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 /*
* Copyright 1993-2023 NVIDIA Corporation. All rights reserved.
*
* NOTICE TO LICENSEE:
*
* This source code and/or documentation ("Licensed Deliverables") are
* subject to NVIDIA intellectual property rights under U.S. and
* international Copyright laws.
*
* These Licensed Deliverables contained herein is PROPRIETARY and
* CONFIDENTIAL to NVIDIA and is being provided under the terms and
* conditions of a form of NVIDIA software license agreement by and
* between NVIDIA and Licensee ("License Agreement") or electronically
* accepted by Licensee. Notwithstanding any terms or conditions to
* the contrary in the License Agreement, reproduction or disclosure
* of the Licensed Deliverables to any third party without the express
* written consent of NVIDIA is prohibited.
*
* NOTWITHSTANDING ANY TERMS OR CONDITIONS TO THE CONTRARY IN THE
* LICENSE AGREEMENT, NVIDIA MAKES NO REPRESENTATION ABOUT THE
* SUITABILITY OF THESE LICENSED DELIVERABLES FOR ANY PURPOSE. IT IS
* PROVIDED "AS IS" WITHOUT EXPRESS OR IMPLIED WARRANTY OF ANY KIND.
* NVIDIA DISCLAIMS ALL WARRANTIES WITH REGARD TO THESE LICENSED
* DELIVERABLES, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY,
* NONINFRINGEMENT, AND FITNESS FOR A PARTICULAR PURPOSE.
* NOTWITHSTANDING ANY TERMS OR CONDITIONS TO THE CONTRARY IN THE
* LICENSE AGREEMENT, IN NO EVENT SHALL NVIDIA BE LIABLE FOR ANY
* SPECIAL, INDIRECT, INCIDENTAL, OR CONSEQUENTIAL DAMAGES, OR ANY
* DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS,
* WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS
* ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE
* OF THESE LICENSED DELIVERABLES.
*
* U.S. Government End Users. These Licensed Deliverables are a
* "commercial item" as that term is defined at 48 C.F.R. 2.101 (OCT
* 1995), consisting of "commercial computer software" and "commercial
* computer software documentation" as such terms are used in 48
* C.F.R. 12.212 (SEPT 1995) and is provided to the U.S. Government
* only as a commercial end item. Consistent with 48 C.F.R.12.212 and
* 48 C.F.R. 227.7202-1 through 227.7202-4 (JUNE 1995), all
* U.S. Government End Users acquire the Licensed Deliverables with
* only those rights set forth herein.
*
* Any use of the Licensed Deliverables in individual and commercial
* software must include, in the user documentation and internal
* comments to the code, the above Disclaimer and U.S. Government End
* Users Notice.
*/
#if !defined(__CUDA_INCLUDE_COMPILER_INTERNAL_HEADERS__)
#if defined(_MSC_VER)
#pragma message("crt/math_functions.hpp is an internal header file and must not be used directly. Please use cuda_runtime_api.h or cuda_runtime.h instead.")
#else
#warning "crt/math_functions.hpp is an internal header file and must not be used directly. Please use cuda_runtime_api.h or cuda_runtime.h instead."
#endif
#define __CUDA_INCLUDE_COMPILER_INTERNAL_HEADERS__
#define __UNDEF_CUDA_INCLUDE_COMPILER_INTERNAL_HEADERS_MATH_FUNCTIONS_HPP__
#endif
#if !defined(__MATH_FUNCTIONS_HPP__)
#define __MATH_FUNCTIONS_HPP__
/*******************************************************************************
* *
* *
* *
*******************************************************************************/
#if defined(__cplusplus) && defined(__CUDACC__)
/*******************************************************************************
* *
* *
* *
*******************************************************************************/
#include "builtin_types.h"
#include "host_defines.h"
/*******************************************************************************
* *
* *
* *
*******************************************************************************/
#if defined(__CUDACC_RTC__)
__host__ __device__ __cudart_builtin__ int signbit(const float x) { return __signbitf(x); }
__host__ __device__ __cudart_builtin__ int signbit(const double x) { return __signbit(x); }
__host__ __device__ __cudart_builtin__ int signbit(const long double x) { return __signbitl(static_cast<double>(x));}
__host__ __device__ __cudart_builtin__ int isfinite(const float x) { return __finitef(x); }
__host__ __device__ __cudart_builtin__ int isfinite(const double x) { return __finite(x); }
__host__ __device__ __cudart_builtin__ int isfinite(const long double x) { return __finitel(static_cast<double>(x)); }
__host__ __device__ __cudart_builtin__ int isnan(const float x) { return __isnanf(x); }
__host__ __device__ __cudart_builtin__ int isnan(const double x) { return __isnan(x); }
__host__ __device__ __cudart_builtin__ int isnan(const long double x) { return __isnanl(static_cast<double>(x)); }
__host__ __device__ __cudart_builtin__ int isinf(const float x) { return __isinff(x); }
__host__ __device__ __cudart_builtin__ int isinf(const double x) { return __isinf(x); }
__host__ __device__ __cudart_builtin__ int isinf(const long double x) { return __isinfl(static_cast<double>(x)); }
__host__ __device__ __cudart_builtin__ long long int abs(const long long int a) { return llabs(a); }
__host__ __device__ __cudart_builtin__ long int abs(const long int in) { return llabs(in); }
__host__ __device__ __cudart_builtin__ float abs(const float in) { return fabsf(in); }
__host__ __device__ __cudart_builtin__ double abs(const double in) { return fabs(in); }
__host__ __device__ __cudart_builtin__ float fabs(const float in) { return fabsf(in); }
__host__ __device__ __cudart_builtin__ float ceil(const float in) { return ceilf(in); }
__host__ __device__ __cudart_builtin__ float floor(const float in) { return floorf(in); }
__host__ __device__ __cudart_builtin__ float sqrt(const float in) { return sqrtf(in); }
__host__ __device__ __cudart_builtin__ float pow(const float a, const float b) { return powf(a, b); }
extern "C" __device__ float powif(float, int);
__host__ __device__ __cudart_builtin__ float pow(const float a, const int b) { return powif(a, b); }
extern "C" __device__ double powi(double, int);
__host__ __device__ __cudart_builtin__ double pow(const double a, const int b) { return powi(a, b); }
__host__ __device__ __cudart_builtin__ float log(const float in) { return logf(in); }
__host__ __device__ __cudart_builtin__ float log10(const float in) { return log10f(in); }
__host__ __device__ __cudart_builtin__ float fmod(const float a, const float b) { return fmodf(a, b); }
__host__ __device__ __cudart_builtin__ float modf(const float a, float*b) { return modff(a, b); }
__host__ __device__ __cudart_builtin__ float exp(const float in) { return expf(in); }
__host__ __device__ __cudart_builtin__ float frexp(const float a, int*b) { return frexpf(a, b); }
__host__ __device__ __cudart_builtin__ float ldexp(const float a, int b) { return ldexpf(a, b); }
__host__ __device__ __cudart_builtin__ float asin(const float in) { return asinf(in); }
__host__ __device__ __cudart_builtin__ float sin(const float in) { return sinf(in); }
__host__ __device__ __cudart_builtin__ float sinh(const float in) { return sinhf(in); }
__host__ __device__ __cudart_builtin__ float acos(const float in) { return acosf(in); }
__host__ __device__ __cudart_builtin__ float cos(const float in) { return cosf(in); }
__host__ __device__ __cudart_builtin__ float cosh(const float in) { return coshf(in); }
__host__ __device__ __cudart_builtin__ float atan(const float in) { return atanf(in); }
__host__ __device__ __cudart_builtin__ float atan2(const float a, const float b) { return atan2f(a, b); }
__host__ __device__ __cudart_builtin__ float tan(const float in) { return tanf(in); }
__host__ __device__ __cudart_builtin__ float tanh(const float in) { return tanhf(in); }
#elif defined(__GNUC__)
#undef signbit
#undef isfinite
#undef isnan
#undef isinf
#if defined(_LIBCPP_VERSION)
extern "C" __device__ float powif(float, int);
extern "C" __device__ double powi(double, int);
#endif /* _LIBCPP_VERSION */
#if defined(__APPLE__)
__forceinline__ __host__ __device__ __cudart_builtin__ int signbit(const float x) { return __signbitf(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int signbit(const double x) { return __signbitd(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int signbit(const long double x) { return __signbitl(x);}
__forceinline__ __host__ __device__ __cudart_builtin__ int isfinite(const float x) { return __isfinitef(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int isfinite(const double x) { return __isfinited(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int isfinite(const long double x) { return __isfinite(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int isnan(const double x) throw() { return __isnand(x); }
#if defined(_LIBCPP_VERSION) && _LIBCPP_VERSION < 7000
__forceinline__ __host__ __device__ __cudart_builtin__ int isnan(const float x) { return __isnanf(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int isnan(const long double x) { return __isnan(x); }
#endif /* defined(_LIBCPP_VERSION) && _LIBCPP_VERSION < 7000 */
__forceinline__ __host__ __device__ __cudart_builtin__ int isinf(const double x) throw() { return __isinfd(x); }
#if defined(_LIBCPP_VERSION) && _LIBCPP_VERSION < 7000
__forceinline__ __host__ __device__ __cudart_builtin__ int isinf(const float x) { return __isinff(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int isinf(const long double x) { return __isinf(x); }
#endif /* defined(_LIBCPP_VERSION) && _LIBCPP_VERSION < 7000 */
#else /* __APPLE__ */
#if ((defined _GLIBCXX_MATH_H) && _GLIBCXX_MATH_H) && (__cplusplus >= 201103L)
#if defined(__CUDA_ARCH__)
#define __NV_BUILTIN_FUNC_DECL__ __forceinline__ __host__ __device__ __cudart_builtin__
#if _GLIBCXX_HAVE_OBSOLETE_ISNAN && !_GLIBCXX_NO_OBSOLETE_ISINF_ISNAN_DYNAMIC
__NV_BUILTIN_FUNC_DECL__ int isnan(const double a) throw() { return __isnan(a); }
__NV_BUILTIN_FUNC_DECL__ int isinf(const double x) throw() { return __isinf(x); }
#endif /* _GLIBCXX_HAVE_OBSOLETE_ISNAN && !_GLIBCXX_NO_OBSOLETE_ISINF_ISNAN_DYNAMIC */
#undef __NV_BUILTIN_FUNC_DECL__
#endif /* __CUDA_ARCH */
#else /* !(((defined _GLIBCXX_MATH_H) && _GLIBCXX_MATH_H) && (__cplusplus >= 201103L)) */
#if defined(__QNX__)
#if defined(__QNX__) && defined(_LIBCPP_VERSION)
static __inline__ __host__ __device__ __cudart_builtin__ bool signbit(const float x)
{
#if defined(__CUDA_ARCH__)
return (__signbitf(x) != 0);
#else /* !__CUDA_ARCH__ */
return signbit<float>(x);
#endif /* __CUDA_ARCH__ */
}
static __inline__ __host__ __device__ __cudart_builtin__ bool signbit(const double x)
{
#if defined(__CUDA_ARCH__)
return (__signbit(x) != 0);
#else /* !__CUDA_ARCH__ */
return signbit<double>(x);
#endif /* __CUDA_ARCH__ */
}
static __inline__ __host__ __device__ __cudart_builtin__ bool signbit(const long double x)
{
#if defined(__CUDA_ARCH__)
return (__signbitl(x) != 0);
#else /* !__CUDA_ARCH__ */
return signbit<long double>(x);
#endif /* __CUDA_ARCH__ */
}
#endif /* (__QNX__ && _LIBCPP_VERSION) */
static __inline__ __host__ __device__ __cudart_builtin__ bool isfinite(const long double a)
{
#if defined(__CUDA_ARCH__)
return (__finitel(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isfinite<long double>(a);
#endif /* defined(__CUDA_ARCH__) */
}
static __inline__ __host__ __device__ __cudart_builtin__ bool isfinite(const double a)
{
#if defined(__CUDA_ARCH__)
return (__finite(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isfinite<double>(a);
#endif /* defined(__CUDA_ARCH__) */
}
static __inline__ __host__ __device__ __cudart_builtin__ bool isfinite(const float a)
{
#if defined(__CUDA_ARCH__)
return (__finitef(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isfinite<float>(a);
#endif /* defined(__CUDA_ARCH__) */
}
static __inline__ __host__ __device__ __cudart_builtin__ bool isnan(const long double a)
{
#if defined(__CUDA_ARCH__)
return (__isnanl(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isnan<long double>(a);
#endif /* defined(__CUDA_ARCH__) */
}
static __inline__ __host__ __device__ __cudart_builtin__ bool isnan(const double a)
{
#if defined(__CUDA_ARCH__)
return (__isnan(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isnan<double>(a);
#endif /* defined(__CUDA_ARCH__) */
}
static __inline__ __host__ __device__ __cudart_builtin__ bool isnan(const float a)
{
#if defined(__CUDA_ARCH__)
return (__isnanf(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isnan<float>(a);
#endif /* defined(__CUDA_ARCH__) */
}
static __inline__ __host__ __device__ __cudart_builtin__ bool isinf(const long double a)
{
