/////////////////////////////////////////////////////////////// // Copyright 2013 John Maddock. Distributed under the Boost // Software License, Version 1.0. (See accompanying file // LICENSE_1_0.txt or copy at https://www.boost.org/LICENSE_1_0.txt #ifndef BOOST_MP_FLOAT128_HPP #define BOOST_MP_FLOAT128_HPP #include #include #include #include #if defined(BOOST_INTEL) && !defined(BOOST_MP_USE_FLOAT128) && !defined(BOOST_MP_USE_QUAD) #if defined(BOOST_INTEL_CXX_VERSION) && (BOOST_INTEL_CXX_VERSION >= 1310) && defined(__GNUC__) #if (__GNUC__ > 4) || ((__GNUC__ == 4) && (__GNUC_MINOR__ >= 6)) #define BOOST_MP_USE_FLOAT128 #endif #endif #ifndef BOOST_MP_USE_FLOAT128 #define BOOST_MP_USE_QUAD #endif #endif #if defined(__GNUC__) && !defined(BOOST_MP_USE_FLOAT128) && !defined(BOOST_MP_USE_QUAD) #define BOOST_MP_USE_FLOAT128 #endif #if !defined(BOOST_MP_USE_FLOAT128) && !defined(BOOST_MP_USE_QUAD) #error "Sorry compiler is neither GCC, not Intel, don't know how to configure this header." #endif #if defined(BOOST_MP_USE_FLOAT128) && defined(BOOST_MP_USE_QUAD) #error "Oh dear, both BOOST_MP_USE_FLOAT128 and BOOST_MP_USE_QUAD are defined, which one should I be using?" #endif #if defined(BOOST_MP_USE_FLOAT128) extern "C" { #include } using float128_type = __float128; #elif defined(BOOST_MP_USE_QUAD) #include using float128_type = _Quad; extern "C" { _Quad __ldexpq(_Quad, int); _Quad __frexpq(_Quad, int*); _Quad __fabsq(_Quad); _Quad __floorq(_Quad); _Quad __ceilq(_Quad); _Quad __sqrtq(_Quad); _Quad __truncq(_Quad); _Quad __expq(_Quad); _Quad __powq(_Quad, _Quad); _Quad __logq(_Quad); _Quad __log10q(_Quad); _Quad __sinq(_Quad); _Quad __cosq(_Quad); _Quad __tanq(_Quad); _Quad __asinq(_Quad); _Quad __acosq(_Quad); _Quad __atanq(_Quad); _Quad __sinhq(_Quad); _Quad __coshq(_Quad); _Quad __tanhq(_Quad); _Quad __fmodq(_Quad, _Quad); _Quad __atan2q(_Quad, _Quad); #define ldexpq __ldexpq #define frexpq __frexpq #define fabsq __fabsq #define floorq __floorq #define ceilq __ceilq #define sqrtq __sqrtq #define truncq __truncq #define expq __expq #define powq __powq #define logq __logq #define log10q __log10q #define sinq __sinq #define cosq __cosq #define tanq __tanq #define asinq __asinq #define acosq __acosq #define atanq __atanq #define sinhq __sinhq #define coshq __coshq #define tanhq __tanhq #define fmodq __fmodq #define atan2q __atan2q } inline _Quad isnanq(_Quad v) { return v != v; } inline _Quad isinfq(_Quad v) { return __fabsq(v) > 1.18973149535723176508575932662800702e4932Q; } #endif namespace boost { namespace multiprecision { #ifndef BOOST_MP_BITS_OF_FLOAT128_DEFINED namespace detail { template <> struct bits_of { static constexpr const unsigned value = 113; }; } #endif namespace backends { struct float128_backend; } using backends::float128_backend; template <> struct number_category : public std::integral_constant {}; #if defined(BOOST_MP_USE_QUAD) template <> struct number_category : public std::integral_constant {}; #endif using float128 = number; namespace quad_constants { constexpr __float128 quad_min = static_cast<__float128>(1) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) / 1073741824; constexpr __float128 quad_denorm_min = static_cast<__float128>(1) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) * static_cast<__float128>(DBL_MIN) / 5.5751862996326557854e+42; constexpr double dbl_mult = 8.9884656743115795386e+307; // This has one bit set only. constexpr __float128 quad_max = (static_cast<__float128>(1) - 9.62964972193617926527988971292463659e-35) // This now has all bits sets to 1 * static_cast<__float128>(dbl_mult) * static_cast<__float128>(dbl_mult) * static_cast<__float128>(dbl_mult) * static_cast<__float128>(dbl_mult) * static_cast<__float128>(dbl_mult) * static_cast<__float128>(dbl_mult) * static_cast<__float128>(dbl_mult) * static_cast<__float128>(dbl_mult) * static_cast<__float128>(dbl_mult) * static_cast<__float128>(dbl_mult) * static_cast<__float128>(dbl_mult) * static_cast<__float128>(dbl_mult) * static_cast<__float128>(dbl_mult) * static_cast<__float128>(dbl_mult) * static_cast<__float128>(dbl_mult) * static_cast<__float128>(dbl_mult) * 65536; } // namespace quad_constants #define BOOST_MP_QUAD_MIN boost::multiprecision::quad_constants::quad_min #define BOOST_MP_QUAD_DENORM_MIN boost::multiprecision::quad_constants::quad_denorm_min #define BOOST_MP_QUAD_MAX boost::multiprecision::quad_constants::quad_max namespace backends { struct float128_backend { using signed_types = std::tuple; using unsigned_types = std::tuple; using float_types = std::tuple; using exponent_type = int ; private: float128_type m_value; public: constexpr float128_backend() noexcept : m_value(0) {} constexpr float128_backend(const float128_backend& o) noexcept : m_value(o.m_value) {} BOOST_MP_CXX14_CONSTEXPR float128_backend& operator=(const float128_backend& o) noexcept { m_value = o.m_value; return *this; } template constexpr float128_backend(const T& i, const typename std::enable_if::value>::type* = 0) noexcept(noexcept(std::declval() = std::declval())) : m_value(i) {} template BOOST_MP_CXX14_CONSTEXPR typename std::enable_if::value || std::is_convertible::value, float128_backend&>::type operator=(const T& i) noexcept(noexcept(std::declval() = std::declval())) { m_value = i; return *this; } BOOST_MP_CXX14_CONSTEXPR float128_backend(long double const& f) : m_value(f) { if (::fabsl(f) > LDBL_MAX) m_value = (f < 0) ? -static_cast<__float128>(HUGE_VAL) : static_cast<__float128>(HUGE_VAL); } BOOST_MP_CXX14_CONSTEXPR float128_backend& operator=(long double const& f) { if (f > LDBL_MAX) m_value = static_cast<__float128>(HUGE_VAL); else if (-f > LDBL_MAX) m_value = -static_cast<__float128>(HUGE_VAL); else m_value = f; return *this; } float128_backend& operator=(const char* s) { #ifndef BOOST_MP_USE_QUAD char* p_end; m_value = strtoflt128(s, &p_end); if (p_end - s != (std::ptrdiff_t)std::strlen(s)) { BOOST_THROW_EXCEPTION(std::runtime_error("Unable to interpret input string as a floating point value")); } #else boost::multiprecision::detail::convert_from_string(*this, s); #endif return *this; } BOOST_MP_CXX14_CONSTEXPR void swap(float128_backend& o) noexcept { // We don't call std::swap here because it's no constexpr (yet): float128_type t(o.value()); o.value() = m_value; m_value = t; } std::string str(std::streamsize digits, std::ios_base::fmtflags f) const { #ifndef BOOST_MP_USE_QUAD char buf[128]; std::string format = "%"; if (f & std::ios_base::showpos) format += "+"; if (f & std::ios_base::showpoint) format += "#"; format += ".*"; if (digits == 0) digits = 36; format += "Q"; if (f & std::ios_base::scientific) format += "e"; else if (f & std::ios_base::fixed) format += "f"; else format += "g"; int v; if ((f & std::ios_base::scientific) && (f & std::ios_base::fixed)) { v = quadmath_snprintf(buf, sizeof buf, "%Qa", m_value); } else { v = quadmath_snprintf(buf, sizeof buf, format.c_str(), digits, m_value); } if ((v < 0) || (v >= 127)) { int v_max = v; std::unique_ptr buf2; buf2.reset(new char[v + 3]); v = quadmath_snprintf(&buf2[0], v_max + 3, format.c_str(), digits, m_value); if (v >= v_max + 3) { BOOST_THROW_EXCEPTION(std::runtime_error("Formatting of float128_type failed.")); } return &buf2[0]; } return buf; #else return boost::multiprecision::detail::convert_to_string(*this, digits ? digits : 37, f); #endif } BOOST_MP_CXX14_CONSTEXPR void negate() noexcept { m_value = -m_value; } BOOST_MP_CXX14_CONSTEXPR int compare(const float128_backend& o) const { return m_value == o.m_value ? 