qt-everywhere-src-5.15.1/qtbase/src/corelib/global/qnumeric_p.h - orbit - Git at Google

 /****************************************************************************
 **
 ** Copyright (C) 2019 The Qt Company Ltd.
 ** Copyright (C) 2018 Intel Corporation.
 ** Contact: https://www.qt.io/licensing/
 **
 ** This file is part of the QtCore module of the Qt Toolkit.
 **
 ** $QT_BEGIN_LICENSE:LGPL$
 ** Commercial License Usage
 ** Licensees holding valid commercial Qt licenses may use this file in
 ** accordance with the commercial license agreement provided with the
 ** Software or, alternatively, in accordance with the terms contained in
 ** a written agreement between you and The Qt Company. For licensing terms
 ** and conditions see https://www.qt.io/terms-conditions. For further
 ** information use the contact form at https://www.qt.io/contact-us.
 **
 ** GNU Lesser General Public License Usage
 ** Alternatively, this file may be used under the terms of the GNU Lesser
 ** General Public License version 3 as published by the Free Software
 ** Foundation and appearing in the file LICENSE.LGPL3 included in the
 ** packaging of this file. Please review the following information to
 ** ensure the GNU Lesser General Public License version 3 requirements
 ** will be met: https://www.gnu.org/licenses/lgpl-3.0.html.
 **
 ** GNU General Public License Usage
 ** Alternatively, this file may be used under the terms of the GNU
 ** General Public License version 2.0 or (at your option) the GNU General
 ** Public license version 3 or any later version approved by the KDE Free
 ** Qt Foundation. The licenses are as published by the Free Software
 ** Foundation and appearing in the file LICENSE.GPL2 and LICENSE.GPL3
 ** included in the packaging of this file. Please review the following
 ** information to ensure the GNU General Public License requirements will
 ** be met: https://www.gnu.org/licenses/gpl-2.0.html and
 ** https://www.gnu.org/licenses/gpl-3.0.html.
 **
 ** $QT_END_LICENSE$
 **
 ****************************************************************************/

 #ifndef QNUMERIC_P_H
 #define QNUMERIC_P_H

 //
 //  W A R N I N G
 //  -------------
 //
 // This file is not part of the Qt API.  It exists purely as an
 // implementation detail.  This header file may change from version to
 // version without notice, or even be removed.
 //
 // We mean it.
 //

 #include "QtCore/private/qglobal_p.h"
 #include <cmath>
 #include <limits>

 #if defined(Q_CC_MSVC)
 #  include <intrin.h>
 #  include <float.h>
 #  if defined(Q_PROCESSOR_X86_64) || defined(Q_PROCESSOR_ARM_64)
 #    define Q_INTRINSIC_MUL_OVERFLOW64
 #    define Q_UMULH(v1, v2) __umulh(v1, v2);
 #    define Q_SMULH(v1, v2) __mulh(v1, v2);
 #    pragma intrinsic(__umulh)
 #    pragma intrinsic(__mulh)
 #  endif
 #endif

 # if defined(Q_OS_INTEGRITY) && defined(Q_PROCESSOR_ARM_64)
 #include <arm64_ghs.h>
 #  define Q_INTRINSIC_MUL_OVERFLOW64
 #  define Q_UMULH(v1, v2) __MULUH64(v1, v2);
 #  define Q_SMULH(v1, v2) __MULSH64(v1, v2);
 #endif

 #if !defined(Q_CC_MSVC) && (defined(Q_OS_QNX) || defined(Q_CC_INTEL))
 #  include <math.h>
 #  ifdef isnan
 #    define QT_MATH_H_DEFINES_MACROS
 QT_BEGIN_NAMESPACE
 namespace qnumeric_std_wrapper {
 // the 'using namespace std' below is cases where the stdlib already put the math.h functions in the std namespace and undefined the macros.
 Q_DECL_CONST_FUNCTION static inline bool math_h_isnan(double d) { using namespace std; return isnan(d); }
 Q_DECL_CONST_FUNCTION static inline bool math_h_isinf(double d) { using namespace std; return isinf(d); }
 Q_DECL_CONST_FUNCTION static inline bool math_h_isfinite(double d) { using namespace std; return isfinite(d); }
 Q_DECL_CONST_FUNCTION static inline int math_h_fpclassify(double d) { using namespace std; return fpclassify(d); }
 Q_DECL_CONST_FUNCTION static inline bool math_h_isnan(float f) { using namespace std; return isnan(f); }
 Q_DECL_CONST_FUNCTION static inline bool math_h_isinf(float f) { using namespace std; return isinf(f); }
 Q_DECL_CONST_FUNCTION static inline bool math_h_isfinite(float f) { using namespace std; return isfinite(f); }
 Q_DECL_CONST_FUNCTION static inline int math_h_fpclassify(float f) { using namespace std; return fpclassify(f); }
 }
 QT_END_NAMESPACE
 // These macros from math.h conflict with the real functions in the std namespace.
 #    undef signbit
 #    undef isnan
 #    undef isinf
 #    undef isfinite
 #    undef fpclassify
 #  endif // defined(isnan)
 #endif