#if defined(__CUDA_ARCH__)
return (__isinfl(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isinf<long double>(a);
#endif /* defined(__CUDA_ARCH__) */
}
static __inline__ __host__ __device__ __cudart_builtin__ bool isinf(const double a)
{
#if defined(__CUDA_ARCH__)
return (__isinf(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isinf<double>(a);
#endif /* defined(__CUDA_ARCH__) */
}
static __inline__ __host__ __device__ __cudart_builtin__ bool isinf(const float a)
{
#if defined(__CUDA_ARCH__)
return (__isinff(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isinf<float>(a);
#endif /* defined(__CUDA_ARCH__) */
}
#elif ( (defined(__ANDROID__) || defined(__HORIZON__)) && defined(_LIBCPP_VERSION))
#if defined(__CUDA_ARCH__)
__forceinline__ __host__ __device__ __cudart_builtin__ int signbit(const float x) { return __signbitf(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int signbit(const double x) { return __signbit(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int signbit(const long double x) { return __signbitl(x);}
__forceinline__ __host__ __device__ __cudart_builtin__ int isfinite(const float x) { return __finitef(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int isfinite(const double x) { return __finite(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int isfinite(const long double x) { return __finitel(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int isnan(const double x) { return __isnan(x); }
#if _LIBCPP_VERSION < 8000
__forceinline__ __host__ __device__ __cudart_builtin__ int isnan(const float x) { return __isnanf(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int isnan(const long double x) { return __isnanl(x); }
#endif /* _LIBCPP_VERSION < 8000 */
__forceinline__ __host__ __device__ __cudart_builtin__ int isinf(const double x) { return __isinf(x); }
#if _LIBCPP_VERSION < 8000
__forceinline__ __host__ __device__ __cudart_builtin__ int isinf(const float x) { return __isinff(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int isinf(const long double x) { return __isinfl(x); }
#endif /* _LIBCPP_VERSION < 8000 */
#else /* !defined(__CUDA_ARCH__) */
__forceinline__ __host__ __device__ __cudart_builtin__ int signbit(const float x) { return signbit<float>(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int signbit(const double x) { return signbit<double>(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int signbit(const long double x) { return signbit<long double>(x);}
__forceinline__ __host__ __device__ __cudart_builtin__ int isfinite(const float x) { return isfinite<float>(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int isfinite(const double x) { return isfinite<double>(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int isfinite(const long double x) { return isfinite<long double>(x); }
#if _LIBCPP_VERSION < 8000
__forceinline__ __host__ __device__ __cudart_builtin__ int isnan(const float x) { return isnan<float>(x); }
/* int isnan(double) provided by math.h */
__forceinline__ __host__ __device__ __cudart_builtin__ int isnan(const long double x) { return isnan<long double>(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int isinf(const float x) { return isinf<float>(x); }
/* int isinf(double) provided by math.h */
__forceinline__ __host__ __device__ __cudart_builtin__ int isinf(const long double x) { return isinf<long double>(x); }
#endif /* _LIBCPP_VERSION < 8000 */
#endif /* defined(__CUDA_ARCH__) */
#else /* !__QNX__ */
__forceinline__ __host__ __device__ __cudart_builtin__ int signbit(const float x) { return __signbitf(x); }
#if defined(__ICC)
__forceinline__ __host__ __device__ __cudart_builtin__ int signbit(const double x) throw() { return __signbit(x); }
#else /* !__ICC */
__forceinline__ __host__ __device__ __cudart_builtin__ int signbit(const double x) { return __signbit(x); }
#endif /* __ICC */
__forceinline__ __host__ __device__ __cudart_builtin__ int signbit(const long double x) { return __signbitl(x);}
#if defined(__ANDROID__)
__forceinline__ __host__ __device__ __cudart_builtin__ int isfinite(const float x) {
#if defined(__CUDA_ARCH__)
return __finitef(x);
#else /* !__CUDA_ARCH__ */
return __isfinitef(x);
#endif /* __CUDA_ARCH__ */
}
#else /* !__ANDROID__ */
__forceinline__ __host__ __device__ __cudart_builtin__ int isfinite(const float x) { return __finitef(x); }
#endif /* __ANDROID__ */
#if defined(__ANDROID__)
__forceinline__ __host__ __device__ __cudart_builtin__ int isfinite(const double x)
{
#ifdef __CUDA_ARCH__
return __finite(x);
#else /* !__CUDA_ARCH__ */
return __isfinite(x);
#endif /* __CUDA_ARCH__ */
}
#elif defined(__ICC)
__forceinline__ __host__ __device__ __cudart_builtin__ int isfinite(const double x) throw() { return __finite(x); }
#else
__forceinline__ __host__ __device__ __cudart_builtin__ int isfinite(const double x) { return __finite(x); }
#endif /* __ANDROID__ */
#if defined(__ANDROID__)
__forceinline__ __host__ __device__ __cudart_builtin__ int isfinite(const long double x)
{
#ifdef __CUDA_ARCH__
return __finitel(x);
#else /* !__CUDA_ARCH__ */
return __isfinitel(x);
#endif /* __CUDA_ARCH__ */
}
#else /* !__ANDROID__ */
__forceinline__ __host__ __device__ __cudart_builtin__ int isfinite(const long double x) { return __finitel(x); }
#endif /* __ANDROID__ */
__forceinline__ __host__ __device__ __cudart_builtin__ int isnan(const float x) { return __isnanf(x); }
#if defined(__ANDROID__)
__forceinline__ __host__ __device__ __cudart_builtin__ int isnan(const double x) { return __isnan(x); }
#else /* !__ANDROID__ */
__forceinline__ __host__ __device__ __cudart_builtin__ int isnan(const double x) throw() { return __isnan(x); }
#endif /* __ANDROID__ */
__forceinline__ __host__ __device__ __cudart_builtin__ int isnan(const long double x) { return __isnanl(x); }
__forceinline__ __host__ __device__ __cudart_builtin__ int isinf(const float x) { return __isinff(x); }
#if defined(__ANDROID__)
__forceinline__ __host__ __device__ __cudart_builtin__ int isinf(const double x) { return __isinf(x); }
#else /* !__ANDROID__ */
__forceinline__ __host__ __device__ __cudart_builtin__ int isinf(const double x) throw() { return __isinf(x); }
#endif /* __ANDROID__ */
__forceinline__ __host__ __device__ __cudart_builtin__ int isinf(const long double x) { return __isinfl(x); }
#endif /* __QNX__ || __HORIZON__ */
#endif /* ((defined _GLIBCXX_MATH_H) && _GLIBCXX_MATH_H) && (__cplusplus >= 201103L) */
#endif /* __APPLE__ */
#if defined(__arm__) && !defined(_STLPORT_VERSION) && !_GLIBCXX_USE_C99
#if !defined(__ANDROID__) || (!defined(_LIBCPP_VERSION) && (__GNUC__ < 4 || (__GNUC__ == 4 && __GNUC_MINOR__ < 8)))
#if !defined(__QNX__) && !defined(__HORIZON__)
static __inline__ __host__ __device__ __cudart_builtin__ long long int abs(const long long int a)
{
return llabs(a);
}
#endif /* !__QNX__ && !__HORIZON__*/
#endif /* !defined(__ANDROID__) || (!defined(_LIBCPP_VERSION) && (__GNUC__ < 4 || (__GNUC__ == 4 && __GNUC_MINOR__ < 8))) */
#endif /* __arm__ && !_STLPORT_VERSION && !_GLIBCXX_USE_C99 */
#elif defined(_WIN32)
#if (!defined(_MSC_VER) || _MSC_VER < 1800)
static __inline__ __host__ __device__ __cudart_builtin__ int signbit(const long double a)
{
return __signbitl(a);
}
static __inline__ __host__ __device__ __cudart_builtin__ int signbit(const double a)
{
return __signbit(a);
}
static __inline__ __host__ __device__ __cudart_builtin__ int signbit(const float a)
{
return __signbitf(a);
}
#endif /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
#if (!defined(_MSC_VER) || _MSC_VER < 1800)
static __inline__ __host__ __device__ __cudart_builtin__ int isinf(const long double a)
{
return __isinfl(a);
}
#else /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
static __inline__ __host__ __device__ __cudart_builtin__ bool isinf(const long double a)
{
#if defined(__CUDA_ARCH__)
return (__isinfl(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isinf<long double>(a);
#endif /* defined(__CUDA_ARCH__) */
}
#endif /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
#if (!defined(_MSC_VER) || _MSC_VER < 1800)
static __inline__ __host__ __device__ __cudart_builtin__ int isinf(const double a)
{
return __isinf(a);
}
#else /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
static __inline__ __host__ __device__ __cudart_builtin__ bool isinf(const double a)
{
#if defined(__CUDA_ARCH__)
return (__isinf(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isinf<double>(a);
#endif /* defined(__CUDA_ARCH__) */
}
#endif /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
#if (!defined(_MSC_VER) || _MSC_VER < 1800)
static __inline__ __host__ __device__ __cudart_builtin__ int isinf(const float a)
{
return __isinff(a);
}
#else /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
static __inline__ __host__ __device__ bool isinf(const float a)
{
#if defined(__CUDA_ARCH__)
return (__isinff(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isinf<float>(a);
#endif /* defined(__CUDA_ARCH__) */
}
#endif /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
#if (!defined(_MSC_VER) || _MSC_VER < 1800)
static __inline__ __host__ __device__ __cudart_builtin__ int isnan(const long double a)
{
return __isnanl(a);
}
#else /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
static __inline__ __host__ __device__ __cudart_builtin__ bool isnan(const long double a)
{
#if defined(__CUDA_ARCH__)
return (__isnanl(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isnan<long double>(a);
#endif /* defined(__CUDA_ARCH__) */
}
#endif /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
#if (!defined(_MSC_VER) || _MSC_VER < 1800)
static __inline__ __host__ __device__ __cudart_builtin__ int isnan(const double a)
{
return __isnan(a);
}
#else /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
static __inline__ __host__ __device__ __cudart_builtin__ bool isnan(const double a)
{
#if defined(__CUDA_ARCH__)
return (__isnan(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isnan<double>(a);
#endif /* defined(__CUDA_ARCH__) */
}
#endif /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
#if (!defined(_MSC_VER) || _MSC_VER < 1800)
static __inline__ __host__ __device__ __cudart_builtin__ int isnan(const float a)
{
return __isnanf(a);
}
#else /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
static __inline__ __host__ __device__ __cudart_builtin__ bool isnan(const float a)
{
#if defined(__CUDA_ARCH__)
return (__isnanf(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isnan<float>(a);
#endif /* defined(__CUDA_ARCH__) */
}
#endif /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
#if (!defined(_MSC_VER) || _MSC_VER < 1800)
static __inline__ __host__ __device__ __cudart_builtin__ int isfinite(const long double a)
{
return __finitel(a);
}
#else /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
static __inline__ __host__ __device__ __cudart_builtin__ bool isfinite(const long double a)
{
#if defined(__CUDA_ARCH__)
return (__finitel(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isfinite<long double>(a);
#endif /* defined(__CUDA_ARCH__) */
}
#endif /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
#if (!defined(_MSC_VER) || _MSC_VER < 1800)
static __inline__ __host__ __device__ __cudart_builtin__ int isfinite(const double a)
{
return __finite(a);
}
#else /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
static __inline__ __host__ __device__ __cudart_builtin__ bool isfinite(const double a)
{
#if defined(__CUDA_ARCH__)
return (__finite(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isfinite<double>(a);
#endif /* defined(__CUDA_ARCH__) */
}
#endif /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
#if (!defined(_MSC_VER) || _MSC_VER < 1800)
static __inline__ __host__ __device__ __cudart_builtin__ int isfinite(const float a)
{
return __finitef(a);
}
#else /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
static __inline__ __host__ __device__ __cudart_builtin__ bool isfinite(const float a)
{
#if defined(__CUDA_ARCH__)
return (__finitef(a) != 0);
#else /* defined(__CUDA_ARCH__) */
return isfinite<float>(a);
#endif /* defined(__CUDA_ARCH__) */
}
#endif /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
#endif /* __CUDACC_RTC__ */
#if defined(__CUDACC_RTC__)
#define __MATH_FUNCTIONS_DECL__ __host__ __device__
#define __MATH_FUNCTIONS_DEVICE_DECL__ __device__
#else /* __CUDACC_RTC__ */
#define __MATH_FUNCTIONS_DECL__ static inline __host__ __device__
#define __MATH_FUNCTIONS_DEVICE_DECL__ static inline __device__