0 : m_value < o.m_value ? -1 : 1; } template BOOST_MP_CXX14_CONSTEXPR int compare(const T& i) const { return m_value == i ? 0 : m_value < i ? -1 : 1; } BOOST_MP_CXX14_CONSTEXPR float128_type& value() { return m_value; } BOOST_MP_CXX14_CONSTEXPR const float128_type& value() const { return m_value; } }; inline BOOST_MP_CXX14_CONSTEXPR void eval_add(float128_backend& result, const float128_backend& a) { result.value() += a.value(); } template inline BOOST_MP_CXX14_CONSTEXPR void eval_add(float128_backend& result, const A& a) { result.value() += a; } inline BOOST_MP_CXX14_CONSTEXPR void eval_subtract(float128_backend& result, const float128_backend& a) { result.value() -= a.value(); } template inline BOOST_MP_CXX14_CONSTEXPR void eval_subtract(float128_backend& result, const A& a) { result.value() -= a; } inline BOOST_MP_CXX14_CONSTEXPR void eval_multiply(float128_backend& result, const float128_backend& a) { result.value() *= a.value(); } template inline BOOST_MP_CXX14_CONSTEXPR void eval_multiply(float128_backend& result, const A& a) { result.value() *= a; } inline BOOST_MP_CXX14_CONSTEXPR void eval_divide(float128_backend& result, const float128_backend& a) { result.value() /= a.value(); } template inline BOOST_MP_CXX14_CONSTEXPR void eval_divide(float128_backend& result, const A& a) { result.value() /= a; } inline BOOST_MP_CXX14_CONSTEXPR void eval_add(float128_backend& result, const float128_backend& a, const float128_backend& b) { result.value() = a.value() + b.value(); } template inline BOOST_MP_CXX14_CONSTEXPR void eval_add(float128_backend& result, const float128_backend& a, const A& b) { result.value() = a.value() + b; } inline BOOST_MP_CXX14_CONSTEXPR void eval_subtract(float128_backend& result, const float128_backend& a, const float128_backend& b) { result.value() = a.value() - b.value(); } template inline BOOST_MP_CXX14_CONSTEXPR void eval_subtract(float128_backend& result, const float128_backend& a, const A& b) { result.value() = a.value() - b; } template inline BOOST_MP_CXX14_CONSTEXPR void eval_subtract(float128_backend& result, const A& a, const float128_backend& b) { result.value() = a - b.value(); } inline BOOST_MP_CXX14_CONSTEXPR void eval_multiply(float128_backend& result, const float128_backend& a, const float128_backend& b) { result.value() = a.value() * b.value(); } template inline BOOST_MP_CXX14_CONSTEXPR void eval_multiply(float128_backend& result, const float128_backend& a, const A& b) { result.value() = a.value() * b; } inline BOOST_MP_CXX14_CONSTEXPR void eval_divide(float128_backend& result, const float128_backend& a, const float128_backend& b) { result.value() = a.value() / b.value(); } template inline BOOST_MP_CXX14_CONSTEXPR void eval_convert_to(R* result, const float128_backend& val) { *result = static_cast(val.value()); } inline void eval_frexp(float128_backend& result, const float128_backend& arg, int* exp) { result.value() = frexpq(arg.value(), exp); } inline void eval_ldexp(float128_backend& result, const float128_backend& arg, int exp) { result.value() = ldexpq(arg.value(), exp); } inline void eval_floor(float128_backend& result, const float128_backend& arg) { result.value() = floorq(arg.value()); } inline void eval_ceil(float128_backend& result, const float128_backend& arg) { result.value() = ceilq(arg.value()); } inline