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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/device_functions.h 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/device_functions.h 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_DEVICE_FUNCTIONS_H__
#endif

#if !defined(__DEVICE_FUNCTIONS_H__)
#define __DEVICE_FUNCTIONS_H__

/*******************************************************************************

*                                                                              *

*                                                                              *

*                                                                              *

*******************************************************************************/

#if defined(__cplusplus) && defined(__CUDACC__)

#if defined(__CUDACC_RTC__)
#define __DEVICE_FUNCTIONS_DECL__ __device__ __cudart_builtin__
#define __DEVICE_FUNCTIONS_STATIC_DECL__ __device__ __cudart_builtin__
#define __DEVICE_HOST_FUNCTIONS_STATIC_DECL__ __device__ __host__ __cudart_builtin__
#else
#define __DEVICE_FUNCTIONS_DECL__ __device__ __cudart_builtin__
#define __DEVICE_FUNCTIONS_STATIC_DECL__ static __inline__ __device__ __cudart_builtin__
#define __DEVICE_HOST_FUNCTIONS_STATIC_DECL__ static __inline__ __device__ __host__ __cudart_builtin__
#endif /* __CUDACC_RTC__ */

#include "builtin_types.h"
#include "device_types.h"
#include "host_defines.h"


//NOTE: For NVRTC, these declarations have been moved into the compiler (to reduce compile time)
#define EXCLUDE_FROM_RTC

/*******************************************************************************

*                                                                              *

*                                                                              *

*                                                                              *

*******************************************************************************/

extern "C"
{
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Calculate the most significant 32 bits of the product of the two 32-bit integers.

 *

 * Calculate the most significant 32 bits of the 64-bit product \p x * \p y, where \p x and \p y

 * are 32-bit integers.

 *

 * \return Returns the most significant 32 bits of the product \p x * \p y.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ int                    __mulhi(int x, int y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Calculate the most significant 32 bits of the product of the two 32-bit unsigned integers.

 *

 * Calculate the most significant 32 bits of the 64-bit product \p x * \p y, where \p x and \p y

 * are 32-bit unsigned integers. 

 *

 * \return Returns the most significant 32 bits of the product \p x * \p y.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __umulhi(unsigned int x, unsigned int y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Calculate the most significant 64 bits of the product of the two 64-bit integers.

 *

 * Calculate the most significant 64 bits of the 128-bit product \p x * \p y, where \p x and \p y

 * are 64-bit integers. 

 *

 * \return Returns the most significant 64 bits of the product \p x * \p y.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ long long int          __mul64hi(long long int x, long long int y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Calculate the most significant 64 bits of the product of the two 64 unsigned bit integers.

 *

 * Calculate the most significant 64 bits of the 128-bit product \p x * \p y, where \p x and \p y

 * are 64-bit unsigned integers. 

 *

 * \return Returns the most significant 64 bits of the product \p x * \p y.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned long long int __umul64hi(unsigned long long int x, unsigned long long int y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Reinterpret bits in an integer as a float.

 *

 * Reinterpret the bits in the signed integer value \p x as a single-precision

 * floating-point value.

 * \return Returns reinterpreted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __int_as_float(int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Reinterpret bits in a float as a signed integer.

 *

 * Reinterpret the bits in the single-precision floating-point value \p x

 * as a signed integer.

 * \return Returns reinterpreted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ int                    __float_as_int(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Reinterpret bits in an unsigned integer as a float.

 *

 * Reinterpret the bits in the unsigned integer value \p x as a single-precision

 * floating-point value.

 * \return Returns reinterpreted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __uint_as_float(unsigned int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Reinterpret bits in a float as a unsigned integer.

 *

 * Reinterpret the bits in the single-precision floating-point value \p x

 * as a unsigned integer.