#endif /* __CUDACC_RTC__ */
#if defined(__CUDACC_RTC__) || (!defined(_MSC_VER) || _MSC_VER < 1800)
#if defined(__QNX__) && defined(_LIBCPP_VERSION)
_LIBCPP_BEGIN_NAMESPACE_STD
#endif /* __QNX__ && _LIBCPP_VERSION */
#if !defined(__QNX__) && !(defined(_LIBCPP_VERSION) && _LIBCPP_VERSION >= 3800)
#if !(((defined _GLIBCXX_MATH_H) && _GLIBCXX_MATH_H) && (__cplusplus >= 201103L))
__MATH_FUNCTIONS_DECL__ float logb(const float a)
{
return logbf(a);
}
__MATH_FUNCTIONS_DECL__ int ilogb(const float a)
{
return ilogbf(a);
}
__MATH_FUNCTIONS_DECL__ float scalbn(const float a, const int b)
{
return scalbnf(a, b);
}
__MATH_FUNCTIONS_DECL__ float scalbln(const float a, const long int b)
{
return scalblnf(a, b);
}
__MATH_FUNCTIONS_DECL__ float exp2(const float a)
{
return exp2f(a);
}
__MATH_FUNCTIONS_DECL__ float expm1(const float a)
{
return expm1f(a);
}
__MATH_FUNCTIONS_DECL__ float log2(const float a)
{
return log2f(a);
}
__MATH_FUNCTIONS_DECL__ float log1p(const float a)
{
return log1pf(a);
}
__MATH_FUNCTIONS_DECL__ float acosh(const float a)
{
return acoshf(a);
}
__MATH_FUNCTIONS_DECL__ float asinh(const float a)
{
return asinhf(a);
}
__MATH_FUNCTIONS_DECL__ float atanh(const float a)
{
return atanhf(a);
}
__MATH_FUNCTIONS_DECL__ float hypot(const float a, const float b)
{
return hypotf(a, b);
}
__MATH_FUNCTIONS_DECL__ float cbrt(const float a)
{
return cbrtf(a);
}
__MATH_FUNCTIONS_DECL__ float erf(const float a)
{
return erff(a);
}
__MATH_FUNCTIONS_DECL__ float erfc(const float a)
{
return erfcf(a);
}
__MATH_FUNCTIONS_DECL__ float lgamma(const float a)
{
return lgammaf(a);
}
__MATH_FUNCTIONS_DECL__ float tgamma(const float a)
{
return tgammaf(a);
}
__MATH_FUNCTIONS_DECL__ float copysign(const float a, const float b)
{
return copysignf(a, b);
}
__MATH_FUNCTIONS_DECL__ float nextafter(const float a, const float b)
{
return nextafterf(a, b);
}
__MATH_FUNCTIONS_DECL__ float remainder(const float a, const float b)
{
return remainderf(a, b);
}
__MATH_FUNCTIONS_DECL__ float remquo(const float a, const float b, int *quo)
{
return remquof(a, b, quo);
}
__MATH_FUNCTIONS_DECL__ float round(const float a)
{
return roundf(a);
}
__MATH_FUNCTIONS_DECL__ long int lround(const float a)
{
return lroundf(a);
}
__MATH_FUNCTIONS_DECL__ long long int llround(const float a)
{
return llroundf(a);
}
__MATH_FUNCTIONS_DECL__ float trunc(const float a)
{
return truncf(a);
}
__MATH_FUNCTIONS_DECL__ float rint(const float a)
{
return rintf(a);
}
__MATH_FUNCTIONS_DECL__ long int lrint(const float a)
{
return lrintf(a);
}
__MATH_FUNCTIONS_DECL__ long long int llrint(const float a)
{
return llrintf(a);
}
__MATH_FUNCTIONS_DECL__ float nearbyint(const float a)
{
return nearbyintf(a);
}
__MATH_FUNCTIONS_DECL__ float fdim(const float a, const float b)
{
return fdimf(a, b);
}
__MATH_FUNCTIONS_DECL__ float fma(const float a, const float b, const float c)
{
return fmaf(a, b, c);
}
__MATH_FUNCTIONS_DECL__ float fmax(const float a, const float b)
{
return fmaxf(a, b);
}
__MATH_FUNCTIONS_DECL__ float fmin(const float a, const float b)
{
return fminf(a, b);
}
#endif /* !(((defined _GLIBCXX_MATH_H) && _GLIBCXX_MATH_H) && (__cplusplus >= 201103L)) */
#endif /* !(!defined(__QNX__) && !(defined(_LIBCPP_VERSION) && _LIBCPP_VERSION >= 3800)) */
#if defined(__QNX__) && defined(_LIBCPP_VERSION)
_LIBCPP_END_NAMESPACE_STD
#endif
#endif /* __CUDACC_RTC__ || (!defined(_MSC_VER) || _MSC_VER < 1800) */
__MATH_FUNCTIONS_DECL__ float exp10(const float a)
{
return exp10f(a);
}
__MATH_FUNCTIONS_DECL__ float rsqrt(const float a)
{
return rsqrtf(a);
}
__MATH_FUNCTIONS_DECL__ float rcbrt(const float a)
{
return rcbrtf(a);
}
__MATH_FUNCTIONS_DECL__ float sinpi(const float a)
{
return sinpif(a);
}
__MATH_FUNCTIONS_DECL__ float cospi(const float a)
{
return cospif(a);
}
__MATH_FUNCTIONS_DECL__ void sincospi(const float a, float *const sptr, float *const cptr)
{
sincospif(a, sptr, cptr);
}
__MATH_FUNCTIONS_DECL__ void sincos(const float a, float *const sptr, float *const cptr)
{
sincosf(a, sptr, cptr);
}
__MATH_FUNCTIONS_DECL__ float j0(const float a)
{
return j0f(a);
}
__MATH_FUNCTIONS_DECL__ float j1(const float a)
{
return j1f(a);
}
__MATH_FUNCTIONS_DECL__ float jn(const int n, const float a)
{
return jnf(n, a);
}
__MATH_FUNCTIONS_DECL__ float y0(const float a)
{
return y0f(a);
}
__MATH_FUNCTIONS_DECL__ float y1(const float a)
{
return y1f(a);
}
__MATH_FUNCTIONS_DECL__ float yn(const int n, const float a)
{
return ynf(n, a);
}
__MATH_FUNCTIONS_DEVICE_DECL__ float cyl_bessel_i0(const float a)
{
return cyl_bessel_i0f(a);
}
__MATH_FUNCTIONS_DEVICE_DECL__ float cyl_bessel_i1(const float a)
{
return cyl_bessel_i1f(a);
}
__MATH_FUNCTIONS_DECL__ float erfinv(const float a)
{
return erfinvf(a);
}
__MATH_FUNCTIONS_DECL__ float erfcinv(const float a)
{
return erfcinvf(a);
}
__MATH_FUNCTIONS_DECL__ float normcdfinv(const float a)
{
return normcdfinvf(a);
}
__MATH_FUNCTIONS_DECL__ float normcdf(const float a)
{
return normcdff(a);
}
__MATH_FUNCTIONS_DECL__ float erfcx(const float a)
{
return erfcxf(a);
}
__MATH_FUNCTIONS_DECL__ double copysign(const double a, const float b)
{
return copysign(a, static_cast<double>(b));
}
__MATH_FUNCTIONS_DECL__ double copysign(const float a, const double b)
{
return copysign(static_cast<double>(a), b);
}
__MATH_FUNCTIONS_DECL__ unsigned int min(const unsigned int a, const unsigned int b)
{
return umin(a, b);
}
__MATH_FUNCTIONS_DECL__ unsigned int min(const int a, const unsigned int b)
{
return umin(static_cast<unsigned int>(a), b);
}
__MATH_FUNCTIONS_DECL__ unsigned int min(const unsigned int a, const int b)
{
return umin(a, static_cast<unsigned int>(b));
}
__MATH_FUNCTIONS_DECL__ long int min(const long int a, const long int b)
{
long int retval;
/* Suppress VS warning: warning C4127: conditional expression is constant */
#if defined(_MSC_VER) && !defined(__CUDA_ARCH__)
#pragma warning (push)
#pragma warning (disable: 4127)
#endif /* _MSC_VER && !defined(__CUDA_ARCH__) */
/* long can be of 32-bit type on some systems. */
if (sizeof(long int) == sizeof(int)) {
#if defined(_MSC_VER) && !defined(__CUDA_ARCH__)
#pragma warning (pop)
#endif /* _MSC_VER && !defined(__CUDA_ARCH__) */
retval = static_cast<long int>(min(static_cast<int>(a), static_cast<int>(b)));
} else {
retval = static_cast<long int>(llmin(static_cast<long long int>(a), static_cast<long long int>(b)));
}
return retval;
}
__MATH_FUNCTIONS_DECL__ unsigned long int min(const unsigned long int a, const unsigned long int b)
{
unsigned long int retval;
#if defined(_MSC_VER) && !defined(__CUDA_ARCH__)
#pragma warning (push)
#pragma warning (disable: 4127)
#endif /* _MSC_VER && !defined(__CUDA_ARCH__) */
if (sizeof(unsigned long int) == sizeof(unsigned int)) {
#if defined(_MSC_VER) && !defined(__CUDA_ARCH__)
#pragma warning (pop)
#endif /* _MSC_VER && !defined(__CUDA_ARCH__) */
retval = static_cast<unsigned long int>(umin(static_cast<unsigned int>(a), static_cast<unsigned int>(b)));
} else {
retval = static_cast<unsigned long int>(ullmin(static_cast<unsigned long long int>(a), static_cast<unsigned long long int>(b)));
}
return retval;
}
__MATH_FUNCTIONS_DECL__ unsigned long int min(const long int a, const unsigned long int b)
{
unsigned long int retval;
#if defined(_MSC_VER) && !defined(__CUDA_ARCH__)
#pragma warning (push)
#pragma warning (disable: 4127)
#endif /* _MSC_VER && !defined(__CUDA_ARCH__) */
if (sizeof(unsigned long int) == sizeof(unsigned int)) {
#if defined(_MSC_VER) && !defined(__CUDA_ARCH__)
#pragma warning (pop)
#endif /* _MSC_VER && !defined(__CUDA_ARCH__) */
retval = static_cast<unsigned long int>(umin(static_cast<unsigned int>(a), static_cast<unsigned int>(b)));
} else {
retval = static_cast<unsigned long int>(ullmin(static_cast<unsigned long long int>(a), static_cast<unsigned long long int>(b)));
}
return retval;
}
__MATH_FUNCTIONS_DECL__ unsigned long int min(const unsigned long int a, const long int b)
{
unsigned long int retval;
#if defined(_MSC_VER) && !defined(__CUDA_ARCH__)
#pragma warning (push)
#pragma warning (disable: 4127)
#endif /* _MSC_VER && !defined(__CUDA_ARCH__) */
if (sizeof(unsigned long int) == sizeof(unsigned int)) {
#if defined(_MSC_VER) && !defined(__CUDA_ARCH__)
#pragma warning (pop)
#endif /* _MSC_VER && !defined(__CUDA_ARCH__) */
retval = static_cast<unsigned long int>(umin(static_cast<unsigned int>(a), static_cast<unsigned int>(b)));
} else {
retval = static_cast<unsigned long int>(ullmin(static_cast<unsigned long long int>(a), static_cast<unsigned long long int>(b)));
}
return retval;
}
__MATH_FUNCTIONS_DECL__ long long int min(const long long int a, const long long int b)
{
return llmin(a, b);
}
__MATH_FUNCTIONS_DECL__ unsigned long long int min(const unsigned long long int a, const unsigned long long int b)
{
return ullmin(a, b);
}
__MATH_FUNCTIONS_DECL__ unsigned long long int min(const long long int a, const unsigned long long int b)
{
return ullmin(static_cast<unsigned long long int>(a), b);
}
__MATH_FUNCTIONS_DECL__ unsigned long long int min(const unsigned long long int a, const long long int b)
{
return ullmin(a, static_cast<unsigned long long int>(b));
}
__MATH_FUNCTIONS_DECL__ float min(const float a, const float b)
{
return fminf(a, b);
}
__MATH_FUNCTIONS_DECL__ double min(const double a, const double b)
{
return fmin(a, b);
}
__MATH_FUNCTIONS_DECL__ double min(const float a, const double b)
{
return fmin(static_cast<double>(a), b);
}
__MATH_FUNCTIONS_DECL__ double min(const double a, const float b)
{
return fmin(a, static_cast<double>(b));
}
__MATH_FUNCTIONS_DECL__ unsigned int max(const unsigned int a, const unsigned int b)
{
return umax(a, b);
}
__MATH_FUNCTIONS_DECL__ unsigned int max(const int a, const unsigned int b)
{
return umax(static_cast<unsigned int>(a), b);
}
__MATH_FUNCTIONS_DECL__ unsigned int max(const unsigned int a, const int b)
{
return umax(a, static_cast<unsigned int>(b));
}
__MATH_FUNCTIONS_DECL__ long int max(const long int a, const long int b)
{
long int retval;
/* long can be of 32-bit type on some systems. */
#if defined(_MSC_VER) && !defined(__CUDA_ARCH__)
#pragma warning (push)
#pragma warning (disable: 4127)
#endif /* _MSC_VER && !defined(__CUDA_ARCH__) */
if (sizeof(long int) == sizeof(int)) {
#if defined(_MSC_VER) && !defined(__CUDA_ARCH__)
#pragma warning (pop)
#endif /* _MSC_VER && !defined(__CUDA_ARCH__) */
retval = static_cast<long int>(max(static_cast<int>(a), static_cast<int>(b)));
} else {
retval = static_cast<long int>(llmax(static_cast<long long int>(a), static_cast<long long int>(b)));
}
return retval;
}
__MATH_FUNCTIONS_DECL__ unsigned long int max(const unsigned long int a, const unsigned long int b)
{
unsigned long int retval;
#if defined(_MSC_VER) && !defined(__CUDA_ARCH__)
#pragma warning (push)
#pragma warning (disable: 4127)
#endif /* _MSC_VER && !defined(__CUDA_ARCH__) */
if (sizeof(unsigned long int) == sizeof(unsigned int)) {
#if defined(_MSC_VER) && !defined(__CUDA_ARCH__)
#pragma warning (pop)
#endif /* _MSC_VER && !defined(__CUDA_ARCH__) */
retval = static_cast<unsigned long int>(umax(static_cast<unsigned int>(a), static_cast<unsigned int>(b)));
} else {
retval = static_cast<unsigned long int>(ullmax(static_cast<unsigned long long int>(a), static_cast<unsigned long long int>(b)));
}
return retval;
}
__MATH_FUNCTIONS_DECL__ unsigned long int max(const long int a, const unsigned long int b)
{
unsigned long int retval;
#if defined(_MSC_VER) && !defined(__CUDA_ARCH__)
#pragma warning (push)
#pragma warning (disable: 4127)
#endif /* _MSC_VER && !defined(__CUDA_ARCH__) */
if (sizeof(unsigned long int) == sizeof(unsigned int)) {
#if defined(_MSC_VER) && !defined(__CUDA_ARCH__)
#pragma warning (pop)
#endif /* _MSC_VER && !defined(__CUDA_ARCH__) */
retval = static_cast<unsigned long int>(umax(static_cast<unsigned int>(a), static_cast<unsigned int>(b)));
} else {
retval = static_cast<unsigned long int>(ullmax(static_cast<unsigned long long int>(a), static_cast<unsigned long long int>(b)));
}
return retval;
}
__MATH_FUNCTIONS_DECL__ unsigned long int max(const unsigned long int a, const long int b)
{
unsigned long int retval;
#if defined(_MSC_VER) && !defined(__CUDA_ARCH__)
#pragma warning (push)
#pragma warning (disable: 4127)
#endif /* _MSC_VER && !defined(__CUDA_ARCH__) */
if (sizeof(unsigned long int) == sizeof(unsigned int)) {
#if defined(_MSC_VER) && !defined(__CUDA_ARCH__)
#pragma warning (pop)
#endif /* _MSC_VER && !defined(__CUDA_ARCH__) */