void eval_sqrt(float128_backend& result, const float128_backend& arg) { result.value() = sqrtq(arg.value()); } inline void eval_rsqrt(float128_backend& result, const float128_backend& arg) { #if (LDBL_MANT_DIG > 100) // GCC can't mix and match __float128 and quad precision long double // error: __float128 and long double cannot be used in the same expression result.value() = 1 / sqrtq(arg.value()); #else using std::sqrt; if (arg.value() < std::numeric_limits::denorm_min() || arg.value() > (std::numeric_limits::max)()) { result.value() = 1/sqrtq(arg.value()); return; } float128_backend xk = 1/sqrt(static_cast(arg.value())); // Newton iteration for f(x) = arg.value() - 1/x^2. BOOST_IF_CONSTEXPR (sizeof(long double) == sizeof(double)) { // If the long double is the same as a double, then we need two Newton iterations: xk.value() = xk.value() + xk.value()*(1-arg.value()*xk.value()*xk.value())/2; result.value() = xk.value() + xk.value()*(1-arg.value()*xk.value()*xk.value())/2; } else { // 80 bit long double only needs a single iteration to produce ~2ULPs. result.value() = xk.value() + xk.value() * (1 - arg.value() * xk.value() * xk.value()) / 2; } #endif } #ifndef BOOST_MP_NO_CONSTEXPR_DETECTION inline BOOST_MP_CXX14_CONSTEXPR #else inline #endif int eval_fpclassify(const float128_backend& arg) { float128_type v = arg.value(); #ifndef BOOST_MP_NO_CONSTEXPR_DETECTION if (BOOST_MP_IS_CONST_EVALUATED(v)) { if (v != v) return FP_NAN; if (v == 0) return FP_ZERO; float128_type t(v); if (t < 0) t = -t; if (t > BOOST_MP_QUAD_MAX) return FP_INFINITE; if (t < BOOST_MP_QUAD_MIN) return FP_SUBNORMAL; return FP_NORMAL; } else #endif { if (isnanq(v)) return FP_NAN; else if (isinfq(v)) return FP_INFINITE; else if (v == 0) return FP_ZERO; float128_backend t(arg); if (t.value() < 0) t.negate(); if (t.value() < BOOST_MP_QUAD_MIN) return FP_SUBNORMAL; return FP_NORMAL; } } #if defined(BOOST_GCC) && (__GNUC__ == 9) // See https://gcc.gnu.org/bugzilla/show_bug.cgi?id=91705 inline BOOST_MP_CXX14_CONSTEXPR void eval_increment(float128_backend& arg) { arg.value() = 1 + arg.value(); } inline BOOST_MP_CXX14_CONSTEXPR void eval_decrement(float128_backend& arg) { arg.value() = arg.value() - 1; } #else inline BOOST_MP_CXX14_CONSTEXPR void eval_increment(float128_backend& arg) { ++arg.value(); } inline BOOST_MP_CXX14_CONSTEXPR void eval_decrement(float128_backend& arg) { --arg.value(); } #endif /********************************************************************* * * abs/fabs: * *********************************************************************/ #ifndef BOOST_MP_NO_CONSTEXPR_DETECTION inline BOOST_MP_CXX14_CONSTEXPR void eval_abs(float128_backend& result, const float128_backend& arg) #else inline void eval_abs(float128_backend& result, const float128_backend& arg) #endif { #ifndef BOOST_MP_NO_CONSTEXPR_DETECTION float128_type v(arg.value()); if (BOOST_MP_IS_CONST_EVALUATED(v)) { result.value() = v < 0 ? -v : v; } else #endif { result.value() = fabsq(arg.value()); } } #ifndef BOOST_MP_NO_CONSTEXPR_DETECTION inline BOOST_MP_CXX14_CONSTEXPR void eval_fabs(float128_backend& result, const float128_backend& arg) #else inline void eval_fabs(float128_backend& result, const float128_backend& arg) #endif { #ifndef BOOST_MP_NO_CONSTEXPR_DETECTION float128_type v(arg.value()); if (BOOST_MP_IS_CONST_EVALUATED(v)) { result.value() = v < 0 ? -v : v; } else #endif { result.value() = fabsq(arg.value()); } } /********************************************************************* * * Floating point functions: * *********************************************************************/ inline void eval_trunc(float128_backend& result, const float128_backend& arg) { result.value() = truncq(arg.value()); } /* // // This doesn't actually work... rely on our own default version instead. // inline void eval_round(float128_backend& result, const float128_backend& arg) { if(isnanq(arg.value()) || isinf(arg.value())) { result = boost::math::policies::raise_rounding_error( "boost::multiprecision::trunc<%1%>(%1%)", 0, number(arg), number(arg), boost::math::policies::policy<>()).backend(); return; } result.value() = roundq(arg.value()); } */ inline void eval_exp(float128_backend& result, const float128_backend& arg) { result.value() = expq(arg.value()); } inline void eval_log(float128_backend& result, const float128_backend& arg) { result.value() = logq(arg.value()); } inline void eval_log10(float128_backend& result, const float128_backend& arg) { result.value() = log10q(arg.value()); } inline void eval_sin(float128_backend& result, const float128_backend& arg) { result.value() = sinq(arg.value()); } inline void eval_cos(float128_backend& result, const float128_backend& arg) { result.value() = cosq(arg.value()); } inline void eval_tan(float128_backend& result, const float128_backend& arg) { result.value() = tanq(arg.value()); } inline void eval_asin(float128_backend& result, const float128_backend& arg) { result.value() = asinq(arg.value()); } inline void eval_acos(float128_backend& result, const float128_backend& arg) { result.value() = acosq(arg.value()); } inline void eval_atan(float128_backend& result, const float128_backend& arg) { result.value() = atanq(arg.value()); } inline void eval_sinh(float128_backend& result, const float128_backend& arg) { result.value() = sinhq(arg.value()); } inline void eval_cosh(float128_backend& result, const float128_backend& arg) { result.value() = coshq(arg.value()); } inline void eval_tanh(float128_backend& result, const float128_backend& arg) { result.value() = tanhq(arg.value()); } inline void eval_fmod(float128_backend& result, const float128_backend& a, const float128_backend& b) { result.value() = fmodq(a.value(), b.value()); } inline void eval_pow(float128_backend& result, const float128_backend& a, const float128_backend& b) { result.value() = powq(a.value(), b.value()); } inline void eval_atan2(float128_backend& result, const float128_backend& a, const float128_backend& b) { result.value() = atan2q(a.value(), b.value()); } #ifndef BOOST_MP_USE_QUAD inline void eval_multiply_add(float128_backend& result, const float128_backend& a, const float128_backend& b, const float128_backend& c) { result.value() = fmaq(a.value(), b.value(), c.value()); } inline int eval_signbit BOOST_PREVENT_MACRO_SUBSTITUTION(const float128_backend& arg) { return ::signbitq(arg.value()); } #endif inline std::size_t hash_value(const float128_backend& val) { return boost::multiprecision::detail::hash_value(static_cast(val.value())); } } // namespace backends template inline boost::multiprecision::number asinh BOOST_PREVENT_MACRO_SUBSTITUTION(const boost::multiprecision::number& arg) { return asinhq(arg.backend().value()); } template inline boost::multiprecision::number acosh BOOST_PREVENT_MACRO_SUBSTITUTION(const boost::multiprecision::number& arg) { return acoshq(arg.backend().value()); } template inline boost::multiprecision::number atanh BOOST_PREVENT_MACRO_SUBSTITUTION(const boost::multiprecision::number& arg) { return atanhq(arg.backend().value()); } template inline boost::multiprecision::number cbrt BOOST_PREVENT_MACRO_SUBSTITUTION(const boost::multiprecision::number& arg) { return cbrtq(arg.backend().value()); } template