 QT_BEGIN_NAMESPACE

 namespace qnumeric_std_wrapper {
 #if defined(QT_MATH_H_DEFINES_MACROS)
 #  undef QT_MATH_H_DEFINES_MACROS
 Q_DECL_CONST_FUNCTION static inline bool isnan(double d) { return math_h_isnan(d); }
 Q_DECL_CONST_FUNCTION static inline bool isinf(double d) { return math_h_isinf(d); }
 Q_DECL_CONST_FUNCTION static inline bool isfinite(double d) { return math_h_isfinite(d); }
 Q_DECL_CONST_FUNCTION static inline int fpclassify(double d) { return math_h_fpclassify(d); }
 Q_DECL_CONST_FUNCTION static inline bool isnan(float f) { return math_h_isnan(f); }
 Q_DECL_CONST_FUNCTION static inline bool isinf(float f) { return math_h_isinf(f); }
 Q_DECL_CONST_FUNCTION static inline bool isfinite(float f) { return math_h_isfinite(f); }
 Q_DECL_CONST_FUNCTION static inline int fpclassify(float f) { return math_h_fpclassify(f); }
 #else
 Q_DECL_CONST_FUNCTION static inline bool isnan(double d) { return std::isnan(d); }
 Q_DECL_CONST_FUNCTION static inline bool isinf(double d) { return std::isinf(d); }
 Q_DECL_CONST_FUNCTION static inline bool isfinite(double d) { return std::isfinite(d); }
 Q_DECL_CONST_FUNCTION static inline int fpclassify(double d) { return std::fpclassify(d); }
 Q_DECL_CONST_FUNCTION static inline bool isnan(float f) { return std::isnan(f); }
 Q_DECL_CONST_FUNCTION static inline bool isinf(float f) { return std::isinf(f); }
 Q_DECL_CONST_FUNCTION static inline bool isfinite(float f) { return std::isfinite(f); }
 Q_DECL_CONST_FUNCTION static inline int fpclassify(float f) { return std::fpclassify(f); }
 #endif
 }

 Q_DECL_CONSTEXPR Q_DECL_CONST_FUNCTION static inline double qt_inf() noexcept
 {
     Q_STATIC_ASSERT_X(std::numeric_limits<double>::has_infinity,
                       "platform has no definition for infinity for type double");
     return std::numeric_limits<double>::infinity();
 }

 #if QT_CONFIG(signaling_nan)
 Q_DECL_CONSTEXPR Q_DECL_CONST_FUNCTION static inline double qt_snan() noexcept
 {
     Q_STATIC_ASSERT_X(std::numeric_limits<double>::has_signaling_NaN,
                       "platform has no definition for signaling NaN for type double");
     return std::numeric_limits<double>::signaling_NaN();
 }
 #endif

 // Quiet NaN
 Q_DECL_CONSTEXPR Q_DECL_CONST_FUNCTION static inline double qt_qnan() noexcept
 {
     Q_STATIC_ASSERT_X(std::numeric_limits<double>::has_quiet_NaN,
                       "platform has no definition for quiet NaN for type double");
     return std::numeric_limits<double>::quiet_NaN();
 }

 Q_DECL_CONST_FUNCTION static inline bool qt_is_inf(double d)
 {
     return qnumeric_std_wrapper::isinf(d);
 }

 Q_DECL_CONST_FUNCTION static inline bool qt_is_nan(double d)
 {
     return qnumeric_std_wrapper::isnan(d);
 }

 Q_DECL_CONST_FUNCTION static inline bool qt_is_finite(double d)
 {
     return qnumeric_std_wrapper::isfinite(d);
 }

 Q_DECL_CONST_FUNCTION static inline int qt_fpclassify(double d)
 {
     return qnumeric_std_wrapper::fpclassify(d);
 }

 Q_DECL_CONST_FUNCTION static inline bool qt_is_inf(float f)
 {
     return qnumeric_std_wrapper::isinf(f);
 }

 Q_DECL_CONST_FUNCTION static inline bool qt_is_nan(float f)
 {
     return qnumeric_std_wrapper::isnan(f);
 }

 Q_DECL_CONST_FUNCTION static inline bool qt_is_finite(float f)
 {
     return qnumeric_std_wrapper::isfinite(f);
 }

 Q_DECL_CONST_FUNCTION static inline int qt_fpclassify(float f)
 {
     return qnumeric_std_wrapper::fpclassify(f);
 }

 #ifndef Q_CLANG_QDOC
 namespace {
 /*!
     Returns true if the double \a v can be converted to type \c T, false if
     it's out of range. If the conversion is successful, the converted value is
     stored in \a value; if it was not successful, \a value will contain the
     minimum or maximum of T, depending on the sign of \a d. If \c T is
     unsigned, then \a value contains the absolute value of \a v.