retval = static_cast<unsigned long int>(umax(static_cast<unsigned int>(a), static_cast<unsigned int>(b)));
} else {
retval = static_cast<unsigned long int>(ullmax(static_cast<unsigned long long int>(a), static_cast<unsigned long long int>(b)));
}
return retval;
}
__MATH_FUNCTIONS_DECL__ long long int max(const long long int a, const long long int b)
{
return llmax(a, b);
}
__MATH_FUNCTIONS_DECL__ unsigned long long int max(const unsigned long long int a, const unsigned long long int b)
{
return ullmax(a, b);
}
__MATH_FUNCTIONS_DECL__ unsigned long long int max(const long long int a, const unsigned long long int b)
{
return ullmax(static_cast<unsigned long long int>(a), b);
}
__MATH_FUNCTIONS_DECL__ unsigned long long int max(const unsigned long long int a, const long long int b)
{
return ullmax(a, static_cast<unsigned long long int>(b));
}
__MATH_FUNCTIONS_DECL__ float max(const float a, const float b)
{
return fmaxf(a, b);
}
__MATH_FUNCTIONS_DECL__ double max(const double a, const double b)
{
return fmax(a, b);
}
__MATH_FUNCTIONS_DECL__ double max(const float a, const double b)
{
return fmax(static_cast<double>(a), b);
}
__MATH_FUNCTIONS_DECL__ double max(const double a, const float b)
{
return fmax(a, static_cast<double>(b));
}
#if !defined(__CUDA_ARCH__)
#if defined(_WIN32)
#define __HELPER_FUNC_LINKAGE static inline __host__ __device__
#pragma warning (push)
#pragma warning (disable : 4211)
#else /* !defined(_WIN32) */
#define __HELPER_FUNC_LINKAGE inline __host__ __device__
#endif /* defined(_WIN32) */
__HELPER_FUNC_LINKAGE int min(const int a, const int b)
{
return (a < b) ? a : b;
}
__HELPER_FUNC_LINKAGE unsigned int umin(const unsigned int a, const unsigned int b)
{
return (a < b) ? a : b;
}
__HELPER_FUNC_LINKAGE long long int llmin(const long long int a, const long long int b)
{
return (a < b) ? a : b;
}
__HELPER_FUNC_LINKAGE unsigned long long int ullmin(const unsigned long long int a,
const unsigned long long int b)
{
return (a < b) ? a : b;
}
__HELPER_FUNC_LINKAGE int max(const int a, const int b)
{
return (a > b) ? a : b;
}
__HELPER_FUNC_LINKAGE unsigned int umax(const unsigned int a, const unsigned int b)
{
return (a > b) ? a : b;
}
__HELPER_FUNC_LINKAGE long long int llmax(const long long int a, const long long int b)
{
return (a > b) ? a : b;
}
__HELPER_FUNC_LINKAGE unsigned long long int ullmax(const unsigned long long int a,
const unsigned long long int b)
{
return (a > b) ? a : b;
}
#if defined(_WIN32)
#pragma warning (pop)
#endif /* defined(_WIN32) */
#undef __HELPER_FUNC_LINKAGE
#endif /* !defined(__CUDA_ARCH__) */
#undef __MATH_FUNCTIONS_DECL__
#undef __MATH_FUNCTIONS_DEVICE_DECL__
/*******************************************************************************
* *
* *
* *
*******************************************************************************/
#endif /* __cplusplus && __CUDACC__ */
#if !defined(__CUDACC__)
#include "host_defines.h"
#include "math_constants.h"
#define __cuda_INT_MAX \
((int)((unsigned int)-1 >> 1))
/*******************************************************************************
* *
* ONLY FOR HOST CODE! NOT FOR DEVICE EXECUTION *
* *
*******************************************************************************/
#include <crt/func_macro.h>
#if defined(_WIN32)
#pragma warning (push)
#pragma warning (disable : 4211)
#endif /* _WIN32 */
#if defined(_WIN32) || defined(__APPLE__) || defined (__ANDROID__) || defined(__QNX__)
__func__(int __isnan(const double a))
{
unsigned long long int l;
memcpy(&l, &a, sizeof(double));
return (l << 1ULL) > 0xffe0000000000000ULL;
}
#endif /* _WIN32 || __APPLE__ || __ANDROID__ || __QNX__ */
#if defined(_WIN32) || defined(__APPLE__) || defined(__QNX__)
/*******************************************************************************
* *
* HOST IMPLEMENTATION FOR DOUBLE ROUTINES FOR WINDOWS & APPLE PLATFORMS *
* *
*******************************************************************************/
__func__(double exp10(const double a))
{
return pow(10.0, a);
}
__func__(float exp10f(const float a))
{
return static_cast<float>(exp10(static_cast<double>(a)));
}
__func__(void sincos(const double a, double *sptr, double *cptr))
{
*sptr = sin(a);
*cptr = cos(a);
}
__func__(void sincosf(const float a, float *sptr, float *cptr))
{
double s, c;
sincos(static_cast<double>(a), &s, &c);
*sptr = static_cast<float>(s);
*cptr = static_cast<float>(c);
}
__func__(int __isinf(const double a))
{
unsigned long long int l;
memcpy(&l, &a, sizeof(double));
return (l << 1ULL) == 0xffe0000000000000ULL;
}
#endif /* _WIN32 || __APPLE__ */
#if defined(_WIN32) || defined (__ANDROID__)
#if (!defined(_MSC_VER) || _MSC_VER < 1800)
__func__(double log2(const double a))
{
return log(a) * 1.44269504088896340;
}
#endif /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
#endif /* _WIN32 || __ANDROID__ */
#if defined(_WIN32)
/*******************************************************************************
* *
* HOST IMPLEMENTATION FOR DOUBLE ROUTINES FOR WINDOWS PLATFORM *
* *
*******************************************************************************/
__func__(int __signbit(double a))
{
signed long long int l;
memcpy(&l, &a, sizeof(double));
return l < 0LL;
}
#if (!defined(_MSC_VER) || _MSC_VER < 1800)
__func__(double copysign(double a, double b))
{
unsigned long long int la, lb;
memcpy(&la, &a, sizeof(double));
memcpy(&lb, &b, sizeof(double));
la = (la & 0x7fffffffffffffffULL) | (lb & 0x8000000000000000ULL);
memcpy(&a, &la, sizeof(double));
return a;
}
#endif /* MSC_VER < 1800 */
__func__(int __finite(double a))
{
unsigned long long int l;
memcpy(&l, &a, sizeof(double));
return (l << 1ULL) < 0xffe0000000000000ULL;
}
#if (!defined(_MSC_VER) || _MSC_VER < 1800)
__func__(double fmax(double a, double b))
{
if (__isnan(a) && __isnan(b)) return a + b;
if (__isnan(a)) return b;
if (__isnan(b)) return a;
if ((a == 0.0) && (b == 0.0) && __signbit(b)) return a;
return a > b ? a : b;
}
__func__(double fmin(double a, double b))
{
if (__isnan(a) && __isnan(b)) return a + b;
if (__isnan(a)) return b;
if (__isnan(b)) return a;
if ((a == 0.0) && (b == 0.0) && __signbit(a)) return a;
return a < b ? a : b;
}
__func__(double trunc(double a))
{
return a < 0.0 ? ceil(a) : floor(a);
}
__func__(double round(double a))
{
double fa = fabs(a);
if (fa > CUDART_TWO_TO_52) {
return a;
} else {
double u = floor(fa + 0.5);
if (fa < 0.5) u = 0;
u = copysign (u, a);
return u;
}
}
__func__(long int lround(double a))
{
return static_cast<long int>(round(a));
}
__func__(long long int llround(double a))
{
return static_cast<long long int>(round(a));
}
__func__(double rint(double a))
{
double fa = fabs(a);
double u = CUDART_TWO_TO_52 + fa;
if (fa >= CUDART_TWO_TO_52) {
u = a;
} else {
u = u - CUDART_TWO_TO_52;
u = copysign (u, a);
}
return u;
}
__func__(double nearbyint(double a))
{
return rint(a);
}
__func__(long int lrint(double a))
{
return static_cast<long int>(rint(a));
}
__func__(long long int llrint(double a))
{
return static_cast<long long int>(rint(a));
}
__func__(double fdim(double a, double b))
{
if (a > b) {
return (a - b);
} else if (a <= b) {
return 0.0;
} else if (__isnan(a)) {
return a;
} else {
return b;
}
}
__func__(double scalbn(double a, int b))
{
return ldexp(a, b);
}
__func__(double scalbln(double a, long int b))
{
int t;
if (b > 2147483647L) {
t = 2147483647;
} else if (b < (-2147483647 - 1)) {
t = (-2147483647 - 1);
} else {
t = static_cast<int>(b);
}
return scalbn(a, t);
}
__func__(double exp2(double a))
{
return pow(2.0, a);
}
/*
* The following is based on: David Goldberg, "What every computer scientist
* should know about floating-point arithmetic", ACM Computing Surveys, Volume
* 23, Issue 1, March 1991.
*/
__func__(double log1p(double a))
{
volatile double u, m;
u = 1.0 + a;
if (u == 1.0) {
/* a very close to zero */
u = a;
} else {
m = u - 1.0;
u = log(u);
if (a < 1.0) {
/* a somewhat close to zero */
u = a * u;
u = u / m;
}
}
return u;
}
/*
* This code based on: http://www.cs.berkeley.edu/~wkahan/Math128/Sumnfp.pdf
*/
__func__(double expm1(double a))
{
volatile double u, m;
u = exp(a);
m = u - 1.0;
if (m == 0.0) {
/* a very close zero */
m = a;
}
else if (fabs(a) < 1.0) {
/* a somewhat close zero */
u = log(u);
m = m * a;
m = m / u;
}
return m;
}
__func__(double cbrt(double a))
{
double s, t;
if (a == 0.0 || __isinf(a)) {
return a;
}
s = fabs(a);
t = exp2(CUDART_THIRD * log2(s)); /* initial approximation */
t = t - (t - (s / (t * t))) * CUDART_THIRD; /* refine approximation */
t = copysign(t, a);
return t;
}
__func__(double acosh(double a))
{
double s, t;
t = a - 1.0;
if (t == a) {
return log(2.0) + log(a);
} else {
s = a + 1.0;
t = t + sqrt(s * t);
return log1p(t);
}
}
__func__(double asinh(double a))
{
double fa, oofa, t;
fa = fabs(a);
if (fa > 1e18) {
t = log(2.0) + log(fa);
} else {
oofa = 1.0 / fa;
t = fa + fa / (oofa + sqrt(1.0 + oofa * oofa));
t = log1p(t);
}
t = copysign(t, a);
return t;
}
__func__(double atanh(double a))
{
double fa, t;
if (__isnan(a)) {
return a + a;
}
fa = fabs(a);
t = (2.0 * fa) / (1.0 - fa);
t = 0.5 * log1p(t);
if (__isnan(t) || !__signbit(a)) {
return t;
}
return -t;
}
__func__(int ilogb(double a))
{
unsigned long long int i;
int expo = -1022;
if (__isnan(a)) return -__cuda_INT_MAX-1;
if (__isinf(a)) return __cuda_INT_MAX;
memcpy(&i, &a, sizeof(double));
i = i & 0x7fffffffffffffffULL;
if (i == 0) return -__cuda_INT_MAX-1;
if (i >= 0x0010000000000000ULL) {
return (int)(((i >> 52ULL) & 0x7ffU) - 1023);
}
while (i < 0x0010000000000000ULL) {
expo--;
i <<= 1;
}
return expo;
}
__func__(double logb(double a))
{
unsigned long long int i;
int expo = -1022;
if (__isnan(a)) return a + a;
if (__isinf(a)) return fabs(a);
memcpy(&i, &a, sizeof(double));
i = i & 0x7fffffffffffffffULL;
if (i == 0) return -1.0/fabs(a);
if (i >= 0x0010000000000000ULL) {
return (double)((int)((i >> 52ULL) & 0x7ffU) - 1023);
}
while (i < 0x0010000000000000ULL) {
expo--;
i <<= 1;
}
return static_cast<double>(expo);
}
__func__(double remquo(double a, double b, int *quo))
{
unsigned long long int aa, bb;
int rem1 = 1; /* do FPREM1, a.k.a IEEE remainder */
int expo_a;
int expo_b;
unsigned long long mant_a;
unsigned long long mant_b;
unsigned long long mant_c;
unsigned long long temp;
int sign_a;
int sign_b;
int sign_c;
int expo_c;
int expodiff;
int quot = 0; /* initialize quotient */
int l;
int iter;
memcpy(&aa, &a, sizeof(double));
mant_a = (aa << 11ULL) | 0x8000000000000000ULL;
expo_a = (int)((aa >> 52ULL) & 0x7ffU) - 1023;
sign_a = (int)(aa >> 63ULL);
memcpy(&bb, &b, sizeof(double));
mant_b = (bb << 11ULL) | 0x8000000000000000ULL;
expo_b = (int)((bb >> 52ULL) & 0x7ffU) - 1023;
sign_b = (int)(bb >> 63ULL);
sign_c = sign_a; /* remainder has sign of dividend */
expo_c = expo_a; /* default */
/* handled NaNs and infinities */
if (__isnan(a) || __isnan(b)) {
*quo = quot;
return a + b;
}
if (__isinf(a) || (b == 0.0)) {
*quo = quot;
aa = 0xfff8000000000000ULL;
memcpy(&a, &aa, sizeof(double));
return a;
}
if ((a == 0.0) || (__isinf(b))) {
*quo = quot;
return a;
}
/* normalize denormals */
if (expo_a < -1022) {
mant_a = mant_a + mant_a;
while (mant_a < 0x8000000000000000ULL) {
mant_a = mant_a + mant_a;
expo_a--;
}
}
if (expo_b < -1022) {
mant_b = mant_b + mant_b;
while (mant_b < 0x8000000000000000ULL) {
mant_b = mant_b + mant_b;
expo_b--;
}
}
expodiff = expo_a - expo_b;
/* clamp iterations if exponent difference negative */
if (expodiff < 0) {
iter = -1;
} else {
iter = expodiff;
}
/* Shift dividend and divisor right by one bit to prevent overflow
during the division algorithm.
*/
mant_a = mant_a >> 1ULL;
mant_b = mant_b >> 1ULL;
expo_c = expo_a - iter; /* default exponent of result */
/* Use binary longhand division (restoring) */
for (l = 0; l < (iter + 1); l++) {
mant_a = mant_a - mant_b;
if (mant_a & 0x8000000000000000ULL) {
mant_a = mant_a + mant_b;
quot = quot + quot;
} else {
quot = quot + quot + 1;
}
mant_a = mant_a + mant_a;
}
/* Save current remainder */
mant_c = mant_a;
/* If remainder's mantissa is all zeroes, final result is zero. */
if (mant_c == 0) {
quot = quot & 7;
*quo = (sign_a ^ sign_b) ? -quot : quot;
aa = static_cast<unsigned long long int>(sign_c) << 63ULL;
memcpy(&a, &aa, sizeof(double));
return a;
}
/* Normalize result */
while (!(mant_c & 0x8000000000000000ULL)) {
mant_c = mant_c + mant_c;
expo_c--;
}
/* For IEEE remainder (quotient rounded to nearest-even we might need to
do a final subtraction of the divisor from the remainder.