inline boost::multiprecision::number erf BOOST_PREVENT_MACRO_SUBSTITUTION(const boost::multiprecision::number& arg) { return erfq(arg.backend().value()); } template inline boost::multiprecision::number erfc BOOST_PREVENT_MACRO_SUBSTITUTION(const boost::multiprecision::number& arg) { return erfcq(arg.backend().value()); } template inline boost::multiprecision::number expm1 BOOST_PREVENT_MACRO_SUBSTITUTION(const boost::multiprecision::number& arg) { return expm1q(arg.backend().value()); } template inline boost::multiprecision::number lgamma BOOST_PREVENT_MACRO_SUBSTITUTION(const boost::multiprecision::number& arg) { return lgammaq(arg.backend().value()); } template inline boost::multiprecision::number tgamma BOOST_PREVENT_MACRO_SUBSTITUTION(const boost::multiprecision::number& arg) { if(eval_signbit(arg.backend()) != 0) { const bool result_is_neg = ((static_cast(floorq(-arg.backend().value())) % 2U) == 0U); const boost::multiprecision::number result_of_tgammaq = fabsq(tgammaq(arg.backend().value())); return ((result_is_neg == false) ? result_of_tgammaq : -result_of_tgammaq); } else { return tgammaq(arg.backend().value()); } } template inline boost::multiprecision::number log1p BOOST_PREVENT_MACRO_SUBSTITUTION(const boost::multiprecision::number& arg) { return log1pq(arg.backend().value()); } template inline boost::multiprecision::number rsqrt BOOST_PREVENT_MACRO_SUBSTITUTION(const boost::multiprecision::number& arg) { boost::multiprecision::number res; eval_rsqrt(res.backend(), arg.backend()); return res; } #ifndef BOOST_MP_USE_QUAD template inline boost::multiprecision::number copysign BOOST_PREVENT_MACRO_SUBSTITUTION(const boost::multiprecision::number& a, const boost::multiprecision::number& b) { return ::copysignq(a.backend().value(), b.backend().value()); } inline void eval_remainder(float128_backend& result, const float128_backend& a, const float128_backend& b) { result.value() = remainderq(a.value(), b.value()); } inline void eval_remainder(float128_backend& result, const float128_backend& a, const float128_backend& b, int* pi) { result.value() = remquoq(a.value(), b.value(), pi); } #endif } // namespace multiprecision namespace math { using boost::multiprecision::copysign; using boost::multiprecision::signbit; } // namespace math } // namespace boost namespace boost { namespace archive { class binary_oarchive; class binary_iarchive; } // namespace archive namespace serialization { namespace float128_detail { template void do_serialize(Archive& ar, boost::multiprecision::backends::float128_backend& val, const std::integral_constant&, const std::integral_constant&) { // saving // non-binary std::string s(val.str(0, std::ios_base::scientific)); ar& boost::make_nvp("value", s); } template void do_serialize(Archive& ar, boost::multiprecision::backends::float128_backend& val, const std::integral_constant&, const std::integral_constant&) { // loading // non-binary std::string s; ar& boost::make_nvp("value", s); val = s.c_str(); } template void do_serialize(Archive& ar, boost::multiprecision::backends::float128_backend& val, const std::integral_constant&, const std::integral_constant&) { // saving // binary ar.save_binary(&val, sizeof(val)); } template void do_serialize(Archive& ar, boost::multiprecision::backends::float128_backend& val, const std::integral_constant&, const std::integral_constant&) { // loading // binary ar.load_binary(&val, sizeof(val)); } } // namespace float128_detail template void serialize(Archive& ar, boost::multiprecision::backends::float128_backend& val, unsigned int /*version*/) { using load_tag = typename