     This function works for v containing infinities, but not NaN. It's the
     caller's responsibility to exclude that possibility before calling it.
 */
 template <typename T> static inline bool convertDoubleTo(double v, T *value)
 {
     Q_STATIC_ASSERT(std::numeric_limits<T>::is_integer);

     // The [conv.fpint] (7.10 Floating-integral conversions) section of the C++
     // standard says only exact conversions are guaranteed. Converting
     // integrals to floating-point with loss of precision has implementation-
     // defined behavior whether the next higher or next lower is returned;
     // converting FP to integral is UB if it can't be represented.
     //
     // That means we can't write UINT64_MAX+1. Writing ldexp(1, 64) would be
     // correct, but Clang, ICC and MSVC don't realize that it's a constant and
     // the math call stays in the compiled code.

     double supremum;
     if (std::numeric_limits<T>::is_signed) {
         supremum = -1.0 * std::numeric_limits<T>::min();    // -1 * (-2^63) = 2^63, exact (for T = qint64)
         *value = std::numeric_limits<T>::min();
         if (v < std::numeric_limits<T>::min())
             return false;
     } else {
         using ST = typename std::make_signed<T>::type;
         supremum = -2.0 * std::numeric_limits<ST>::min();   // -2 * (-2^63) = 2^64, exact (for T = quint64)
         v = fabs(v);
     }

     *value = std::numeric_limits<T>::max();
     if (v >= supremum)
         return false;

     // Now we can convert, these two conversions cannot be UB
     *value = T(v);

 QT_WARNING_PUSH
 QT_WARNING_DISABLE_GCC("-Wfloat-equal")
 QT_WARNING_DISABLE_CLANG("-Wfloat-equal")

     return *value == v;

 QT_WARNING_POP
 }

 // Overflow math.
 // This provides efficient implementations for int, unsigned, qsizetype and
 // size_t. Implementations for 8- and 16-bit types will work but may not be as
 // efficient. Implementations for 64-bit may be missing on 32-bit platforms.

 #if ((defined(Q_CC_INTEL) ? (Q_CC_INTEL >= 1800 && !defined(Q_OS_WIN)) : defined(Q_CC_GNU)) \
      && Q_CC_GNU >= 500) || __has_builtin(__builtin_add_overflow)
 // GCC 5, ICC 18, and Clang 3.8 have builtins to detect overflows

 template <typename T> inline
 typename std::enable_if<std::is_unsigned<T>::value || std::is_signed<T>::value, bool>::type
 add_overflow(T v1, T v2, T *r)
 { return __builtin_add_overflow(v1, v2, r); }

 template <typename T> inline
 typename std::enable_if<std::is_unsigned<T>::value || std::is_signed<T>::value, bool>::type
 sub_overflow(T v1, T v2, T *r)
 { return __builtin_sub_overflow(v1, v2, r); }

 template <typename T> inline
 typename std::enable_if<std::is_unsigned<T>::value || std::is_signed<T>::value, bool>::type
 mul_overflow(T v1, T v2, T *r)
 { return __builtin_mul_overflow(v1, v2, r); }

 #else
 // Generic implementations

 template <typename T> inline typename std::enable_if<std::is_unsigned<T>::value, bool>::type
 add_overflow(T v1, T v2, T *r)
 {
     // unsigned additions are well-defined
     *r = v1 + v2;
     return v1 > T(v1 + v2);
 }

 template <typename T> inline typename std::enable_if<std::is_signed<T>::value, bool>::type
 add_overflow(T v1, T v2, T *r)
 {
     // Here's how we calculate the overflow:
     // 1) unsigned addition is well-defined, so we can always execute it
     // 2) conversion from unsigned back to signed is implementation-
     //    defined and in the implementations we use, it's a no-op.
     // 3) signed integer overflow happens if the sign of the two input operands
     //    is the same but the sign of the result is different. In other words,
     //    the sign of the result must be the same as the sign of either
     //    operand.

     using U = typename std::make_unsigned<T>::type;
     *r = T(U(v1) + U(v2));