*/
if (rem1 && ((expodiff+1) >= 0)) {
temp = mant_a - mant_b;
/* round quotient to nearest even */
if (((temp != 0ULL) && (!(temp & 0x8000000000000000ULL))) ||
((temp == 0ULL) && (quot & 1))) {
mant_a = mant_a >> 1ULL;
quot++;
/* Since the divisor is greater than the remainder, the result will
have opposite sign of the dividend. To avoid a negative mantissa
when subtracting the divisor from remainder, reverse subtraction
*/
sign_c = 1 ^ sign_c;
expo_c = expo_a - iter + 1;
mant_c = mant_b - mant_a;
/* normalize result */
while (!(mant_c & 0x8000000000000000ULL)) {
mant_c = mant_c + mant_c;
expo_c--;
}
}
}
/* package up result */
if (expo_c >= -1022) { /* normal */
mant_c = ((mant_c >> 11ULL) +
(((static_cast<unsigned long long>(sign_c)) << 63ULL) +
(((unsigned long long)(expo_c + 1022)) << 52ULL)));
} else { /* denormal */
mant_c = (((static_cast<unsigned long long>(sign_c)) << 63ULL) +
(mant_c >> (unsigned long long)(11 - expo_c - 1022)));
}
quot = quot & 7; /* mask quotient down to least significant three bits */
*quo = (sign_a ^ sign_b) ? -quot : quot;
memcpy(&a, &mant_c, sizeof(double));
return a;
}
__func__(double remainder(double a, double b))
{
int quo;
return remquo (a, b, &quo);
}
__func__(double fma (double a, double b, double c))
{
struct {
unsigned int lo;
unsigned int hi;
} xx, yy, zz, ww;
double d;
unsigned int s, t, u, prod0, prod1, prod2, prod3, expo_x, expo_y, expo_z;
memcpy(&xx, &a, sizeof(double));
memcpy(&yy, &b, sizeof(double));
memcpy(&zz, &c, sizeof(double));
expo_z = 0x7FFU;
t = xx.hi >> 20;
expo_x = expo_z & t;
expo_x = expo_x - 1; /* expo(x) - 1 */
t = yy.hi >> 20;
expo_y = expo_z & t;
expo_y = expo_y - 1; /* expo(y) - 1 */
t = zz.hi >> 20;
expo_z = expo_z & t;
expo_z = expo_z - 1; /* expo(z) - 1 */
if (!((expo_x <= 0x7FDU) &&
(expo_y <= 0x7FDU) &&
(expo_z <= 0x7FDU))) {
/* fma (nan, y, z) --> nan
fma (x, nan, z) --> nan
fma (x, y, nan) --> nan
*/
if (((yy.hi << 1) | (yy.lo != 0)) > 0xffe00000U) {
yy.hi |= 0x00080000U;
memcpy(&d, &yy, sizeof(double));
return d;
}
if (((zz.hi << 1) | (zz.lo != 0)) > 0xffe00000U) {
zz.hi |= 0x00080000U;
memcpy(&d, &zz, sizeof(double));
return d;
}
if (((xx.hi << 1) | (xx.lo != 0)) > 0xffe00000U) {
xx.hi |= 0x00080000U;
memcpy(&d, &xx, sizeof(double));
return d;
}
/* fma (0, inf, z) --> INDEFINITE
fma (inf, 0, z) --> INDEFINITE
fma (-inf,+y,+inf) --> INDEFINITE
fma (+x,-inf,+inf) --> INDEFINITE
fma (+inf,-y,+inf) --> INDEFINITE
fma (-x,+inf,+inf) --> INDEFINITE
fma (-inf,-y,-inf) --> INDEFINITE
fma (-x,-inf,-inf) --> INDEFINITE
fma (+inf,+y,-inf) --> INDEFINITE
fma (+x,+inf,-inf) --> INDEFINITE
*/
if (((((xx.hi << 1) | xx.lo) == 0) &&
(((yy.hi << 1) | (yy.lo != 0)) == 0xffe00000U)) ||
((((yy.hi << 1) | yy.lo) == 0) &&
(((xx.hi << 1) | (xx.lo != 0)) == 0xffe00000U))) {
xx.hi = 0xfff80000U;
xx.lo = 0x00000000U;
memcpy(&d, &xx, sizeof(double));
return d;
}
if (((zz.hi << 1) | (zz.lo != 0)) == 0xffe00000U) {
if ((((yy.hi << 1) | (yy.lo != 0)) == 0xffe00000U) ||
(((xx.hi << 1) | (xx.lo != 0)) == 0xffe00000U)) {
if ((int)(xx.hi ^ yy.hi ^ zz.hi) < 0) {
xx.hi = 0xfff80000U;
xx.lo = 0x00000000U;
memcpy(&d, &xx, sizeof(double));
return d;
}
}
}
/* fma (inf, y, z) --> inf
fma (x, inf, z) --> inf
fma (x, y, inf) --> inf
*/
if (((xx.hi << 1) | (xx.lo != 0)) == 0xffe00000U) {
xx.hi = xx.hi ^ (yy.hi & 0x80000000U);
memcpy(&d, &xx, sizeof(double));
return d;
}
if (((yy.hi << 1) | (yy.lo != 0)) == 0xffe00000U) {
yy.hi = yy.hi ^ (xx.hi & 0x80000000U);
memcpy(&d, &yy, sizeof(double));
return d;
}
if (((zz.hi << 1) | (zz.lo != 0)) == 0xffe00000U) {
memcpy(&d, &zz, sizeof(double));
return d;
}
/* fma (+0, -y, -0) --> -0
fma (-0, +y, -0) --> -0
fma (+x, -0, -0) --> -0
fma (-x, +0, -0) --> -0
*/
if ((zz.hi == 0x80000000U) && (zz.lo == 0)) {
if ((((xx.hi << 1) | xx.lo) == 0) ||
(((yy.hi << 1) | yy.lo) == 0)) {
if ((int)(xx.hi ^ yy.hi) < 0) {
memcpy(&d, &zz, sizeof(double));
return d;
}
}
}
/* fma (0, y, 0) --> +0 (-0 if round down and signs of addend differ)
fma (x, 0, 0) --> +0 (-0 if round down and signs of addend differ)
*/
if ((((zz.hi << 1) | zz.lo) == 0) &&
((((xx.hi << 1) | xx.lo) == 0) ||
(((yy.hi << 1) | yy.lo) == 0))) {
zz.hi &= 0x7fffffffU;
memcpy(&d, &zz, sizeof(double));
return d;
}
/* fma (0, y, z) --> z
fma (x, 0, z) --> z
*/
if ((((xx.hi << 1) | xx.lo) == 0) ||
(((yy.hi << 1) | yy.lo) == 0)) {
memcpy(&d, &zz, sizeof(double));
return d;
}
if (expo_x == 0xffffffffU) {
expo_x++;
t = xx.hi & 0x80000000U;
s = xx.lo >> 21;
xx.lo = xx.lo << 11;
xx.hi = xx.hi << 11;
xx.hi = xx.hi | s;
if (!xx.hi) {
xx.hi = xx.lo;
xx.lo = 0;
expo_x -= 32;
}
while (static_cast<int>(xx.hi) > 0) {
s = xx.lo >> 31;
xx.lo = xx.lo + xx.lo;
xx.hi = xx.hi + xx.hi;
xx.hi = xx.hi | s;
expo_x--;
}
xx.lo = (xx.lo >> 11);
xx.lo |= (xx.hi << 21);
xx.hi = (xx.hi >> 11) | t;
}
if (expo_y == 0xffffffffU) {
expo_y++;
t = yy.hi & 0x80000000U;
s = yy.lo >> 21;
yy.lo = yy.lo << 11;
yy.hi = yy.hi << 11;
yy.hi = yy.hi | s;
if (!yy.hi) {
yy.hi = yy.lo;
yy.lo = 0;
expo_y -= 32;
}
while (static_cast<int>(yy.hi) > 0) {
s = yy.lo >> 31;
yy.lo = yy.lo + yy.lo;
yy.hi = yy.hi + yy.hi;
yy.hi = yy.hi | s;
expo_y--;
}
yy.lo = (yy.lo >> 11);
yy.lo |= (yy.hi << 21);
yy.hi = (yy.hi >> 11) | t;
}
if (expo_z == 0xffffffffU) {
expo_z++;
t = zz.hi & 0x80000000U;
s = zz.lo >> 21;
zz.lo = zz.lo << 11;
zz.hi = zz.hi << 11;
zz.hi = zz.hi | s;
if (!zz.hi) {
zz.hi = zz.lo;
zz.lo = 0;
expo_z -= 32;
}
while (static_cast<int>(zz.hi) > 0) {
s = zz.lo >> 31;
zz.lo = zz.lo + zz.lo;
zz.hi = zz.hi + zz.hi;
zz.hi = zz.hi | s;
expo_z--;
}
zz.lo = (zz.lo >> 11);
zz.lo |= (zz.hi << 21);
zz.hi = (zz.hi >> 11) | t;
}
}
expo_x = expo_x + expo_y;
expo_y = xx.hi ^ yy.hi;
t = xx.lo >> 21;
xx.lo = xx.lo << 11;
xx.hi = xx.hi << 11;
xx.hi = xx.hi | t;
yy.hi = yy.hi & 0x000fffffU;
xx.hi = xx.hi | 0x80000000U; /* set mantissa hidden bit */
yy.hi = yy.hi | 0x00100000U; /* set mantissa hidden bit */
prod0 = xx.lo * yy.lo;
prod1 =(unsigned)((static_cast<unsigned long long>(xx.lo)*static_cast<unsigned long long>(yy.lo))>>32ULL);
prod2 = xx.hi * yy.lo;
prod3 = xx.lo * yy.hi;
prod1 += prod2;
t = (unsigned)(prod1 < prod2);
prod1 += prod3;
t += prod1 < prod3;
prod2 =(unsigned)((static_cast<unsigned long long>(xx.hi)*static_cast<unsigned long long>(yy.lo))>>32ULL);
prod3 =(unsigned)((static_cast<unsigned long long>(xx.lo)*static_cast<unsigned long long>(yy.hi))>>32ULL);
prod2 += prod3;
s = (unsigned)(prod2 < prod3);
prod3 = xx.hi * yy.hi;
prod2 += prod3;
s += prod2 < prod3;
prod2 += t;
s += prod2 < t;
prod3 =(unsigned)((static_cast<unsigned long long>(xx.hi)*static_cast<unsigned long long>(yy.hi))>>32ULL);
prod3 = prod3 + s;
yy.lo = prod0; /* mantissa */
yy.hi = prod1; /* mantissa */
xx.lo = prod2; /* mantissa */
xx.hi = prod3; /* mantissa */
expo_x = expo_x - (1023 - 2); /* expo-1 */
expo_y = expo_y & 0x80000000U; /* sign */
if (xx.hi < 0x00100000U) {
s = xx.lo >> 31;
s = (xx.hi << 1) + s;
xx.hi = s;
s = yy.hi >> 31;
s = (xx.lo << 1) + s;
xx.lo = s;
s = yy.lo >> 31;
s = (yy.hi << 1) + s;
yy.hi = s;
s = yy.lo << 1;
yy.lo = s;
expo_x--;
}
t = 0;
if (((zz.hi << 1) | zz.lo) != 0) { /* z is not zero */
s = zz.hi & 0x80000000U;
zz.hi &= 0x000fffffU;
zz.hi |= 0x00100000U;
ww.hi = 0;
ww.lo = 0;
/* compare and swap. put augend into xx:yy */
if (static_cast<int>(expo_z) > static_cast<int>(expo_x)) {
t = expo_z;
expo_z = expo_x;
expo_x = t;
t = zz.hi;
zz.hi = xx.hi;
xx.hi = t;
t = zz.lo;
zz.lo = xx.lo;
xx.lo = t;
t = ww.hi;
ww.hi = yy.hi;
yy.hi = t;
t = ww.lo;
ww.lo = yy.lo;
yy.lo = t;
t = expo_y;
expo_y = s;
s = t;
}
/* augend_sign = expo_y, augend_mant = xx:yy, augend_expo = expo_x */
/* addend_sign = s, addend_mant = zz:ww, addend_expo = expo_z */
expo_z = expo_x - expo_z;
u = expo_y ^ s;
if (expo_z <= 107) {
/* denormalize addend */
t = 0;
while (expo_z >= 32) {
t = ww.lo | (t != 0);
ww.lo = ww.hi;
ww.hi = zz.lo;
zz.lo = zz.hi;
zz.hi = 0;
expo_z -= 32;
}
if (expo_z) {
t = (t >> expo_z) | (ww.lo << (32 - expo_z)) |
((t << (32 - expo_z)) != 0);
ww.lo = (ww.lo >> expo_z) | (ww.hi << (32 - expo_z));
ww.hi = (ww.hi >> expo_z) | (zz.lo << (32 - expo_z));
zz.lo = (zz.lo >> expo_z) | (zz.hi << (32 - expo_z));
zz.hi = (zz.hi >> expo_z);
}
} else {
t = 1;
ww.lo = 0;
ww.hi = 0;
zz.lo = 0;
zz.hi = 0;
}
if (static_cast<int>(u) < 0) {
/* signs differ, effective subtraction */
t = (unsigned)(-static_cast<int>(t));
s = (unsigned)(t != 0);
u = yy.lo - s;
s = (unsigned)(u > yy.lo);
yy.lo = u - ww.lo;
s += yy.lo > u;
u = yy.hi - s;
s = (unsigned)(u > yy.hi);
yy.hi = u - ww.hi;
s += yy.hi > u;
u = xx.lo - s;
s = (unsigned)(u > xx.lo);
xx.lo = u - zz.lo;
s += xx.lo > u;
xx.hi = (xx.hi - zz.hi) - s;
if (!(xx.hi | xx.lo | yy.hi | yy.lo | t)) {
/* complete cancelation, return 0 */
memcpy(&d, &xx, sizeof(double));
return d;
}
if (static_cast<int>(xx.hi) < 0) {
/* Oops, augend had smaller mantissa. Negate mantissa and flip
sign of result
*/
t = ~t;
yy.lo = ~yy.lo;
yy.hi = ~yy.hi;
xx.lo = ~xx.lo;
xx.hi = ~xx.hi;
if (++t == 0) {
if (++yy.lo == 0) {
if (++yy.hi == 0) {
if (++xx.lo == 0) {
++xx.hi;
}
}
}
}
expo_y ^= 0x80000000U;
}
/* normalize mantissa, if necessary */
while (!(xx.hi & 0x00100000U)) {
xx.hi = (xx.hi << 1) | (xx.lo >> 31);
xx.lo = (xx.lo << 1) | (yy.hi >> 31);
yy.hi = (yy.hi << 1) | (yy.lo >> 31);
yy.lo = (yy.lo << 1);
expo_x--;
}
} else {
/* signs are the same, effective addition */
yy.lo = yy.lo + ww.lo;
s = (unsigned)(yy.lo < ww.lo);
yy.hi = yy.hi + s;
u = (unsigned)(yy.hi < s);
yy.hi = yy.hi + ww.hi;
u += yy.hi < ww.hi;
xx.lo = xx.lo + u;
s = (unsigned)(xx.lo < u);
xx.lo = xx.lo + zz.lo;
s += xx.lo < zz.lo;
xx.hi = xx.hi + zz.hi + s;
if (xx.hi & 0x00200000U) {
t = t | (yy.lo << 31);
yy.lo = (yy.lo >> 1) | (yy.hi << 31);
yy.hi = (yy.hi >> 1) | (xx.lo << 31);
xx.lo = (xx.lo >> 1) | (xx.hi << 31);
xx.hi = ((xx.hi & 0x80000000U) | (xx.hi >> 1)) & ~0x40000000U;
expo_x++;
}
}
}
t = yy.lo | (t != 0);
t = yy.hi | (t != 0);
xx.hi |= expo_y; /* or in sign bit */
if (expo_x <= 0x7FDU) {
/* normal */
xx.hi = xx.hi & ~0x00100000U; /* lop off integer bit */
s = xx.lo & 1; /* mantissa lsb */
u = xx.lo;
xx.lo += (t == 0x80000000U) ? s : (t >> 31);
xx.hi += (u > xx.lo);
xx.hi += ((expo_x + 1) << 20);