 * \return Returns reinterpreted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __float_as_uint(float x);
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ void                   __syncthreads(void);
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ void                   __prof_trigger(int);
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ void                   __threadfence(void);
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ void                   __threadfence_block(void);
__DEVICE_FUNCTIONS_DECL__ 
#if defined(__GNUC__) || defined(__CUDACC_RTC__)
__attribute__((__noreturn__))
#elif defined(_MSC_VER)
__declspec(noreturn)
#endif  /* defined(__GNUC__) || defined(__CUDACC_RTC__) */
__device_builtin__ void                   __trap(void);
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ void                   __brkpt();
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Clamp the input argument to [+0.0, 1.0].

 *

 * Clamp the input argument \p x to be within the interval [+0.0, 1.0].

 * \return 

 * - __saturatef(\p x) returns 0 if \p x < 0.

 * - __saturatef(\p x) returns 1 if \p x > 1.

 * - __saturatef(\p x) returns \p x if 

 * \latexonly $0 \le x \le 1$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mn>0</m:mn>

 *   <m:mo>&#x2264;<!-- &Le --></m:mo>

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x2264;<!-- &Le --></m:mo>

 *   <m:mn>1</m:mn>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 * - __saturatef(NaN) returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __saturatef(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Calculate 

 * \latexonly $|x - y| + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mrow class="MJX-TeXAtom-ORD">

 *     <m:mo stretchy="false">|</m:mo>

 *   </m:mrow>

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x2212;<!-- &Minus --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mrow class="MJX-TeXAtom-ORD">

 *     <m:mo stretchy="false">|</m:mo>

 *   </m:mrow>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , the sum of absolute difference.

 *

 * Calculate 

 * \latexonly $|x - y| + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mrow class="MJX-TeXAtom-ORD">

 *     <m:mo stretchy="false">|</m:mo>

 *   </m:mrow>

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x2212;<!-- &Minus --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mrow class="MJX-TeXAtom-ORD">

 *     <m:mo stretchy="false">|</m:mo>

 *   </m:mrow>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , the 32-bit sum of the third argument \p z plus and the absolute 

 * value of the difference between the first argument, \p x, and second 

 * argument, \p y.

 * 

 * Inputs \p x and \p y are signed 32-bit integers, input \p z is 

 * a 32-bit unsigned integer.

 *

 * \return Returns 

 * \latexonly $|x - y| + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mrow class="MJX-TeXAtom-ORD">

 *     <m:mo stretchy="false">|</m:mo>

 *   </m:mrow>

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x2212;<!-- &Minus --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mrow class="MJX-TeXAtom-ORD">

 *     <m:mo stretchy="false">|</m:mo>

 *   </m:mrow>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __sad(int x, int y, unsigned int z);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Calculate 

 * \latexonly $|x - y| + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mrow class="MJX-TeXAtom-ORD">

 *     <m:mo stretchy="false">|</m:mo>

 *   </m:mrow>

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x2212;<!-- &Minus --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mrow class="MJX-TeXAtom-ORD">

 *     <m:mo stretchy="false">|</m:mo>

 *   </m:mrow>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , the sum of absolute difference.

 *

 * Calculate 

 * \latexonly $|x - y| + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mrow class="MJX-TeXAtom-ORD">

 *     <m:mo stretchy="false">|</m:mo>

 *   </m:mrow>

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x2212;<!-- &Minus --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mrow class="MJX-TeXAtom-ORD">

 *     <m:mo stretchy="false">|</m:mo>

 *   </m:mrow>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , the 32-bit sum of the third argument \p z plus and the absolute 

 * value of the difference between the first argument, \p x, and second 

 * argument, \p y.

 * 

 * Inputs \p x, \p y, and \p z are unsigned 32-bit integers.

 * 

 * \return Returns 

 * \latexonly $|x - y| + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mrow class="MJX-TeXAtom-ORD">

 *     <m:mo stretchy="false">|</m:mo>

 *   </m:mrow>

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x2212;<!-- &Minus --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mrow class="MJX-TeXAtom-ORD">

 *     <m:mo stretchy="false">|</m:mo>

 *   </m:mrow>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __usad(unsigned int x, unsigned int y, unsigned int z);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Calculate the least significant 32 bits of the product of the least significant 24 bits of two integers.