     // If int is two's complement, assume all integer types are too.
     if (std::is_same<int32_t, int>::value) {
         // Two's complement equivalent (generates slightly shorter code):
         //  x ^ y             is negative if x and y have different signs
         //  x & y             is negative if x and y are negative
         // (x ^ z) & (y ^ z)  is negative if x and z have different signs
         //                    AND y and z have different signs
         return ((v1 ^ *r) & (v2 ^ *r)) < 0;
     }

     bool s1 = (v1 < 0);
     bool s2 = (v2 < 0);
     bool sr = (*r < 0);
     return s1 != sr && s2 != sr;
     // also: return s1 == s2 && s1 != sr;
 }

 template <typename T> inline typename std::enable_if<std::is_unsigned<T>::value, bool>::type
 sub_overflow(T v1, T v2, T *r)
 {
     // unsigned subtractions are well-defined
     *r = v1 - v2;
     return v1 < v2;
 }

 template <typename T> inline typename std::enable_if<std::is_signed<T>::value, bool>::type
 sub_overflow(T v1, T v2, T *r)
 {
     // See above for explanation. This is the same with some signs reversed.
     // We can't use add_overflow(v1, -v2, r) because it would be UB if
     // v2 == std::numeric_limits<T>::min().

     using U = typename std::make_unsigned<T>::type;
     *r = T(U(v1) - U(v2));

     if (std::is_same<int32_t, int>::value)
         return ((v1 ^ *r) & (~v2 ^ *r)) < 0;

     bool s1 = (v1 < 0);
     bool s2 = !(v2 < 0);
     bool sr = (*r < 0);
     return s1 != sr && s2 != sr;
     // also: return s1 == s2 && s1 != sr;
 }

 template <typename T> inline
 typename std::enable_if<std::is_unsigned<T>::value || std::is_signed<T>::value, bool>::type
 mul_overflow(T v1, T v2, T *r)
 {
     // use the next biggest type
     // Note: for 64-bit systems where __int128 isn't supported, this will cause an error.
     using LargerInt = QIntegerForSize<sizeof(T) * 2>;
     using Larger = typename std::conditional<std::is_signed<T>::value,
             typename LargerInt::Signed, typename LargerInt::Unsigned>::type;
     Larger lr = Larger(v1) * Larger(v2);
     *r = T(lr);
     return lr > std::numeric_limits<T>::max() || lr < std::numeric_limits<T>::min();
 }

 # if defined(Q_INTRINSIC_MUL_OVERFLOW64)
 template <> inline bool mul_overflow(quint64 v1, quint64 v2, quint64 *r)
 {
     *r = v1 * v2;
     return Q_UMULH(v1, v2);
 }
 template <> inline bool mul_overflow(qint64 v1, qint64 v2, qint64 *r)
 {
     // This is slightly more complex than the unsigned case above: the sign bit
     // of 'low' must be replicated as the entire 'high', so the only valid
     // values for 'high' are 0 and -1. Use unsigned multiply since it's the same
     // as signed for the low bits and use a signed right shift to verify that
     // 'high' is nothing but sign bits that match the sign of 'low'.

     qint64 high = Q_SMULH(v1, v2);
     *r = qint64(quint64(v1) * quint64(v2));
     return (*r >> 63) != high;
 }

 #   if defined(Q_OS_INTEGRITY) && defined(Q_PROCESSOR_ARM_64)
 template <> inline bool mul_overflow(uint64_t v1, uint64_t v2, uint64_t *r)
 {
     return mul_overflow<quint64>(v1,v2,reinterpret_cast<quint64*>(r));
 }

 template <> inline bool mul_overflow(int64_t v1, int64_t v2, int64_t *r)
 {
     return mul_overflow<qint64>(v1,v2,reinterpret_cast<qint64*>(r));
 }
 #    endif // OS_INTEGRITY ARM64
 #  endif // Q_INTRINSIC_MUL_OVERFLOW64

 #  if defined(Q_CC_MSVC) && defined(Q_PROCESSOR_X86)
 // We can use intrinsics for the unsigned operations with MSVC
 template <> inline bool add_overflow(unsigned v1, unsigned v2, unsigned *r)
 { return _addcarry_u32(0, v1, v2, r); }

 // 32-bit mul_overflow is fine with the generic code above

 template <> inline bool add_overflow(quint64 v1, quint64 v2, quint64 *r)
 {
 #    if defined(Q_PROCESSOR_X86_64)
     return _addcarry_u64(0, v1, v2, reinterpret_cast<unsigned __int64 *>(r));
 #    else
     uint low, high;
     uchar carry = _addcarry_u32(0, unsigned(v1), unsigned(v2), &low);
     carry = _addcarry_u32(carry, v1 >> 32, v2 >> 32, &high);
     *r = (quint64(high) << 32) | low;
     return carry;
 #    endif // !x86-64
 }
 #  endif // MSVC X86
 #endif // !GCC
 }
 #endif // Q_CLANG_QDOC