memcpy(&d, &xx, sizeof(double));
return d;
} else if (static_cast<int>(expo_x) >= 2046) {
/* overflow */
xx.hi = (xx.hi & 0x80000000U) | 0x7ff00000U;
xx.lo = 0;
memcpy(&d, &xx, sizeof(double));
return d;
}
/* subnormal */
expo_x = (unsigned)(-static_cast<int>(expo_x));
if (expo_x > 54) {
xx.hi = xx.hi & 0x80000000U;
xx.lo = 0;
memcpy(&d, &xx, sizeof(double));
return d;
}
yy.hi = xx.hi & 0x80000000U; /* save sign bit */
xx.hi = xx.hi & ~0xffe00000U;
if (expo_x >= 32) {
t = xx.lo | (t != 0);
xx.lo = xx.hi;
xx.hi = 0;
expo_x -= 32;
}
if (expo_x) {
t = (t >> expo_x) | (xx.lo << (32 - expo_x)) | (t != 0);
xx.lo = (xx.lo >> expo_x) | (xx.hi << (32 - expo_x));
xx.hi = (xx.hi >> expo_x);
}
expo_x = xx.lo & 1;
u = xx.lo;
xx.lo += (t == 0x80000000U) ? expo_x : (t >> 31);
xx.hi += (u > xx.lo);
xx.hi |= yy.hi;
memcpy(&d, &xx, sizeof(double));
return d;
}
__func__(double nextafter(double a, double b))
{
unsigned long long int ia;
unsigned long long int ib;
memcpy(&ia, &a, sizeof(double));
memcpy(&ib, &b, sizeof(double));
if (__isnan(a) || __isnan(b)) return a + b; /* NaN */
if (((ia | ib) << 1ULL) == 0ULL) return b;
if (a == 0.0) {
return copysign (4.9406564584124654e-324, b); /* crossover */
}
if ((a < b) && (a < 0.0)) ia--;
if ((a < b) && (a > 0.0)) ia++;
if ((a > b) && (a < 0.0)) ia++;
if ((a > b) && (a > 0.0)) ia--;
memcpy(&a, &ia, sizeof(double));
return a;
}
__func__(double erf(double a))
{
double t, r, q;
t = fabs(a);
if (t >= 1.0) {
r = -1.28836351230756500E-019;
r = r * t + 1.30597472161093370E-017;
r = r * t - 6.33924401259620500E-016;
r = r * t + 1.96231865908940140E-014;
r = r * t - 4.35272243559990750E-013;
r = r * t + 7.37083927929352150E-012;
r = r * t - 9.91402142550461630E-011;
r = r * t + 1.08817017167760820E-009;
r = r * t - 9.93918713097634620E-009;
r = r * t + 7.66739923255145500E-008;
r = r * t - 5.05440278302806720E-007;
r = r * t + 2.87474157099000620E-006;
r = r * t - 1.42246725399722510E-005;
r = r * t + 6.16994555079419460E-005;
r = r * t - 2.36305221938908790E-004;
r = r * t + 8.05032844055371070E-004;
r = r * t - 2.45833366629108140E-003;
r = r * t + 6.78340988296706120E-003;
r = r * t - 1.70509103597554640E-002;
r = r * t + 3.93322852515666300E-002;
r = r * t - 8.37271292613764040E-002;
r = r * t + 1.64870423707623280E-001;
r = r * t - 2.99729521787681470E-001;
r = r * t + 4.99394435612628580E-001;
r = r * t - 7.52014596480123030E-001;
r = r * t + 9.99933138314926250E-001;
r = r * t - 1.12836725321102670E+000;
r = r * t + 9.99998988715182450E-001;
q = exp (-t * t);
r = 1.0 - r * q;
if (t >= 6.5) {
r = 1.0;
}
a = copysign (r, a);
} else {
q = a * a;
r = -7.77946848895991420E-010;
r = r * q + 1.37109803980285950E-008;
r = r * q - 1.62063137584932240E-007;
r = r * q + 1.64471315712790040E-006;
r = r * q - 1.49247123020098620E-005;
r = r * q + 1.20552935769006260E-004;
r = r * q - 8.54832592931448980E-004;
r = r * q + 5.22397760611847340E-003;
r = r * q - 2.68661706431114690E-002;
r = r * q + 1.12837916709441850E-001;
r = r * q - 3.76126389031835210E-001;
r = r * q + 1.12837916709551260E+000;
a = r * a;
}
return a;
}
__func__(double erfc(double a))
{
double p, q, h, l;
if (a < 0.75) {
return 1.0 - erf(a);
}
if (a > 27.3) {
return 0.0;
}
if (a < 5.0) {
double t;
t = 1.0 / a;
p = 1.9759923722227928E-008;
p = p * t - 1.0000002670474897E+000;
p = p * t - 7.4935303236347828E-001;
p = p * t - 1.5648136328071860E-001;
p = p * t + 1.2871196242447239E-001;
p = p * t + 1.1126459974811195E-001;
p = p * t + 4.0678642255914332E-002;
p = p * t + 7.9915414156678296E-003;
p = p * t + 7.1458332107840234E-004;
q = t + 2.7493547525030619E+000;
q = q * t + 3.3984254815725423E+000;
q = q * t + 2.4635304979947761E+000;
q = q * t + 1.1405284734691286E+000;
q = q * t + 3.4130157606195649E-001;
q = q * t + 6.2250967676044953E-002;
q = q * t + 5.5661370941268700E-003;
q = q * t + 1.0575248365468671E-009;
p = p / q;
p = p * t;
h = ((int)(a * 16.0)) * 0.0625;
l = (a - h) * (a + h);
q = exp(-h * h) * exp(-l);
q = q * 0.5;
p = p * q + q;
p = p * t;
} else {
double ooa, ooasq;
ooa = 1.0 / a;
ooasq = ooa * ooa;
p = -4.0025406686930527E+005;
p = p * ooasq + 1.4420582543942123E+005;
p = p * ooasq - 2.7664185780951841E+004;
p = p * ooasq + 4.1144611644767283E+003;
p = p * ooasq - 5.8706000519209351E+002;
p = p * ooasq + 9.1490086446323375E+001;
p = p * ooasq - 1.6659491387740221E+001;
p = p * ooasq + 3.7024804085481784E+000;
p = p * ooasq - 1.0578553994424316E+000;
p = p * ooasq + 4.2314218745087778E-001;
p = p * ooasq - 2.8209479177354962E-001;
p = p * ooasq + 5.6418958354775606E-001;
h = a * a;
h = ((int)(a * 16.0)) * 0.0625;
l = (a - h) * (a + h);
q = exp(-h * h) * exp(-l);
p = p * ooa;
p = p * q;
}
return p;
}
__func__(double lgamma(double a))
{
double s;
double t;
double i;
double fa;
double sum;
long long int quot;
if (__isnan(a) || __isinf(a)) {
return a * a;
}
fa = fabs(a);
if (fa >= 3.0) {
if (fa >= 8.0) {
/* Stirling approximation; coefficients from Hart et al, "Computer
* Approximations", Wiley 1968. Approximation 5404.
*/
s = 1.0 / fa;
t = s * s;
sum = -0.1633436431e-2;
sum = sum * t + 0.83645878922e-3;
sum = sum * t - 0.5951896861197e-3;
sum = sum * t + 0.793650576493454e-3;
sum = sum * t - 0.277777777735865004e-2;
sum = sum * t + 0.833333333333331018375e-1;
sum = sum * s + 0.918938533204672;
s = 0.5 * log (fa);
t = fa - 0.5;
s = s * t;
t = s - fa;
s = s + sum;
t = t + s;
} else {
i = fa - 3.0;
s = -4.02412642744125560E+003;
s = s * i - 2.97693796998962000E+005;
s = s * i - 6.38367087682528790E+006;
s = s * i - 5.57807214576539320E+007;
s = s * i - 2.24585140671479230E+008;
s = s * i - 4.70690608529125090E+008;
s = s * i - 7.62587065363263010E+008;
s = s * i - 9.71405112477113250E+008;
t = i - 1.02277248359873170E+003;
t = t * i - 1.34815350617954480E+005;
t = t * i - 4.64321188814343610E+006;
t = t * i - 6.48011106025542540E+007;
t = t * i - 4.19763847787431360E+008;
t = t * i - 1.25629926018000720E+009;
t = t * i - 1.40144133846491690E+009;
t = s / t;
t = t + i;
}
} else if (fa >= 1.5) {
i = fa - 2.0;
t = 9.84839283076310610E-009;
t = t * i - 6.69743850483466500E-008;
t = t * i + 2.16565148880011450E-007;
t = t * i - 4.86170275781575260E-007;
t = t * i + 9.77962097401114400E-007;
t = t * i - 2.03041287574791810E-006;
t = t * i + 4.36119725805364580E-006;
t = t * i - 9.43829310866446590E-006;
t = t * i + 2.05106878496644220E-005;
t = t * i - 4.49271383742108440E-005;
t = t * i + 9.94570466342226000E-005;
t = t * i - 2.23154589559238440E-004;
t = t * i + 5.09669559149637430E-004;
t = t * i - 1.19275392649162300E-003;
t = t * i + 2.89051032936815490E-003;
t = t * i - 7.38555102806811700E-003;
t = t * i + 2.05808084278121250E-002;
t = t * i - 6.73523010532073720E-002;
t = t * i + 3.22467033424113040E-001;
t = t * i + 4.22784335098467190E-001;
t = t * i;
} else if (fa >= 0.7) {
i = 1.0 - fa;
t = 1.17786911519331130E-002;
t = t * i + 3.89046747413522300E-002;
t = t * i + 5.90045711362049900E-002;
t = t * i + 6.02143305254344420E-002;
t = t * i + 5.61652708964839180E-002;
t = t * i + 5.75052755193461370E-002;
t = t * i + 6.21061973447320710E-002;
t = t * i + 6.67614724532521880E-002;
t = t * i + 7.14856037245421020E-002;
t = t * i + 7.69311251313347100E-002;
t = t * i + 8.33503129714946310E-002;
t = t * i + 9.09538288991182800E-002;
t = t * i + 1.00099591546322310E-001;
t = t * i + 1.11334278141734510E-001;
t = t * i + 1.25509666613462880E-001;
t = t * i + 1.44049896457704160E-001;
t = t * i + 1.69557177031481600E-001;
t = t * i + 2.07385551032182120E-001;
t = t * i + 2.70580808427600350E-001;
t = t * i + 4.00685634386517050E-001;
t = t * i + 8.22467033424113540E-001;
t = t * i + 5.77215664901532870E-001;
t = t * i;
} else {
t = -9.04051686831357990E-008;
t = t * fa + 7.06814224969349250E-007;
t = t * fa - 3.80702154637902830E-007;
t = t * fa - 2.12880892189316100E-005;
t = t * fa + 1.29108470307156190E-004;
t = t * fa - 2.15932815215386580E-004;
t = t * fa - 1.16484324388538480E-003;
t = t * fa + 7.21883433044470670E-003;
t = t * fa - 9.62194579514229560E-003;
t = t * fa - 4.21977386992884450E-002;
t = t * fa + 1.66538611813682460E-001;
t = t * fa - 4.20026350606819980E-002;
t = t * fa - 6.55878071519427450E-001;
t = t * fa + 5.77215664901523870E-001;
t = t * fa;
t = t * fa + fa;
t = -log (t);
}
if (a >= 0.0) return t;
if (fa < 1e-19) return -log(fa);
i = floor(fa);
if (fa == i) return 1.0 / (fa - i); /* a is an integer: return infinity */
i = rint (2.0 * fa);
quot = static_cast<long long int>(i);
i = fa - 0.5 * i;
i = i * CUDART_PI;
if (quot & 1) {
i = cos(i);
} else {
i = sin(i);
}
i = fabs(i);
t = log(CUDART_PI / (i * fa)) - t;
return t;
}
__func__(unsigned long long int __internal_host_nan_kernel(const char *s))
{
unsigned long long i = 0;
int c;
int ovfl = 0;
int invld = 0;
if (s && (*s == '0')) {
s++;
if ((*s == 'x') || (*s == 'X')) {
s++;
while (*s == '0') s++;
while (*s) {
if (i > 0x0fffffffffffffffULL) {
ovfl = 1;
}
c = (((*s) >= 'A') && ((*s) <= 'F')) ? (*s + 'a' - 'A') : (*s);
if ((c >= 'a') && (c <= 'f')) {
c = c - 'a' + 10;
i = i * 16 + c;
} else if ((c >= '0') && (c <= '9')) {
c = c - '0';
i = i * 16 + c;
} else {
invld = 1;
}
s++;
}
} else {
while (*s == '0') s++;
while (*s) {
if (i > 0x1fffffffffffffffULL) {
ovfl = 1;
}
c = *s;
if ((c >= '0') && (c <= '7')) {
c = c - '0';
i = i * 8 + c;
} else {
invld = 1;
}
s++;
}
}
} else if (s) {
while (*s) {
c = *s;
if ((i > 1844674407370955161ULL) ||
((i == 1844674407370955161ULL) && (c > '5'))) {
ovfl = 1;
}
if ((c >= '0') && (c <= '9')) {
c = c - '0';
i = i * 10 + c;
} else {
invld = 1;
}
s++;
}
}
if (ovfl) {
i = ~0ULL;
}
if (invld) {
i = 0ULL;
}
i = (i & 0x000fffffffffffffULL) | 0x7ff8000000000000ULL;
return i;
}
__func__(double nan(const char *tagp))
{
unsigned long long l;
double d;
l = __internal_host_nan_kernel(tagp);
memcpy(&d, &l, sizeof(double));
return d;
}
__func__(double __host_tgamma_kernel(double a))
{
double t;
t = - 4.4268934071252475E-010;
t = t * a - 2.0266591846658954E-007;
t = t * a + 1.1381211721119527E-006;
t = t * a - 1.2507734816630748E-006;
t = t * a - 2.0136501740408771E-005;
t = t * a + 1.2805012607354486E-004;
t = t * a - 2.1524140811527418E-004;