 *

 * Calculate the least significant 32 bits of the product of the least significant 24 bits of \p x and \p y.

 * The high order 8 bits of \p x and \p y are ignored.

 *

 * \return Returns the least significant 32 bits of the product \p x * \p y.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ int                    __mul24(int x, int y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Calculate the least significant 32 bits of the product of the least significant 24 bits of two unsigned integers.

 *

 * Calculate the least significant 32 bits of the product of the least significant 24 bits of \p x and \p y.

 * The high order 8 bits of  \p x and  \p y are ignored. 

 *

 * \return Returns the least significant 32 bits of the product \p x * \p y.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __umul24(unsigned int x, unsigned int y);
/**

 * \ingroup CUDA_MATH_SINGLE

 * \brief Divide two floating-point values.

 *

 * Compute \p x divided by \p y.  If <tt>--use_fast_math</tt> is specified,

 * use ::__fdividef() for higher performance, otherwise use normal division.

 *

 * \return Returns \p x / \p y.

 *

 * \note_accuracy_single

 * \note_fastmath

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  fdividef(float x, float y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Calculate the fast approximate division of the input arguments.

 *

 * Calculate the fast approximate division of \p x by \p y.

 *

 * \return Returns \p x / \p y.

 * - __fdividef(

 * \latexonly $\infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , \p y) returns NaN for 

 * \latexonly $2^{126} < |y| < 2^{128}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msup>

 *     <m:mn>2</m:mn>

 *     <m:mrow class="MJX-TeXAtom-ORD">

 *       <m:mn>126</m:mn>

 *     </m:mrow>

 *   </m:msup>

 *   <m:mo>&lt;</m:mo>

 *   <m:mi>|y|</m:mi>

 *   <m:mo>&lt;</m:mo>

 *   <m:msup>

 *     <m:mn>2</m:mn>

 *     <m:mrow class="MJX-TeXAtom-ORD">

 *       <m:mn>128</m:mn>

 *     </m:mrow>

 *   </m:msup>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 * - __fdividef(\p x, \p y) returns 0 for 

 * \latexonly $2^{126} < |y| < 2^{128}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msup>

 *     <m:mn>2</m:mn>

 *     <m:mrow class="MJX-TeXAtom-ORD">

 *       <m:mn>126</m:mn>

 *     </m:mrow>

 *   </m:msup>

 *   <m:mo>&lt;</m:mo>

 *   <m:mi>|y|</m:mi>

 *   <m:mo>&lt;</m:mo>

 *   <m:msup>

 *     <m:mn>2</m:mn>

 *     <m:mrow class="MJX-TeXAtom-ORD">

 *       <m:mn>128</m:mn>

 *     </m:mrow>

 *   </m:msup>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  and finite

 * \latexonly $x$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single_intrinsic

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fdividef(float x, float y);
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ double                 fdivide(double x, double y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Calculate the fast approximate sine of the input argument.

 *

 * Calculate the fast approximate sine of the input argument \p x, measured in radians.

 *

 * \return Returns the approximate sine of \p x.

 *

 * \note_accuracy_single_intrinsic

 * \note Output in the denormal range is flushed to sign preserving 0.0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ __cudart_builtin__ float                  __sinf(float x) __THROW;
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Calculate the fast approximate cosine of the input argument.

 *

 * Calculate the fast approximate cosine of the input argument \p x, measured in radians.

 *

 * \return Returns the approximate cosine of \p x.

 *

 * \note_accuracy_single_intrinsic

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ __cudart_builtin__ float                  __cosf(float x) __THROW;
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Calculate the fast approximate tangent of the input argument.

 *

 * Calculate the fast approximate tangent of the input argument \p x, measured in radians.

 *

 * \return Returns the approximate tangent of \p x.

 *

 * \note_accuracy_single_intrinsic

 * \note The result is computed as the fast divide of ::__sinf()

 * by ::__cosf(). Denormal output is flushed to sign-preserving 0.0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ __cudart_builtin__ float                  __tanf(float x) __THROW;
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Calculate the fast approximate of sine and cosine of the first input argument.