 QT_END_NAMESPACE

 #endif // QNUMERIC_P_H
	/****************************************************************************
	**
	** Copyright (C) 2019 The Qt Company Ltd.
	** Copyright (C) 2018 Intel Corporation.
	** Contact: https://www.qt.io/licensing/
	**
	** This file is part of the QtCore module of the Qt Toolkit.
	**
	** $QT_BEGIN_LICENSE:LGPL$
	** Commercial License Usage
	** Licensees holding valid commercial Qt licenses may use this file in
	** accordance with the commercial license agreement provided with the
	** Software or, alternatively, in accordance with the terms contained in
	** a written agreement between you and The Qt Company. For licensing terms
	** and conditions see https://www.qt.io/terms-conditions. For further
	** information use the contact form at https://www.qt.io/contact-us.
	**
	** GNU Lesser General Public License Usage
	** Alternatively, this file may be used under the terms of the GNU Lesser
	** General Public License version 3 as published by the Free Software
	** Foundation and appearing in the file LICENSE.LGPL3 included in the
	** packaging of this file. Please review the following information to
	** ensure the GNU Lesser General Public License version 3 requirements
	** will be met: https://www.gnu.org/licenses/lgpl-3.0.html.
	**
	** GNU General Public License Usage
	** Alternatively, this file may be used under the terms of the GNU
	** General Public License version 2.0 or (at your option) the GNU General
	** Public license version 3 or any later version approved by the KDE Free
	** Qt Foundation. The licenses are as published by the Free Software
	** Foundation and appearing in the file LICENSE.GPL2 and LICENSE.GPL3
	** included in the packaging of this file. Please review the following
	** information to ensure the GNU General Public License requirements will
	** be met: https://www.gnu.org/licenses/gpl-2.0.html and
	** https://www.gnu.org/licenses/gpl-3.0.html.
	**
	** $QT_END_LICENSE$
	**
	****************************************************************************/

	#ifndef QNUMERIC_P_H
	#define QNUMERIC_P_H

	//
	// W A R N I N G
	// -------------
	//
	// This file is not part of the Qt API. It exists purely as an
	// implementation detail. This header file may change from version to
	// version without notice, or even be removed.
	//
	// We mean it.
	//

	#include "QtCore/private/qglobal_p.h"
	#include <cmath>
	#include <limits>

	#if defined(Q_CC_MSVC)
	# include <intrin.h>
	# include <float.h>
	# if defined(Q_PROCESSOR_X86_64) \|\| defined(Q_PROCESSOR_ARM_64)
	# define Q_INTRINSIC_MUL_OVERFLOW64
	# define Q_UMULH(v1, v2) __umulh(v1, v2);
	# define Q_SMULH(v1, v2) __mulh(v1, v2);
	# pragma intrinsic(__umulh)
	# pragma intrinsic(__mulh)
	# endif
	#endif

	# if defined(Q_OS_INTEGRITY) && defined(Q_PROCESSOR_ARM_64)
	#include <arm64_ghs.h>
	# define Q_INTRINSIC_MUL_OVERFLOW64
	# define Q_UMULH(v1, v2) __MULUH64(v1, v2);
	# define Q_SMULH(v1, v2) __MULSH64(v1, v2);
	#endif

	#if !defined(Q_CC_MSVC) && (defined(Q_OS_QNX) \|\| defined(Q_CC_INTEL))
	# include <math.h>
	# ifdef isnan
	# define QT_MATH_H_DEFINES_MACROS
	QT_BEGIN_NAMESPACE
	namespace qnumeric_std_wrapper {
	// the 'using namespace std' below is cases where the stdlib already put the math.h functions in the std namespace and undefined the macros.
	Q_DECL_CONST_FUNCTION static inline bool math_h_isnan(double d) { using namespace std; return isnan(d); }
	Q_DECL_CONST_FUNCTION static inline bool math_h_isinf(double d) { using namespace std; return isinf(d); }
	Q_DECL_CONST_FUNCTION static inline bool math_h_isfinite(double d) { using namespace std; return isfinite(d); }
	Q_DECL_CONST_FUNCTION static inline int math_h_fpclassify(double d) { using namespace std; return fpclassify(d); }
	Q_DECL_CONST_FUNCTION static inline bool math_h_isnan(float f) { using namespace std; return isnan(f); }
	Q_DECL_CONST_FUNCTION static inline bool math_h_isinf(float f) { using namespace std; return isinf(f); }
	Q_DECL_CONST_FUNCTION static inline bool math_h_isfinite(float f) { using namespace std; return isfinite(f); }
	Q_DECL_CONST_FUNCTION static inline int math_h_fpclassify(float f) { using namespace std; return fpclassify(f); }
	}
	QT_END_NAMESPACE
	// These macros from math.h conflict with the real functions in the std namespace.
	# undef signbit
	# undef isnan
	# undef isinf
	# undef isfinite
	# undef fpclassify
	# endif // defined(isnan)
	#endif