t = t * a - 1.1651675459704604E-003;
t = t * a + 7.2189432248466381E-003;
t = t * a - 9.6219715326862632E-003;
t = t * a - 4.2197734554722394E-002;
t = t * a + 1.6653861138250356E-001;
t = t * a - 4.2002635034105444E-002;
t = t * a - 6.5587807152025712E-001;
t = t * a + 5.7721566490153287E-001;
t = t * a + 1.0000000000000000E+000;
return t;
}
__func__(double __host_stirling_poly(double a))
{
double x = 1.0 / a;
double z = 0.0;
z = + 8.3949872067208726e-004;
z = z * x - 5.1717909082605919e-005;
z = z * x - 5.9216643735369393e-004;
z = z * x + 6.9728137583658571e-005;
z = z * x + 7.8403922172006662e-004;
z = z * x - 2.2947209362139917e-004;
z = z * x - 2.6813271604938273e-003;
z = z * x + 3.4722222222222220e-003;
z = z * x + 8.3333333333333329e-002;
z = z * x + 1.0000000000000000e+000;
return z;
}
__func__(double __host_tgamma_stirling(double a))
{
double z;
double x;
z = __host_stirling_poly (a);
if (a < 142.0) {
x = pow (a, a - 0.5);
a = x * exp (-a);
a = a * CUDART_SQRT_2PI;
return a * z;
} else if (a < 172.0) {
x = pow (a, 0.5 * a - 0.25);
a = x * exp (-a);
a = a * CUDART_SQRT_2PI;
a = a * z;
return a * x;
} else {
return exp(1000.0); /* INF */
}
}
__func__(double tgamma(double a))
{
double s, xx, x = a;
if (__isnan(a)) {
return a + a;
}
if (fabs(x) < 20.0) {
if (x >= 0.0) {
s = 1.0;
xx = x;
while (xx > 1.5) {
xx = xx - 1.0;
s = s * xx;
}
if (x >= 0.5) {
xx = xx - 1.0;
}
xx = __host_tgamma_kernel (xx);
if (x < 0.5) {
xx = xx * x;
}
s = s / xx;
} else {
xx = x;
s = xx;
if (x == floor(x)) {
return 0.0 / (x - floor(x));
}
while (xx < -0.5) {
xx = xx + 1.0;
s = s * xx;
}
xx = __host_tgamma_kernel (xx);
s = s * xx;
s = 1.0 / s;
}
return s;
} else {
if (x >= 0.0) {
return __host_tgamma_stirling (x);
} else {
double t;
int quot;
if (x == floor(x)) {
return 0.0 / (x - floor(x));
}
if (x < -185.0) {
int negative;
x = floor(x);
negative = ((x - (2.0 * floor(0.5 * x))) == 1.0);
return negative ? (-1.0 / 1e308 / 1e308) : CUDART_ZERO;
}
/* compute sin(pi*x) accurately */
xx = rint (2.0 * x);
quot = static_cast<int>(xx);
xx = -0.5 * xx + x;
xx = xx * CUDART_PI;
if (quot & 1) {
xx = cos (xx);
} else {
xx = sin (xx);
}
if (quot & 2) {
xx = -xx;
}
x = fabs (x);
s = exp (-x);
t = x - 0.5;
if (x > 140.0) t = 0.5 * t;
t = pow (x, t);
if (x > 140.0) s = s * t;
s = s * __host_stirling_poly (x);
s = s * x;
s = s * xx;
s = 1.0 / s;
s = s * CUDART_SQRT_PIO2;
s = s / t;
return s;
}
}
}
#endif /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
/*******************************************************************************
* *
* HOST IMPLEMENTATION FOR FLOAT AND LONG DOUBLE ROUTINES FOR WINDOWS PLATFORM *
* MAP FLOAT AND LONG DOUBLE ROUTINES TO DOUBLE ROUTINES *
* *
*******************************************************************************/
__func__(int __signbitl(const long double a))
{
return __signbit(static_cast<double>(a));
}
__func__(int __signbitf(const float a))
{
return __signbit(static_cast<double>(a));
}
__func__(int __finitel(const long double a))
{
return __finite(static_cast<double>(a));
}
__func__(int __finitef(const float a))
{
return __finite(static_cast<double>(a));
}
__func__(int __isinfl(const long double a))
{
return __isinf(static_cast<double>(a));
}
__func__(int __isinff(const float a))
{
return __isinf(static_cast<double>(a));
}
__func__(int __isnanl(const long double a))
{
return __isnan(static_cast<double>(a));
}
__func__(int __isnanf(const float a))
{
return __isnan(static_cast<double>(a));
}
#if (!defined(_MSC_VER) || _MSC_VER < 1800)
__func__(float fmaxf(const float a, const float b))
{
return static_cast<float>(fmax(static_cast<double>(a), static_cast<double>(b)));
}
__func__(float fminf(const float a, const float b))
{
return static_cast<float>(fmin(static_cast<double>(a), static_cast<double>(b)));
}
__func__(float roundf(const float a))
{
return static_cast<float>(round(static_cast<double>(a)));
}
__func__(long int lroundf(const float a))
{
return lround(static_cast<double>(a));
}
__func__(long long int llroundf(const float a))
{
return llround(static_cast<double>(a));
}
__func__(float truncf(const float a))
{
return static_cast<float>(trunc(static_cast<double>(a)));
}
__func__(float rintf(const float a))
{
return static_cast<float>(rint(static_cast<double>(a)));
}
__func__(float nearbyintf(const float a))
{
return static_cast<float>(nearbyint(static_cast<double>(a)));
}
__func__(long int lrintf(const float a))
{
return lrint(static_cast<double>(a));
}
__func__(long long int llrintf(const float a))
{
return llrint(static_cast<double>(a));
}
__func__(float logbf(const float a))
{
return static_cast<float>(logb(static_cast<double>(a)));
}
__func__(float scalblnf(const float a, const long int b))
{
return static_cast<float>(scalbln(static_cast<double>(a), b));
}
__func__(float log2f(const float a))
{
return static_cast<float>(log2(static_cast<double>(a)));
}
__func__(float exp2f(const float a))
{
return static_cast<float>(exp2(static_cast<double>(a)));
}
__func__(float acoshf(const float a))
{
return static_cast<float>(acosh(static_cast<double>(a)));
}
__func__(float asinhf(const float a))
{
return static_cast<float>(asinh(static_cast<double>(a)));
}
__func__(float atanhf(const float a))
{
return static_cast<float>(atanh(static_cast<double>(a)));
}
__func__(float cbrtf(const float a))
{
return static_cast<float>(cbrt(static_cast<double>(a)));
}
__func__(float expm1f(const float a))
{
return static_cast<float>(expm1(static_cast<double>(a)));
}
__func__(float fdimf(const float a, const float b))
{
return static_cast<float>(fdim(static_cast<double>(a), static_cast<double>(b)));
}
__func__(float log1pf(const float a))
{
return static_cast<float>(log1p(static_cast<double>(a)));
}
__func__(float scalbnf(const float a, const int b))
{
return static_cast<float>(scalbn(static_cast<double>(a), b));
}
__func__(float fmaf(const float a, const float b, const float c))
{
return static_cast<float>(fma(static_cast<double>(a), static_cast<double>(b), static_cast<double>(c)));
}
__func__(int ilogbf(const float a))
{
return ilogb(static_cast<double>(a));
}
__func__(float erff(const float a))
{
return static_cast<float>(erf(static_cast<double>(a)));
}
__func__(float erfcf(const float a))
{
return static_cast<float>(erfc(static_cast<double>(a)));
}
__func__(float lgammaf(const float a))
{
return static_cast<float>(lgamma(static_cast<double>(a)));
}
__func__(float tgammaf(const float a))
{
return static_cast<float>(tgamma(static_cast<double>(a)));
}
__func__(float remquof(const float a, const float b, int *quo))
{
return static_cast<float>(remquo(static_cast<double>(a), static_cast<double>(b), quo));
}
__func__(float remainderf(const float a, const float b))
{
return static_cast<float>(remainder(static_cast<double>(a), static_cast<double>(b)));
}
#endif /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
#if (defined _MSC_VER) && (_MSC_VER >= 1700)
__func__(float j0f(const float a))
{
return static_cast<float>(_j0(static_cast<double>(a)));
}
__func__(float j1f(const float a))
{
return static_cast<float>(_j1(static_cast<double>(a)));
}
__func__(float jnf(const int n, const float a))
{
return static_cast<float>(_jn(n, static_cast<double>(a)));
}
__func__(float y0f(const float a))
{
return static_cast<float>(_y0(static_cast<double>(a)));
}
__func__(float y1f(const float a))
{
return static_cast<float>(_y1(static_cast<double>(a)));
}
__func__(float ynf(const int n, const float a))
{
return static_cast<float>(_yn(n, static_cast<double>(a)));
}
#endif /* (defined _MSC_VER) && (_MSC_VER >= 1700) */
/*******************************************************************************
* *
* HOST IMPLEMENTATION FOR FLOAT ROUTINES FOR WINDOWS PLATFORM *
* *
*******************************************************************************/
#if (!defined(_MSC_VER) || _MSC_VER < 1800)
__func__(float copysignf(float a, const float b))
{
unsigned int aa, bb;
memcpy(&aa, &a, sizeof(float));
memcpy(&bb, &b, sizeof(float));
aa = (aa & ~0x80000000U) | (bb & 0x80000000U);
memcpy(&a, &aa, sizeof(float));
return a;
}
__func__(float nextafterf(float a, const float b))
{
unsigned int ia;
unsigned int ib;
memcpy(&ia, &a, sizeof(float));
memcpy(&ib, &b, sizeof(float));
if (__isnanf(a) || __isnanf(b)) return a + b; /*NaN*/
if (((ia | ib) << 1U) == 0U) return b;
if (a == 0.0F) {
return copysignf(1.401298464e-045F, b); /*crossover*/
}
if ((a < b) && (a < 0.0F)) ia--;
if ((a < b) && (a > 0.0F)) ia++;
if ((a > b) && (a < 0.0F)) ia++;
if ((a > b) && (a > 0.0F)) ia--;
memcpy(&a, &ia, sizeof(float));
return a;
}
__func__(float nanf(const char *tagp))
{
float f;
unsigned int i;
i = static_cast<unsigned int>(__internal_host_nan_kernel(tagp));
i = (i & 0x007fffffU) | 0x7fc00000U;
memcpy(&f, &i, sizeof(float));
return f;
}
#endif /* (!defined(_MSC_VER) || _MSC_VER < 1800) */
#endif /* _WIN32 */
/*******************************************************************************
* *
* HOST IMPLEMENTATION FOR DOUBLE AND FLOAT ROUTINES. ALL PLATFORMS *
* *
*******************************************************************************/
__func__(double rsqrt(const double a))
{
return 1.0 / sqrt(a);
}
__func__(double rcbrt(const double a))
{
double s, t;
if (__isnan(a)) {
return a + a;
}
if (a == 0.0 || __isinf(a)) {
return 1.0 / a;
}
s = fabs(a);
t = exp2(-CUDART_THIRD * log2(s)); /* initial approximation */
t = ((t*t) * (-s*t) + 1.0) * (CUDART_THIRD*t) + t;/* refine approximation */
#if defined(__APPLE__)
if (__signbitd(a))
#else /* __APPLE__ */
if (__signbit(a))
#endif /* __APPLE__ */
{
t = -t;
}
return t;
}
__func__(double sinpi(double a))
{
int n;
if (__isnan(a)) {
return a + a;
}
if (a == 0.0 || __isinf(a)) {
return sin (a);
}
if (a == floor(a)) {
return ((a / 1.0e308) / 1.0e308) / 1.0e308;
}
double twoa = a + a;
double rtwoa = round(twoa);
long long int l = (long long int)rtwoa;
n = (int)l;
a -= rtwoa * 0.5;
a = a * CUDART_PI;
if (n & 1) {
a = cos (a);
} else {
a = sin (a);
}
if (n & 2) {
a = -a;
}
return a;
}
__func__(double cospi(double a))
{
int n;
if (__isnan(a)) {
return a + a;
}
if (__isinf(a)) {
return cos (a);
}
if (fabs(a) > 9.0071992547409920e+015) {
a = 0.0;
