// Copyright John Maddock 2005-2008. // Copyright (c) 2006-2008 Johan Rade // Use, modification and distribution are subject to the // Boost Software License, Version 1.0. (See accompanying file // LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt) #ifndef BOOST_MATH_FPCLASSIFY_HPP #define BOOST_MATH_FPCLASSIFY_HPP #ifdef _MSC_VER #pragma once #endif #include #include #include #include #include #include #include /*! \file fpclassify.hpp \brief Classify floating-point value as normal, subnormal, zero, infinite, or NaN. \version 1.0 \author John Maddock */ /* 1. If the platform is C99 compliant, then the native floating point classification functions are used. However, note that we must only define the functions which call std::fpclassify etc if that function really does exist: otherwise a compiler may reject the code even though the template is never instantiated. 2. If the platform is not C99 compliant, and the binary format for a floating point type (float, double or long double) can be determined at compile time, then the following algorithm is used: If all exponent bits, the flag bit (if there is one), and all significand bits are 0, then the number is zero. If all exponent bits and the flag bit (if there is one) are 0, and at least one significand bit is 1, then the number is subnormal. If all exponent bits are 1 and all significand bits are 0, then the number is infinity. If all exponent bits are 1 and at least one significand bit is 1, then the number is a not-a-number. Otherwise the number is normal. This algorithm works for the IEEE 754 representation, and also for several non IEEE 754 formats. Most formats have the structure sign bit + exponent bits + significand bits. A few have the structure sign bit + exponent bits + flag bit + significand bits. The flag bit is 0 for zero and subnormal numbers, and 1 for normal numbers and NaN. It is 0 (Motorola 68K) or 1 (Intel) for infinity. To get the bits, the four or eight most significant bytes are copied into an uint32_t or uint64_t and bit masks are applied. This covers all the exponent bits and the flag bit (if there is one), but not always all the significand bits. Some of the functions below have two implementations, depending on whether all the significand bits are copied or not. 3. If the platform is not C99 compliant, and the binary format for a floating point type (float, double or long double) can not be determined at compile time, then comparison with std::numeric_limits values is used. */ #if defined(_MSC_VER) || defined(__BORLANDC__) #include #endif #ifdef BOOST_MATH_USE_FLOAT128 #ifdef __has_include #if __has_include("quadmath.h") #include "quadmath.h" #define BOOST_MATH_HAS_QUADMATH_H #endif #endif #endif #ifdef BOOST_NO_STDC_NAMESPACE namespace std{ using ::abs; using ::fabs; } #endif namespace lslboost{ // // This must not be located in any namespace under lslboost::math // otherwise we can get into an infinite loop if isnan is // a #define for "isnan" ! // namespace math_detail{ #ifdef BOOST_MSVC #pragma warning(push) #pragma warning(disable:4800) #endif template inline bool is_nan_helper(T t, const lslboost::true_type&) { #ifdef isnan return isnan(t); #elif defined(BOOST_MATH_DISABLE_STD_FPCLASSIFY) || !defined(BOOST_HAS_FPCLASSIFY) (void)t; return false; #else // BOOST_HAS_FPCLASSIFY return (BOOST_FPCLASSIFY_PREFIX fpclassify(t) == (int)FP_NAN); #endif } #ifdef BOOST_MSVC #pragma warning(pop) #endif template inline bool is_nan_helper(T, const lslboost::false_type&) { return false; } #if defined(BOOST_MATH_USE_FLOAT128) #if defined(BOOST_MATH_HAS_QUADMATH_H) inline bool is_nan_helper(__float128 f, const lslboost::true_type&) { return ::isnanq(f); } inline bool is_nan_helper(__float128 f, const lslboost::false_type&) { return ::isnanq(f); } #elif defined(BOOST_GNU_STDLIB) && BOOST_GNU_STDLIB && \ _GLIBCXX_USE_C99_MATH && !