct ratio_not_equal
	: integral_constant<bool, !ratio_equal<_R1, _R2>::value>
	{ };

	/// @cond undocumented

	// Both numbers are positive.
	template<typename _R1, typename _R2,
	typename _Left = __big_mul<_R1::num,_R2::den>,
	typename _Right = __big_mul<_R2::num,_R1::den> >
	struct __ratio_less_impl_1
	: integral_constant<bool, __big_less<_Left::__hi, _Left::__lo,
	_Right::__hi, _Right::__lo>::value>
	{ };

	template<typename _R1, typename _R2,
	bool = (_R1::num == 0 \|\| _R2::num == 0
	\|\| (__static_sign<_R1::num>::value
	!= __static_sign<_R2::num>::value)),
	bool = (__static_sign<_R1::num>::value == -1
	&& __static_sign<_R2::num>::value == -1)>
	struct __ratio_less_impl
	: __ratio_less_impl_1<_R1, _R2>::type
	{ };

	template<typename _R1, typename _R2>
	struct __ratio_less_impl<_R1, _R2, true, false>
	: integral_constant<bool, _R1::num < _R2::num>
	{ };

	template<typename _R1, typename _R2>
	struct __ratio_less_impl<_R1, _R2, false, true>
	: __ratio_less_impl_1<ratio<-_R2::num, _R2::den>,
	ratio<-_R1::num, _R1::den> >::type
	{ };

	/// @endcond

	/// ratio_less
	template<typename _R1, typename _R2>
	struct ratio_less
	: __ratio_less_impl<_R1, _R2>::type
	{ };

	/// ratio_less_equal
	template<typename _R1, typename _R2>
	struct ratio_less_equal
	: integral_constant<bool, !ratio_less<_R2, _R1>::value>
	{ };

	/// ratio_greater
	template<typename _R1, typename _R2>
	struct ratio_greater
	: integral_constant<bool, ratio_less<_R2, _R1>::value>
	{ };

	/// ratio_greater_equal
	template<typename _R1, typename _R2>
	struct ratio_greater_equal
	: integral_constant<bool, !ratio_less<_R1, _R2>::value>
	{ };

	#if __cplusplus > 201402L
	template <typename _R1, typename _R2>
	inline constexpr bool ratio_equal_v = ratio_equal<_R1, _R2>::value;
	template <typename _R1, typename _R2>
	inline constexpr bool ratio_not_equal_v = ratio_not_equal<_R1, _R2>::value;
	template <typename _R1, typename _R2>
	inline constexpr bool ratio_less_v = ratio_less<_R1, _R2>::value;
	template <typename _R1, typename _R2>
	inline constexpr bool ratio_less_equal_v =
	ratio_less_equal<_R1, _R2>::value;
	template <typename _R1, typename _R2>
	inline constexpr bool ratio_greater_v = ratio_greater<_R1, _R2>::value;
	template <typename _R1, typename _R2>
	inline constexpr bool ratio_greater_equal_v
	= ratio_greater_equal<_R1, _R2>::value;
	#endif // C++17

	/// @cond undocumented

	template<typename _R1, typename _R2,
	bool = (_R1::num >= 0),
	bool = (_R2::num >= 0),
	bool = ratio_less<ratio<__static_abs<_R1::num>::value, _R1::den>,
	ratio<__static_abs<_R2::num>::value, _R2::den> >::value>
	struct __ratio_add_impl
	{
	private:
	typedef typename __ratio_add_impl<
	ratio<-_R1::num, _R1::den>,
	ratio<-_R2::num, _R2::den> >::type __t;
	public:
	typedef ratio<-__t::num, __t::den> type;
	};

	// True addition of nonnegative numbers.
	template<typename _R1, typename _R2, bool __b>
	struct __ratio_add_impl<_R1, _R2, true, true, __b>
	{
	private:
	static constexpr uintmax_t __g = __static_gcd<_R1::den, _R2::den>::value;
	static constexpr uintmax_t __d2 = _R2::den / __g;
	typedef __big_mul<_R1::den, __d2> __d;
	typedef __big_mul<_R1::num, _R2::den / __g> __x;
	typedef __big_mul<_R2::num, _R1::den / __g> __y;
	typedef __big_add<__x::__hi, __x::__lo, __y::__hi, __y::__lo> __n;
	static_assert(__n::__hi >= __x::__hi, "Internal library error");
	typedef __big_div<__n::__hi, __n::__lo, __g> __ng;
	static constexpr uintmax_t __g2 = __static_gcd<__ng::__rem, __g>::value;
	typedef __big_div<__n::__hi, __n::__lo, __g2> __n_final;
	static_assert(__n_final::__rem == 0, "Internal library error");
	static_assert(__n_final::__quot_hi == 0 &&
	__n_final::__quot_lo <= __INTMAX_MAX__, "overflow in addition");
	typedef __big_mul<_R1::den / __g2, __d2> __d_final;
	static_assert(__d_final::__hi == 0 &&
	__d_final::__lo <= __INTMAX_MAX__, "overflow in addition");
	public:
	typedef ratio<__n_final::__quot_lo, __d_final::__lo> type;
	};