 *

 * Calculate the fast approximate of sine and cosine of the first input argument \p x (measured

 * in radians). The results for sine and cosine are written into the second 

 * argument, \p sptr, and, respectively, third argument, \p cptr.

 *

 * \return

 * - none

 *

 * \note_accuracy_single_intrinsic

 * \note Denorm input/output is flushed to sign preserving 0.0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ __cudart_builtin__ void                   __sincosf(float x, float *sptr, float *cptr) __THROW;
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Calculate the fast approximate base 

 * \latexonly $e$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>e</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  exponential of the input argument.

 *

 * Calculate the fast approximate base 

 * \latexonly $e$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>e</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  exponential of the input argument \p x, 

 * \latexonly $e^x$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msup>

 *     <m:mi>e</m:mi>

 *     <m:mi>x</m:mi>

 *   </m:msup>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \return Returns an approximation to 

 * \latexonly $e^x$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msup>

 *     <m:mi>e</m:mi>

 *     <m:mi>x</m:mi>

 *   </m:msup>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single_intrinsic

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ __cudart_builtin__ float                  __expf(float x) __THROW;
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Calculate the fast approximate base 10 exponential of the input argument.

 *

 * Calculate the fast approximate base 10 exponential of the input argument \p x, 

 * \latexonly $10^x$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msup>

 *     <m:mn>10</m:mn>

 *     <m:mi>x</m:mi>

 *   </m:msup>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \return Returns an approximation to 

 * \latexonly $10^x$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msup>

 *     <m:mn>10</m:mn>

 *     <m:mi>x</m:mi>

 *   </m:msup>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single_intrinsic

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ __cudart_builtin__ float                  __exp10f(float x) __THROW;
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Calculate the fast approximate base 2 logarithm of the input argument.

 *

 * Calculate the fast approximate base 2 logarithm of the input argument \p x.

 *

 * \return Returns an approximation to 

 * \latexonly $\log_2(x)$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msub>

 *     <m:mi>log</m:mi>

 *     <m:mn>2</m:mn>

 *   </m:msub>

 *   <m:mo>&#x2061;<!-- &functionAplication --></m:mo>

 *   <m:mo stretchy="false">(</m:mo>

 *   <m:mi>x</m:mi>

 *   <m:mo stretchy="false">)</m:mo>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single_intrinsic

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ __cudart_builtin__ float                  __log2f(float x) __THROW;
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Calculate the fast approximate base 10 logarithm of the input argument.

 *

 * Calculate the fast approximate base 10 logarithm of the input argument \p x.

 *

 * \return Returns an approximation to 

 * \latexonly $\log_{10}(x)$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msub>

 *     <m:mi>log</m:mi>

 *     <m:mrow class="MJX-TeXAtom-ORD">

 *       <m:mn>10</m:mn>

 *     </m:mrow>

 *   </m:msub>

 *   <m:mo>&#x2061;<!-- &functionAplication --></m:mo>

 *   <m:mo stretchy="false">(</m:mo>

 *   <m:mi>x</m:mi>

 *   <m:mo stretchy="false">)</m:mo>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single_intrinsic

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ __cudart_builtin__ float                  __log10f(float x) __THROW;
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Calculate the fast approximate base 

 * \latexonly $e$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>e</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  logarithm of the input argument.

 *

 * Calculate the fast approximate base 

 * \latexonly $e$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>e</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  logarithm of the input argument \p x.