_GLIBCXX_USE_C99_FP_MACROS_DYNAMIC inline bool is_nan_helper(__float128 f, const lslboost::true_type&) { return std::isnan(static_cast(f)); } inline bool is_nan_helper(__float128 f, const lslboost::false_type&) { return std::isnan(static_cast(f)); } #else inline bool is_nan_helper(__float128 f, const lslboost::true_type&) { return ::isnan(static_cast(f)); } inline bool is_nan_helper(__float128 f, const lslboost::false_type&) { return ::isnan(static_cast(f)); } #endif #endif } namespace math{ namespace detail{ #ifdef BOOST_MATH_USE_STD_FPCLASSIFY template inline int fpclassify_imp BOOST_NO_MACRO_EXPAND(T t, const native_tag&) { return (std::fpclassify)(t); } #endif template inline int fpclassify_imp BOOST_NO_MACRO_EXPAND(T t, const generic_tag&) { BOOST_MATH_INSTRUMENT_VARIABLE(t); // whenever possible check for Nan's first: #if defined(BOOST_HAS_FPCLASSIFY) && !defined(BOOST_MATH_DISABLE_STD_FPCLASSIFY) if(::lslboost::math_detail::is_nan_helper(t, ::lslboost::is_floating_point())) return FP_NAN; #elif defined(isnan) if(lslboost::math_detail::is_nan_helper(t, ::lslboost::is_floating_point())) return FP_NAN; #elif defined(_MSC_VER) || defined(__BORLANDC__) if(::_isnan(lslboost::math::tools::real_cast(t))) return FP_NAN; #endif // std::fabs broken on a few systems especially for long long!!!! T at = (t < T(0)) ? -t : t; // Use a process of exclusion to figure out // what kind of type we have, this relies on // IEEE conforming reals that will treat // Nan's as unordered. Some compilers // don't do this once optimisations are // turned on, hence the check for nan's above. if(at <= (std::numeric_limits::max)()) { if(at >= (std::numeric_limits::min)()) return FP_NORMAL; return (at != 0) ? FP_SUBNORMAL : FP_ZERO; } else if(at > (std::numeric_limits::max)()) return FP_INFINITE; return FP_NAN; } template inline int fpclassify_imp BOOST_NO_MACRO_EXPAND(T t, const generic_tag&) { #ifdef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS if(std::numeric_limits::is_specialized) return fpclassify_imp(t, generic_tag()); #endif // // An unknown type with no numeric_limits support, // so what are we supposed to do we do here? // BOOST_MATH_INSTRUMENT_VARIABLE(t); return t == 0 ? FP_ZERO : FP_NORMAL; } template int fpclassify_imp BOOST_NO_MACRO_EXPAND(T x, ieee_copy_all_bits_tag) { typedef BOOST_DEDUCED_TYPENAME fp_traits::type traits; BOOST_MATH_INSTRUMENT_VARIABLE(x); BOOST_DEDUCED_TYPENAME traits::bits a; traits::get_bits(x,a); BOOST_MATH_INSTRUMENT_VARIABLE(a); a &= traits::exponent | traits::flag | traits::significand; BOOST_MATH_INSTRUMENT_VARIABLE((traits::exponent | traits::flag | traits::significand)); BOOST_MATH_INSTRUMENT_VARIABLE(a); if(a <= traits::significand) { if(a == 0) return FP_ZERO; else return FP_SUBNORMAL; } if(a < traits::exponent) return FP_NORMAL; a &= traits::significand; if(a == 0) return FP_INFINITE; return FP_NAN; } template int fpclassify_imp BOOST_NO_MACRO_EXPAND(T x, ieee_copy_leading_bits_tag) { typedef BOOST_DEDUCED_TYPENAME fp_traits::type traits; BOOST_MATH_INSTRUMENT_VARIABLE(x); BOOST_DEDUCED_TYPENAME traits::bits a; traits::get_bits(x,a); a &= traits::exponent | traits::flag | traits::significand; if(a <= traits::significand) { if(x == 0) return FP_ZERO; else return FP_SUBNORMAL; } if(a < traits::exponent) return FP_NORMAL; a &= traits::significand; traits::set_bits(x,a); if(x == 0) return FP_INFINITE; return FP_NAN; } #if defined(BOOST_MATH_USE_STD_FPCLASSIFY) && (defined(BOOST_MATH_NO_NATIVE_LONG_DOUBLE_FP_CLASSIFY) || defined(BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS)) inline int fpclassify_imp BOOST_NO_MACRO_EXPAND(long double t, const native_tag&) { return lslboost::math::detail::fpclassify_imp(t, generic_tag()); } #endif } // namespace detail template inline int fpclassify BOOST_NO_MACRO_EXPAND(T t) { typedef typename detail::fp_traits::type traits; typedef typename traits::method method; typedef typename tools::promote_args_permissive::type value_type; #ifdef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS if(std::numeric_limits::is_specialized && detail::is_generic_tag_false(static_cast(0))) return detail::fpclassify_imp(static_cast(t), detail::generic_tag()); return detail::fpclassify_imp(static_cast(t), method()); #else return detail::fpclassify_imp(static_cast(t), method()); #endif } #ifdef BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS template <> inline int fpclassify BOOST_NO_MACRO_EXPAND(long double t) { typedef detail::fp_traits::type traits; typedef traits::method method; typedef long double value_type; #ifdef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS if(std::numeric_limits::is_specialized && detail::is_generic_tag_false(static_cast(0))) return detail::fpclassify_imp(static_cast(t), detail::generic_tag()); return detail::fpclassify_imp(static_cast(t), method()); #else