}
double twoa = a + a;
double rtwoa = round(twoa);
long long int l = (long long int)rtwoa;
n = (int)l;
a -= rtwoa * 0.5;
a = a * CUDART_PI;
n++;
if (n & 1) {
a = cos (a);
} else {
a = sin (a);
}
if (n & 2) {
a = -a;
}
if (a == 0.0) {
a = fabs(a);
}
return a;
}
__func__(void sincospi(const double a, double *sptr, double *cptr))
{
*sptr = sinpi(a);
*cptr = cospi(a);
}
__func__(double erfinv(const double a))
{
double p, q, t, fa;
unsigned long long int l;
fa = fabs(a);
if (fa >= 1.0) {
l = 0xfff8000000000000ULL;
memcpy(&t, &l, sizeof(double)); /* INDEFINITE */
if (fa == 1.0) {
t = a * exp(1000.0); /* Infinity */
}
} else if (fa >= 0.9375) {
/* Based on: J.M. Blair, C.A. Edwards, J.H. Johnson: Rational Chebyshev
Approximations for the Inverse of the Error Function. Mathematics of
Computation, Vol. 30, No. 136 (Oct. 1976), pp. 827-830. Table 59
*/
t = log1p(-fa);
t = 1.0 / sqrt(-t);
p = 2.7834010353747001060e-3;
p = p * t + 8.6030097526280260580e-1;
p = p * t + 2.1371214997265515515e+0;
p = p * t + 3.1598519601132090206e+0;
p = p * t + 3.5780402569085996758e+0;
p = p * t + 1.5335297523989890804e+0;
p = p * t + 3.4839207139657522572e-1;
p = p * t + 5.3644861147153648366e-2;
p = p * t + 4.3836709877126095665e-3;
p = p * t + 1.3858518113496718808e-4;
p = p * t + 1.1738352509991666680e-6;
q = t + 2.2859981272422905412e+0;
q = q * t + 4.3859045256449554654e+0;
q = q * t + 4.6632960348736635331e+0;
q = q * t + 3.9846608184671757296e+0;
q = q * t + 1.6068377709719017609e+0;
q = q * t + 3.5609087305900265560e-1;
q = q * t + 5.3963550303200816744e-2;
q = q * t + 4.3873424022706935023e-3;
q = q * t + 1.3858762165532246059e-4;
q = q * t + 1.1738313872397777529e-6;
t = p / (q * t);
if (a < 0.0) t = -t;
} else if (fa >= 0.75) {
/* Based on: J.M. Blair, C.A. Edwards, J.H. Johnson: Rational Chebyshev
Approximations for the Inverse of the Error Function. Mathematics of
Computation, Vol. 30, No. 136 (Oct. 1976), pp. 827-830. Table 39
*/
t = a * a - .87890625;
p = .21489185007307062000e+0;
p = p * t - .64200071507209448655e+1;
p = p * t + .29631331505876308123e+2;
p = p * t - .47644367129787181803e+2;
p = p * t + .34810057749357500873e+2;
p = p * t - .12954198980646771502e+2;
p = p * t + .25349389220714893917e+1;
p = p * t - .24758242362823355486e+0;
p = p * t + .94897362808681080020e-2;
q = t - .12831383833953226499e+2;
q = q * t + .41409991778428888716e+2;
q = q * t - .53715373448862143349e+2;
q = q * t + .33880176779595142685e+2;
q = q * t - .11315360624238054876e+2;
q = q * t + .20369295047216351160e+1;
q = q * t - .18611650627372178511e+0;
q = q * t + .67544512778850945940e-2;
p = p / q;
t = a * p;
} else {
/* Based on: J.M. Blair, C.A. Edwards, J.H. Johnson: Rational Chebyshev
Approximations for the Inverse of the Error Function. Mathematics of
Computation, Vol. 30, No. 136 (Oct. 1976), pp. 827-830. Table 18
*/
t = a * a - .5625;
p = - .23886240104308755900e+2;
p = p * t + .45560204272689128170e+3;
p = p * t - .22977467176607144887e+4;
p = p * t + .46631433533434331287e+4;
p = p * t - .43799652308386926161e+4;
p = p * t + .19007153590528134753e+4;
p = p * t - .30786872642313695280e+3;
q = t - .83288327901936570000e+2;
q = q * t + .92741319160935318800e+3;
q = q * t - .35088976383877264098e+4;
q = q * t + .59039348134843665626e+4;
q = q * t - .48481635430048872102e+4;
q = q * t + .18997769186453057810e+4;
q = q * t - .28386514725366621129e+3;
p = p / q;
t = a * p;
}
return t;
}
__func__(double erfcinv(const double a))
{
double t;
unsigned long long int l;
if (__isnan(a)) {
return a + a;
}
if (a <= 0.0) {
l = 0xfff8000000000000ULL;
memcpy(&t, &l, sizeof(double)); /* INDEFINITE */
if (a == 0.0) {
t = (1.0 - a) * exp(1000.0); /* Infinity */
}
}
else if (a >= 0.0625) {
t = erfinv (1.0 - a);
}
else if (a >= 1e-100) {
/* Based on: J.M. Blair, C.A. Edwards, J.H. Johnson: Rational Chebyshev
Approximations for the Inverse of the Error Function. Mathematics of
Computation, Vol. 30, No. 136 (Oct. 1976), pp. 827-830. Table 59
*/
double p, q;
t = log(a);
t = 1.0 / sqrt(-t);
p = 2.7834010353747001060e-3;
p = p * t + 8.6030097526280260580e-1;
p = p * t + 2.1371214997265515515e+0;
p = p * t + 3.1598519601132090206e+0;
p = p * t + 3.5780402569085996758e+0;
p = p * t + 1.5335297523989890804e+0;
p = p * t + 3.4839207139657522572e-1;
p = p * t + 5.3644861147153648366e-2;
p = p * t + 4.3836709877126095665e-3;
p = p * t + 1.3858518113496718808e-4;
p = p * t + 1.1738352509991666680e-6;
q = t + 2.2859981272422905412e+0;
q = q * t + 4.3859045256449554654e+0;
q = q * t + 4.6632960348736635331e+0;
q = q * t + 3.9846608184671757296e+0;
q = q * t + 1.6068377709719017609e+0;
q = q * t + 3.5609087305900265560e-1;
q = q * t + 5.3963550303200816744e-2;
q = q * t + 4.3873424022706935023e-3;
q = q * t + 1.3858762165532246059e-4;
q = q * t + 1.1738313872397777529e-6;
t = p / (q * t);
}
else {
/* Based on: J.M. Blair, C.A. Edwards, J.H. Johnson: Rational Chebyshev
Approximations for the Inverse of the Error Function. Mathematics of
Computation, Vol. 30, No. 136 (Oct. 1976), pp. 827-830. Table 82
*/
double p, q;
t = log(a);
t = 1.0 / sqrt(-t);
p = 6.9952990607058154858e-1;
p = p * t + 1.9507620287580568829e+0;
p = p * t + 8.2810030904462690216e-1;
p = p * t + 1.1279046353630280005e-1;
p = p * t + 6.0537914739162189689e-3;
p = p * t + 1.3714329569665128933e-4;
p = p * t + 1.2964481560643197452e-6;
p = p * t + 4.6156006321345332510e-9;
p = p * t + 4.5344689563209398450e-12;
q = t + 1.5771922386662040546e+0;
q = q * t + 2.1238242087454993542e+0;
q = q * t + 8.4001814918178042919e-1;
q = q * t + 1.1311889334355782065e-1;
q = q * t + 6.0574830550097140404e-3;
q = q * t + 1.3715891988350205065e-4;
q = q * t + 1.2964671850944981713e-6;
q = q * t + 4.6156017600933592558e-9;
q = q * t + 4.5344687377088206783e-12;
t = p / (q * t);
}
return t;
}
__func__(double normcdfinv(const double a))
{
return -1.4142135623730951 * erfcinv(a + a);
}
__func__(double normcdf(double a))
{
double ah, al, t1, t2, u1, u2, v1, v2, z;
if (fabs (a) > 38.5) a = copysign (38.5, a);
ah = a * 134217729.0;
u1 = (a - ah) + ah;
u2 = a - u1;
v1 = -7.0710678398609161e-01;
v2 = 2.7995440410322203e-09;
t1 = a * -CUDART_SQRT_HALF_HI;
t2 = (((u1 * v1 - t1) + u1 * v2) + u2 * v1) + u2 * v2;
t2 = (a * -CUDART_SQRT_HALF_LO) + t2;
ah = t1 + t2;
z = erfc (ah);
if (a < -1.0) {
al = (t1 - ah) + t2;
t1 = -2.0 * ah * z;
z = t1 * al + z;
}
return 0.5 * z;
}
__func__(double erfcx(const double a))
{
double x, t1, t2, t3;
if (__isnan(a)) {
return a + a;
}
x = fabs(a);
if (x < 32.0) {
/*
* This implementation of erfcx() is based on the algorithm in: M. M.
* Shepherd and J. G. Laframboise, "Chebyshev Approximation of (1 + 2x)
* exp(x^2)erfc x in 0 <= x < INF", Mathematics of Computation, Vol.
* 36, No. 153, January 1981, pp. 249-253. For the core approximation,
* the input domain [0,INF] is transformed via (x-k) / (x+k) where k is
* a precision-dependent constant. Here, we choose k = 4.0, so the input
* domain [0, 27.3] is transformed into the core approximation domain
* [-1, 0.744409].
*/
/*
// Compute (1+2*x)*exp(x*x)*erfc(x)
*/
/* t2 = (x-4.0)/(x+4.0), transforming [0,INF] to [-1,+1] */
t1 = x - 4.0;
t2 = x + 4.0;
t2 = t1 / t2;
/* approximate on [-1, 0.744409] */
t1 = - 3.5602694826817400E-010;
t1 = t1 * t2 - 9.7239122591447274E-009;
t1 = t1 * t2 - 8.9350224851649119E-009;
t1 = t1 * t2 + 1.0404430921625484E-007;
t1 = t1 * t2 + 5.8806698585341259E-008;
t1 = t1 * t2 - 8.2147414929116908E-007;
t1 = t1 * t2 + 3.0956409853306241E-007;
t1 = t1 * t2 + 5.7087871844325649E-006;
t1 = t1 * t2 - 1.1231787437600085E-005;
t1 = t1 * t2 - 2.4399558857200190E-005;
t1 = t1 * t2 + 1.5062557169571788E-004;
t1 = t1 * t2 - 1.9925637684786154E-004;
t1 = t1 * t2 - 7.5777429182785833E-004;
t1 = t1 * t2 + 5.0319698792599572E-003;
t1 = t1 * t2 - 1.6197733895953217E-002;
t1 = t1 * t2 + 3.7167515553018733E-002;
t1 = t1 * t2 - 6.6330365827532434E-002;
t1 = t1 * t2 + 9.3732834997115544E-002;
t1 = t1 * t2 - 1.0103906603555676E-001;
t1 = t1 * t2 + 6.8097054254735140E-002;
t1 = t1 * t2 + 1.5379652102605428E-002;
t1 = t1 * t2 - 1.3962111684056291E-001;
t1 = t1 * t2 + 1.2329951186255526E+000;
/*
// Note: (1+2*x)*exp(x*x)*erfc(x) / (1+2*x) = exp(x*x)*erfc(x)
*/
t2 = 2.0 * x + 1.0;
t1 = t1 / t2;
} else {
/* asymptotic expansion for large aguments */
t2 = 1.0 / x;
t3 = t2 * t2;
t1 = -29.53125;
t1 = t1 * t3 + 6.5625;
t1 = t1 * t3 - 1.875;
t1 = t1 * t3 + 0.75;
t1 = t1 * t3 - 0.5;
t1 = t1 * t3 + 1.0;
t2 = t2 * 5.6418958354775628e-001;
t1 = t1 * t2;
}
if (a < 0.0) {
/*
// Note: erfcx(x) = 2*exp(x^2) - erfcx(|x|)
*/
t2 = (static_cast<int>(x * 16.0)) * 0.0625;
t3 = (x - t2) * (x + t2);
t3 = exp(t2 * t2) * exp(t3);
t3 = t3 + t3;
t1 = t3 - t1;
}
return t1;
}
__func__(float rsqrtf(const float a))
{
return static_cast<float>(rsqrt(static_cast<double>(a)));
}
__func__(float rcbrtf(const float a))
{
return static_cast<float>(rcbrt(static_cast<double>(a)));
}
__func__(float sinpif(const float a))
{
return static_cast<float>(sinpi(static_cast<double>(a)));
}
__func__(float cospif(const float a))
{
return static_cast<float>(cospi(static_cast<double>(a)));
}
__func__(void sincospif(const float a, float *sptr, float *cptr))
{
double s, c;
sincospi(static_cast<double>(a), &s, &c);
*sptr = static_cast<float>(s);
*cptr = static_cast<float>(c);
}
__func__(float erfinvf(const float a))
{
return static_cast<float>(erfinv(static_cast<double>(a)));
}
__func__(float erfcinvf(const float a))
{
return static_cast<float>(erfcinv(static_cast<double>(a)));
}
__func__(float normcdfinvf(const float a))
{
return static_cast<float>(normcdfinv(static_cast<double>(a)));
}
__func__(float normcdff(const float a))
{
return static_cast<float>(normcdf(static_cast<double>(a)));
}
__func__(float erfcxf(const float a))
{
return static_cast<float>(erfcx(static_cast<double>(a)));
}
#if defined(_WIN32)
#pragma warning (pop)
#endif /* _WIN32 */
#endif /* !__CUDACC__ */
#endif /* !__MATH_FUNCTIONS_HPP__ */
#if defined(__UNDEF_CUDA_INCLUDE_COMPILER_INTERNAL_HEADERS_MATH_FUNCTIONS_HPP__)
#undef __CUDA_INCLUDE_COMPILER_INTERNAL_HEADERS__
#undef __UNDEF_CUDA_INCLUDE_COMPILER_INTERNAL_HEADERS_MATH_FUNCTIONS_HPP__
#endif