	template<typename _R1, typename _R2>
	struct __ratio_add_impl<_R1, _R2, false, true, true>
	: __ratio_add_impl<_R2, _R1>
	{ };

	// True subtraction of nonnegative numbers yielding a nonnegative result.
	template<typename _R1, typename _R2>
	struct __ratio_add_impl<_R1, _R2, true, false, false>
	{
	private:
	static constexpr uintmax_t __g = __static_gcd<_R1::den, _R2::den>::value;
	static constexpr uintmax_t __d2 = _R2::den / __g;
	typedef __big_mul<_R1::den, __d2> __d;
	typedef __big_mul<_R1::num, _R2::den / __g> __x;
	typedef __big_mul<-_R2::num, _R1::den / __g> __y;
	typedef __big_sub<__x::__hi, __x::__lo, __y::__hi, __y::__lo> __n;
	typedef __big_div<__n::__hi, __n::__lo, __g> __ng;
	static constexpr uintmax_t __g2 = __static_gcd<__ng::__rem, __g>::value;
	typedef __big_div<__n::__hi, __n::__lo, __g2> __n_final;
	static_assert(__n_final::__rem == 0, "Internal library error");
	static_assert(__n_final::__quot_hi == 0 &&
	__n_final::__quot_lo <= __INTMAX_MAX__, "overflow in addition");
	typedef __big_mul<_R1::den / __g2, __d2> __d_final;
	static_assert(__d_final::__hi == 0 &&
	__d_final::__lo <= __INTMAX_MAX__, "overflow in addition");
	public:
	typedef ratio<__n_final::__quot_lo, __d_final::__lo> type;
	};

	template<typename _R1, typename _R2>
	struct __ratio_add
	{
	typedef typename __ratio_add_impl<_R1, _R2>::type type;
	static constexpr intmax_t num = type::num;
	static constexpr intmax_t den = type::den;
	};

	#if ! __cpp_inline_variables
	template<typename _R1, typename _R2>
	constexpr intmax_t __ratio_add<_R1, _R2>::num;

	template<typename _R1, typename _R2>
	constexpr intmax_t __ratio_add<_R1, _R2>::den;
	#endif

	/// @endcond

	/// ratio_add
	template<typename _R1, typename _R2>
	using ratio_add = typename __ratio_add<_R1, _R2>::type;

	/// @cond undocumented

	template<typename _R1, typename _R2>
	struct __ratio_subtract
	{
	typedef typename __ratio_add<
	_R1,
	ratio<-_R2::num, _R2::den>>::type type;

	static constexpr intmax_t num = type::num;
	static constexpr intmax_t den = type::den;
	};

	#if ! __cpp_inline_variables
	template<typename _R1, typename _R2>
	constexpr intmax_t __ratio_subtract<_R1, _R2>::num;

	template<typename _R1, typename _R2>
	constexpr intmax_t __ratio_subtract<_R1, _R2>::den;
	#endif

	/// @endcond

	/// ratio_subtract
	template<typename _R1, typename _R2>
	using ratio_subtract = typename __ratio_subtract<_R1, _R2>::type;


	typedef ratio<1, 1000000000000000000> atto;
	typedef ratio<1, 1000000000000000> femto;
	typedef ratio<1, 1000000000000> pico;
	typedef ratio<1, 1000000000> nano;
	typedef ratio<1, 1000000> micro;
	typedef ratio<1, 1000> milli;
	typedef ratio<1, 100> centi;
	typedef ratio<1, 10> deci;
	typedef ratio< 10, 1> deca;
	typedef ratio< 100, 1> hecto;
	typedef ratio< 1000, 1> kilo;
	typedef ratio< 1000000, 1> mega;
	typedef ratio< 1000000000, 1> giga;
	typedef ratio< 1000000000000, 1> tera;
	typedef ratio< 1000000000000000, 1> peta;
	typedef ratio< 1000000000000000000, 1> exa;

	/// @} group ratio
	_GLIBCXX_END_NAMESPACE_VERSION
	} // namespace

	#endif // C++11

	#endif //_GLIBCXX_RATIO