	QT_BEGIN_NAMESPACE

	namespace qnumeric_std_wrapper {
	#if defined(QT_MATH_H_DEFINES_MACROS)
	# undef QT_MATH_H_DEFINES_MACROS
	Q_DECL_CONST_FUNCTION static inline bool isnan(double d) { return math_h_isnan(d); }
	Q_DECL_CONST_FUNCTION static inline bool isinf(double d) { return math_h_isinf(d); }
	Q_DECL_CONST_FUNCTION static inline bool isfinite(double d) { return math_h_isfinite(d); }
	Q_DECL_CONST_FUNCTION static inline int fpclassify(double d) { return math_h_fpclassify(d); }
	Q_DECL_CONST_FUNCTION static inline bool isnan(float f) { return math_h_isnan(f); }
	Q_DECL_CONST_FUNCTION static inline bool isinf(float f) { return math_h_isinf(f); }
	Q_DECL_CONST_FUNCTION static inline bool isfinite(float f) { return math_h_isfinite(f); }
	Q_DECL_CONST_FUNCTION static inline int fpclassify(float f) { return math_h_fpclassify(f); }
	#else
	Q_DECL_CONST_FUNCTION static inline bool isnan(double d) { return std::isnan(d); }
	Q_DECL_CONST_FUNCTION static inline bool isinf(double d) { return std::isinf(d); }
	Q_DECL_CONST_FUNCTION static inline bool isfinite(double d) { return std::isfinite(d); }
	Q_DECL_CONST_FUNCTION static inline int fpclassify(double d) { return std::fpclassify(d); }
	Q_DECL_CONST_FUNCTION static inline bool isnan(float f) { return std::isnan(f); }
	Q_DECL_CONST_FUNCTION static inline bool isinf(float f) { return std::isinf(f); }
	Q_DECL_CONST_FUNCTION static inline bool isfinite(float f) { return std::isfinite(f); }
	Q_DECL_CONST_FUNCTION static inline int fpclassify(float f) { return std::fpclassify(f); }
	#endif
	}

	Q_DECL_CONSTEXPR Q_DECL_CONST_FUNCTION static inline double qt_inf() noexcept
	{
	Q_STATIC_ASSERT_X(std::numeric_limits<double>::has_infinity,
	"platform has no definition for infinity for type double");
	return std::numeric_limits<double>::infinity();
	}

	#if QT_CONFIG(signaling_nan)
	Q_DECL_CONSTEXPR Q_DECL_CONST_FUNCTION static inline double qt_snan() noexcept
	{
	Q_STATIC_ASSERT_X(std::numeric_limits<double>::has_signaling_NaN,
	"platform has no definition for signaling NaN for type double");
	return std::numeric_limits<double>::signaling_NaN();
	}
	#endif

	// Quiet NaN
	Q_DECL_CONSTEXPR Q_DECL_CONST_FUNCTION static inline double qt_qnan() noexcept
	{
	Q_STATIC_ASSERT_X(std::numeric_limits<double>::has_quiet_NaN,
	"platform has no definition for quiet NaN for type double");
	return std::numeric_limits<double>::quiet_NaN();
	}

	Q_DECL_CONST_FUNCTION static inline bool qt_is_inf(double d)
	{
	return qnumeric_std_wrapper::isinf(d);
	}

	Q_DECL_CONST_FUNCTION static inline bool qt_is_nan(double d)
	{
	return qnumeric_std_wrapper::isnan(d);
	}

	Q_DECL_CONST_FUNCTION static inline bool qt_is_finite(double d)
	{
	return qnumeric_std_wrapper::isfinite(d);
	}

	Q_DECL_CONST_FUNCTION static inline int qt_fpclassify(double d)
	{
	return qnumeric_std_wrapper::fpclassify(d);
	}

	Q_DECL_CONST_FUNCTION static inline bool qt_is_inf(float f)
	{
	return qnumeric_std_wrapper::isinf(f);
	}

	Q_DECL_CONST_FUNCTION static inline bool qt_is_nan(float f)
	{
	return qnumeric_std_wrapper::isnan(f);
	}

	Q_DECL_CONST_FUNCTION static inline bool qt_is_finite(float f)
	{
	return qnumeric_std_wrapper::isfinite(f);
	}

	Q_DECL_CONST_FUNCTION static inline int qt_fpclassify(float f)
	{
	return qnumeric_std_wrapper::fpclassify(f);
	}

	#ifndef Q_CLANG_QDOC
	namespace {
	/*!
	Returns true if the double \a v can be converted to type \c T, false if
	it's out of range. If the conversion is successful, the converted value is
	stored in \a value; if it was not successful, \a value will contain the
	minimum or maximum of T, depending on the sign of \a d. If \c T is
	unsigned, then \a value contains the absolute value of \a v.