return detail::fpclassify_imp(static_cast(t), method()); #endif } #endif namespace detail { #ifdef BOOST_MATH_USE_STD_FPCLASSIFY template inline bool isfinite_impl(T x, native_tag const&) { return (std::isfinite)(x); } #endif template inline bool isfinite_impl(T x, generic_tag const&) { return x >= -(std::numeric_limits::max)() && x <= (std::numeric_limits::max)(); } template inline bool isfinite_impl(T x, generic_tag const&) { #ifdef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS if(std::numeric_limits::is_specialized) return isfinite_impl(x, generic_tag()); #endif (void)x; // warning suppression. return true; } template inline bool isfinite_impl(T x, ieee_tag const&) { typedef BOOST_DEDUCED_TYPENAME detail::fp_traits::type traits; BOOST_DEDUCED_TYPENAME traits::bits a; traits::get_bits(x,a); a &= traits::exponent; return a != traits::exponent; } #if defined(BOOST_MATH_USE_STD_FPCLASSIFY) && defined(BOOST_MATH_NO_NATIVE_LONG_DOUBLE_FP_CLASSIFY) inline bool isfinite_impl BOOST_NO_MACRO_EXPAND(long double t, const native_tag&) { return lslboost::math::detail::isfinite_impl(t, generic_tag()); } #endif } template inline bool (isfinite)(T x) { //!< \brief return true if floating-point type t is finite. typedef typename detail::fp_traits::type traits; typedef typename traits::method method; // typedef typename lslboost::is_floating_point::type fp_tag; typedef typename tools::promote_args_permissive::type value_type; return detail::isfinite_impl(static_cast(x), method()); } #ifdef BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS template<> inline bool (isfinite)(long double x) { //!< \brief return true if floating-point type t is finite. typedef detail::fp_traits::type traits; typedef traits::method method; //typedef lslboost::is_floating_point::type fp_tag; typedef long double value_type; return detail::isfinite_impl(static_cast(x), method()); } #endif //------------------------------------------------------------------------------ namespace detail { #ifdef BOOST_MATH_USE_STD_FPCLASSIFY template inline bool isnormal_impl(T x, native_tag const&) { return (std::isnormal)(x); } #endif template inline bool isnormal_impl(T x, generic_tag const&) { if(x < 0) x = -x; return x >= (std::numeric_limits::min)() && x <= (std::numeric_limits::max)(); } template inline bool isnormal_impl(T x, generic_tag const&) { #ifdef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS if(std::numeric_limits::is_specialized) return isnormal_impl(x, generic_tag()); #endif return !(x == 0); } template inline bool isnormal_impl(T x, ieee_tag const&) { typedef BOOST_DEDUCED_TYPENAME detail::fp_traits::type traits; BOOST_DEDUCED_TYPENAME traits::bits a; traits::get_bits(x,a); a &= traits::exponent | traits::flag; return (a != 0) && (a < traits::exponent); } #if defined(BOOST_MATH_USE_STD_FPCLASSIFY) && defined(BOOST_MATH_NO_NATIVE_LONG_DOUBLE_FP_CLASSIFY) inline bool isnormal_impl BOOST_NO_MACRO_EXPAND(long double t, const native_tag&) { return lslboost::math::detail::isnormal_impl(t, generic_tag()); } #endif } template inline bool (isnormal)(T x) { typedef typename detail::fp_traits::type traits; typedef typename traits::method method; //typedef typename lslboost::is_floating_point::type fp_tag; typedef typename tools::promote_args_permissive::type value_type; return detail::isnormal_impl(static_cast(x), method()); } #ifdef BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS template<> inline bool (isnormal)(long double x) { typedef detail::fp_traits::type traits; typedef traits::method method; //typedef lslboost::is_floating_point::type fp_tag; typedef long double value_type; return detail::isnormal_impl(static_cast(x), method()); } #endif //------------------------------------------------------------------------------ namespace detail { #ifdef BOOST_MATH_USE_STD_FPCLASSIFY template inline bool isinf_impl(T x, native_tag const&) { return (std::isinf)(x); } #endif template inline bool isinf_impl(T x, generic_tag const&) { (void)x; // in case the compiler thinks that x is unused because std::numeric_limits::has_infinity is false return std::numeric_limits::has_infinity && ( x == std::numeric_limits::infinity() || x == -std::numeric_limits::infinity()); } template inline bool isinf_impl(T x, generic_tag const&) { #ifdef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS if(std::numeric_limits::is_specialized) return isinf_impl(x, generic_tag()); #endif (void)x; // warning suppression. return false; } template inline bool isinf_impl(T x, ieee_copy_all_bits_tag const&) { typedef BOOST_DEDUCED_TYPENAME fp_traits::type traits; BOOST_DEDUCED_TYPENAME traits::bits a; traits::get_bits(x,a); a &= traits::exponent | traits::significand; return a == traits::exponent; } template inline bool isinf_impl(T x, ieee_copy_leading_bits_tag const&) { typedef BOOST_DEDUCED_TYPENAME fp_traits::type traits; BOOST_DEDUCED_TYPENAME traits::bits a; traits::get_bits(x,a); a &= traits::exponent | traits::significand; if(a != traits::exponent) return false; traits::set_bits(x,0); return x == 0; } #if defined(BOOST_MATH_USE_STD_FPCLASSIFY) && defined(BOOST_MATH_NO_NATIVE_LONG_DOUBLE_FP_CLASSIFY) inline bool isinf_impl BOOST_NO_MACRO_EXPAND(long double t, const native_tag&) { return lslboost::math::detail::isinf_impl(t, generic_tag()); } #endif } // namespace detail template inline bool (isinf)(T x) { typedef typename detail::fp_traits::type traits; typedef typename traits::method method; // typedef typename lslboost::is_floating_point::type fp_tag; typedef typename tools::promote_args_permissive::type value_type; return detail::isinf_impl(static_cast(x), method()); } #ifdef BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS template<> inline bool (isinf)(long double x) { typedef detail::fp_traits::type traits; typedef traits::method method; //typedef lslboost::is_floating_point::type fp_tag; typedef long double value_type; return detail::isinf_impl(static_cast(x), method()); } #endif #if defined(BOOST_MATH_USE_FLOAT128) && defined(BOOST_MATH_HAS_QUADMATH_H) template<> inline bool (isinf)(__float128 x) { return ::isinfq(x); } #endif //------------------------------------------------------------------------------ namespace detail { #ifdef BOOST_MATH_USE_STD_FPCLASSIFY template inline bool isnan_impl(T x, native_tag const&) { return (std::isnan)(x); } #endif template inline bool isnan_impl(T x, generic_tag const&) { return std::numeric_limits::has_infinity ? !(x <= std::numeric_limits::infinity()) : x != x; } template inline bool isnan_impl(T x, generic_tag const&) { #ifdef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS if(std::numeric_limits::is_specialized) return isnan_impl(x, generic_tag()); #endif (void)x; // warning suppression return false; } template inline bool isnan_impl(T x, ieee_copy_all_bits_tag const&) { typedef BOOST_DEDUCED_TYPENAME fp_traits::type traits; BOOST_DEDUCED_TYPENAME traits::bits a; traits::get_bits(x,a); a &= traits::exponent | traits::significand; return a > traits::exponent; } template inline bool isnan_impl(T x, ieee_copy_leading_bits_tag const&) { typedef BOOST_DEDUCED_TYPENAME fp_traits::type traits; BOOST_DEDUCED_TYPENAME traits::bits a; traits::get_bits(x,a); a &= traits::exponent | traits::significand; if(a < traits::exponent) return false; a &= traits::significand; traits::set_bits(x,a); return x != 0; } } // namespace detail template inline bool (isnan)(T x) { //!< \brief return true if floating-point type t is NaN (Not A Number). typedef typename detail::fp_traits::type traits; typedef typename traits::method method; // typedef typename lslboost::is_floating_point::type fp_tag; return detail::isnan_impl(x, method()); } #ifdef isnan template <> inline bool isnan BOOST_NO_MACRO_EXPAND(float t){ return ::lslboost::math_detail::is_nan_helper(t, lslboost::true_type()); } template <> inline bool isnan BOOST_NO_MACRO_EXPAND(double t){ return ::lslboost::math_detail::is_nan_helper(t, lslboost::true_type()); } template <> inline bool isnan BOOST_NO_MACRO_EXPAND(long double t){ return ::lslboost::math_detail::is_nan_helper(t, lslboost::true_type()); } #elif defined(BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS) template<> inline bool (isnan)(long double x) { //!< \brief return true if floating-point type t is NaN (Not A Number). typedef detail::fp_traits::type traits; typedef traits::method method; //typedef lslboost::is_floating_point::type fp_tag; return detail::isnan_impl(x, method()); } #endif #if defined(BOOST_MATH_USE_FLOAT128) && defined(BOOST_MATH_HAS_QUADMATH_H) template<> inline bool (isnan)(__float128 x) { return ::isnanq(x); } #endif } // namespace math } // namespace lslboost #endif // BOOST_MATH_FPCLASSIFY_HPP