Archive::is_loading ; using loading = std::integral_constant ; using binary_tag = typename std::integral_constant::value || std::is_same::value>; float128_detail::do_serialize(ar, val, loading(), binary_tag()); } } // namespace serialization } // namespace boost namespace std { template class numeric_limits > { using number_type = boost::multiprecision::number; public: static constexpr bool is_specialized = true; static BOOST_MP_CXX14_CONSTEXPR number_type(min)() noexcept { return BOOST_MP_QUAD_MIN; } static BOOST_MP_CXX14_CONSTEXPR number_type(max)() noexcept { return BOOST_MP_QUAD_MAX; } static BOOST_MP_CXX14_CONSTEXPR number_type lowest() noexcept { return -(max)(); } static constexpr int digits = 113; static constexpr int digits10 = 33; static constexpr int max_digits10 = 36; static constexpr bool is_signed = true; static constexpr bool is_integer = false; static constexpr bool is_exact = false; static constexpr int radix = 2; static BOOST_MP_CXX14_CONSTEXPR number_type epsilon() { return 1.92592994438723585305597794258492732e-34; /* this double value has only one bit set and so is exact */ } static BOOST_MP_CXX14_CONSTEXPR number_type round_error() { return 0.5; } static constexpr int min_exponent = -16381; static constexpr int min_exponent10 = min_exponent * 301L / 1000L; static constexpr int max_exponent = 16384; static constexpr int max_exponent10 = max_exponent * 301L / 1000L; static constexpr bool has_infinity = true; static constexpr bool has_quiet_NaN = true; static constexpr bool has_signaling_NaN = false; static constexpr float_denorm_style has_denorm = denorm_present; static constexpr bool has_denorm_loss = true; static BOOST_MP_CXX14_CONSTEXPR number_type infinity() { return HUGE_VAL; /* conversion from double infinity OK */ } static BOOST_MP_CXX14_CONSTEXPR number_type quiet_NaN() { return number_type(NAN); } static BOOST_MP_CXX14_CONSTEXPR number_type signaling_NaN() { return 0; } static BOOST_MP_CXX14_CONSTEXPR number_type denorm_min() { return BOOST_MP_QUAD_DENORM_MIN; } static constexpr bool is_iec559 = true; static constexpr bool is_bounded = true; static constexpr bool is_modulo = false; static constexpr bool traps = false; static constexpr bool tinyness_before = false; static constexpr float_round_style round_style = round_to_nearest; }; template constexpr bool numeric_limits >::is_specialized; template constexpr int numeric_limits >::digits; template constexpr int numeric_limits >::digits10; template constexpr int numeric_limits >::max_digits10; template constexpr bool numeric_limits >::is_signed; template constexpr bool numeric_limits >::is_integer; template constexpr bool numeric_limits >::is_exact; template constexpr int numeric_limits >::radix; template constexpr int numeric_limits >::min_exponent; template constexpr int numeric_limits >::max_exponent; template constexpr int numeric_limits >::min_exponent10; template constexpr int numeric_limits >::max_exponent10; template constexpr bool numeric_limits >::has_infinity; template constexpr bool numeric_limits >::has_quiet_NaN; template constexpr bool numeric_limits >::has_signaling_NaN; template constexpr bool numeric_limits >::has_denorm_loss; template constexpr bool numeric_limits >::is_iec559; template constexpr bool numeric_limits >::is_bounded; template constexpr bool numeric_limits >::is_modulo; template constexpr bool numeric_limits >::traps; template constexpr bool numeric_limits >::tinyness_before; template constexpr float_round_style numeric_limits >::round_style; template constexpr float_denorm_style numeric_limits >::has_denorm; } // namespace std #endif