	This function works for v containing infinities, but not NaN. It's the
	caller's responsibility to exclude that possibility before calling it.
	*/
	template <typename T> static inline bool convertDoubleTo(double v, T *value)
	{
	Q_STATIC_ASSERT(std::numeric_limits<T>::is_integer);

	// The [conv.fpint] (7.10 Floating-integral conversions) section of the C++
	// standard says only exact conversions are guaranteed. Converting
	// integrals to floating-point with loss of precision has implementation-
	// defined behavior whether the next higher or next lower is returned;
	// converting FP to integral is UB if it can't be represented.
	//
	// That means we can't write UINT64_MAX+1. Writing ldexp(1, 64) would be
	// correct, but Clang, ICC and MSVC don't realize that it's a constant and
	// the math call stays in the compiled code.

	double supremum;
	if (std::numeric_limits<T>::is_signed) {
	supremum = -1.0 * std::numeric_limits<T>::min(); // -1 * (-2^63) = 2^63, exact (for T = qint64)
	*value = std::numeric_limits<T>::min();
	if (v < std::numeric_limits<T>::min())
	return false;
	} else {
	using ST = typename std::make_signed<T>::type;
	supremum = -2.0 * std::numeric_limits<ST>::min(); // -2 * (-2^63) = 2^64, exact (for T = quint64)
	v = fabs(v);
	}

	*value = std::numeric_limits<T>::max();
	if (v >= supremum)
	return false;

	// Now we can convert, these two conversions cannot be UB
	*value = T(v);

	QT_WARNING_PUSH
	QT_WARNING_DISABLE_GCC("-Wfloat-equal")
	QT_WARNING_DISABLE_CLANG("-Wfloat-equal")

	return *value == v;

	QT_WARNING_POP
	}

	// Overflow math.
	// This provides efficient implementations for int, unsigned, qsizetype and
	// size_t. Implementations for 8- and 16-bit types will work but may not be as
	// efficient. Implementations for 64-bit may be missing on 32-bit platforms.

	#if ((defined(Q_CC_INTEL) ? (Q_CC_INTEL >= 1800 && !defined(Q_OS_WIN)) : defined(Q_CC_GNU)) \
	&& Q_CC_GNU >= 500) \|\| __has_builtin(__builtin_add_overflow)
	// GCC 5, ICC 18, and Clang 3.8 have builtins to detect overflows

	template <typename T> inline
	typename std::enable_if<std::is_unsigned<T>::value \|\| std::is_signed<T>::value, bool>::type
	add_overflow(T v1, T v2, T *r)
	{ return __builtin_add_overflow(v1, v2, r); }

	template <typename T> inline
	typename std::enable_if<std::is_unsigned<T>::value \|\| std::is_signed<T>::value, bool>::type
	sub_overflow(T v1, T v2, T *r)
	{ return __builtin_sub_overflow(v1, v2, r); }

	template <typename T> inline
	typename std::enable_if<std::is_unsigned<T>::value \|\| std::is_signed<T>::value, bool>::type
	mul_overflow(T v1, T v2, T *r)
	{ return __builtin_mul_overflow(v1, v2, r); }

	#else
	// Generic implementations

	template <typename T> inline typename std::enable_if<std::is_unsigned<T>::value, bool>::type
	add_overflow(T v1, T v2, T *r)
	{
	// unsigned additions are well-defined
	*r = v1 + v2;
	return v1 > T(v1 + v2);
	}

	template <typename T> inline typename std::enable_if<std::is_signed<T>::value, bool>::type
	add_overflow(T v1, T v2, T *r)
	{
	// Here's how we calculate the overflow:
	// 1) unsigned addition is well-defined, so we can always execute it
	// 2) conversion from unsigned back to signed is implementation-
	// defined and in the implementations we use, it's a no-op.
	// 3) signed integer overflow happens if the sign of the two input operands
	// is the same but the sign of the result is different. In other words,
	// the sign of the result must be the same as the sign of either
	// operand.

	using U = typename std::make_unsigned<T>::type;
	*r = T(U(v1) + U(v2));

	// If int is two's complement, assume all integer types are too.
	if (std::is_same<int32_t, int>::value) {
	// Two's complement equivalent (generates slightly shorter code):
	// x ^ y is negative if x and y have different signs
	// x & y is negative if x and y are negative
	// (x ^ z) & (y ^ z) is negative if x and z have different signs
	// AND y and z have different signs
	return ((v1 ^ r) & (v2 ^ r)) < 0;
	}

	bool s1 = (v1 < 0);
	bool s2 = (v2 < 0);
	bool sr = (*r < 0);
	return s1 != sr && s2 != sr;
	// also: return s1 == s2 && s1 != sr;
	}

	template <typename T> inline typename std::enable_if<std::is_unsigned<T>::value, bool>::type
	sub_overflow(T v1, T v2, T *r)
	{
	// unsigned subtractions are well-defined
	*r = v1 - v2;
	return v1 < v2;
	}

	template <typename T> inline typename std::enable_if<std::is_signed<T>::value, bool>::type
	sub_overflow(T v1, T v2, T *r)
	{
	// See above for explanation. This is the same with some signs reversed.
	// We can't use add_overflow(v1, -v2, r) because it would be UB if
	// v2 == std::numeric_limits<T>::min().

	using U = typename std::make_unsigned<T>::type;
	*r = T(U(v1) - U(v2));

	if (std::is_same<int32_t, int>::value)
	return ((v1 ^ r) & (~v2 ^ r)) < 0;

	bool s1 = (v1 < 0);
	bool s2 = !(v2 < 0);
	bool sr = (*r < 0);
	return s1 != sr && s2 != sr;
	// also: return s1 == s2 && s1 != sr;
	}

	template <typename T> inline
	typename std::enable_if<std::is_unsigned<T>::value \|\| std::is_signed<T>::value, bool>::type
	mul_overflow(T v1, T v2, T *r)
	{
	// use the next biggest type
	// Note: for 64-bit systems where __int128 isn't supported, this will cause an error.
	using LargerInt = QIntegerForSize<sizeof(T) * 2>;
	using Larger = typename std::conditional<std::is_signed<T>::value,
	typename LargerInt::Signed, typename LargerInt::Unsigned>::type;
	Larger lr = Larger(v1) * Larger(v2);
	*r = T(lr);
	return lr > std::numeric_limits<T>::max() \|\| lr < std::numeric_limits<T>::min();
	}

	# if defined(Q_INTRINSIC_MUL_OVERFLOW64)
	template <> inline bool mul_overflow(quint64 v1, quint64 v2, quint64 *r)
	{
	r = v1 v2;
	return Q_UMULH(v1, v2);
	}
	template <> inline bool mul_overflow(qint64 v1, qint64 v2, qint64 *r)
	{
	// This is slightly more complex than the unsigned case above: the sign bit
	// of 'low' must be replicated as the entire 'high', so the only valid
	// values for 'high' are 0 and -1. Use unsigned multiply since it's the same
	// as signed for the low bits and use a signed right shift to verify that
	// 'high' is nothing but sign bits that match the sign of 'low'.

	qint64 high = Q_SMULH(v1, v2);
	r = qint64(quint64(v1) quint64(v2));
	return (*r >> 63) != high;
	}

	# if defined(Q_OS_INTEGRITY) && defined(Q_PROCESSOR_ARM_64)
	template <> inline bool mul_overflow(uint64_t v1, uint64_t v2, uint64_t *r)
	{
	return mul_overflow<quint64>(v1,v2,reinterpret_cast<quint64*>(r));
	}

	template <> inline bool mul_overflow(int64_t v1, int64_t v2, int64_t *r)
	{
	return mul_overflow<qint64>(v1,v2,reinterpret_cast<qint64*>(r));
	}
	# endif // OS_INTEGRITY ARM64
	# endif // Q_INTRINSIC_MUL_OVERFLOW64

	# if defined(Q_CC_MSVC) && defined(Q_PROCESSOR_X86)
	// We can use intrinsics for the unsigned operations with MSVC
	template <> inline bool add_overflow(unsigned v1, unsigned v2, unsigned *r)
	{ return _addcarry_u32(0, v1, v2, r); }

	// 32-bit mul_overflow is fine with the generic code above

	template <> inline bool add_overflow(quint64 v1, quint64 v2, quint64 *r)
	{
	# if defined(Q_PROCESSOR_X86_64)
	return _addcarry_u64(0, v1, v2, reinterpret_cast<unsigned __int64 *>(r));
	# else
	uint low, high;
	uchar carry = _addcarry_u32(0, unsigned(v1), unsigned(v2), &low);
	carry = _addcarry_u32(carry, v1 >> 32, v2 >> 32, &high);
	*r = (quint64(high) << 32) \| low;
	return carry;
	# endif // !x86-64
	}
	# endif // MSVC X86
	#endif // !GCC
	}
	#endif // Q_CLANG_QDOC

	QT_END_NAMESPACE

	#endif // QNUMERIC_P_H