 *

 * \return Returns an approximation to 

 * \latexonly $\log_e(x)$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msub>

 *     <m:mi>log</m:mi>

 *     <m:mi>e</m:mi>

 *   </m:msub>

 *   <m:mo>&#x2061;<!-- &functionAplication --></m:mo>

 *   <m:mo stretchy="false">(</m:mo>

 *   <m:mi>x</m:mi>

 *   <m:mo stretchy="false">)</m:mo>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single_intrinsic

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ __cudart_builtin__ float                  __logf(float x) __THROW;
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Calculate the fast approximate of 

 * \latexonly $x^y$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msup>

 *     <m:mi>x</m:mi>

 *     <m:mi>y</m:mi>

 *   </m:msup>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * Calculate the fast approximate of \p x, the first input argument, 

 * raised to the power of \p y, the second input argument, 

 * \latexonly $x^y$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msup>

 *     <m:mi>x</m:mi>

 *     <m:mi>y</m:mi>

 *   </m:msup>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \return Returns an approximation to 

 * \latexonly $x^y$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msup>

 *     <m:mi>x</m:mi>

 *     <m:mi>y</m:mi>

 *   </m:msup>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single_intrinsic

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ __cudart_builtin__ float                  __powf(float x, float y) __THROW;
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a float to a signed integer in round-to-nearest-even mode.

 *

 * Convert the single-precision floating-point value \p x to a signed integer

 * in round-to-nearest-even mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ int                    __float2int_rn(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a float to a signed integer in round-towards-zero mode.

 *

 * Convert the single-precision floating-point value \p x to a signed integer

 * in round-towards-zero mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ int                    __float2int_rz(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a float to a signed integer in round-up mode.

 *

 * Convert the single-precision floating-point value \p x to a signed integer

 * in round-up (to positive infinity) mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ int                    __float2int_ru(float);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a float to a signed integer in round-down mode.

 *

 * Convert the single-precision floating-point value \p x to a signed integer

 * in round-down (to negative infinity) mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ int                    __float2int_rd(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a float to an unsigned integer in round-to-nearest-even mode.

 *

 * Convert the single-precision floating-point value \p x to an unsigned integer

 * in round-to-nearest-even mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __float2uint_rn(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a float to an unsigned integer in round-towards-zero mode.

 *

 * Convert the single-precision floating-point value \p x to an unsigned integer

 * in round-towards-zero mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __float2uint_rz(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a float to an unsigned integer in round-up mode.

 *

 * Convert the single-precision floating-point value \p x to an unsigned integer

 * in round-up (to positive infinity) mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __float2uint_ru(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a float to an unsigned integer in round-down mode.

 *

 * Convert the single-precision floating-point value \p x to an unsigned integer

 * in round-down (to negative infinity) mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __float2uint_rd(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a signed integer to a float in round-to-nearest-even mode.

 *

 * Convert the signed integer value \p x to a single-precision floating-point value

 * in round-to-nearest-even mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __int2float_rn(int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a signed integer to a float in round-towards-zero mode.

 *

 * Convert the signed integer value \p x to a single-precision floating-point value

 * in round-towards-zero mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __int2float_rz(int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a signed integer to a float in round-up mode.

 *

 * Convert the signed integer value \p x to a single-precision floating-point value

 * in round-up (to positive infinity) mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __int2float_ru(int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a signed integer to a float in round-down mode.

 *

 * Convert the signed integer value \p x to a single-precision floating-point value

 * in round-down (to negative infinity) mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __int2float_rd(int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert an unsigned integer to a float in round-to-nearest-even mode.

 *

 * Convert the unsigned integer value \p x to a single-precision floating-point value

 * in round-to-nearest-even mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __uint2float_rn(unsigned int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert an unsigned integer to a float in round-towards-zero mode.

 *

 * Convert the unsigned integer value \p x to a single-precision floating-point value

 * in round-towards-zero mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __uint2float_rz(unsigned int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert an unsigned integer to a float in round-up mode.

 *

 * Convert the unsigned integer value \p x to a single-precision floating-point value

 * in round-up (to positive infinity) mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __uint2float_ru(unsigned int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert an unsigned integer to a float in round-down mode.

 *

 * Convert the unsigned integer value \p x to a single-precision floating-point value

 * in round-down (to negative infinity) mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __uint2float_rd(unsigned int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a float to a signed 64-bit integer in round-to-nearest-even mode.

 *

 * Convert the single-precision floating-point value \p x to a signed 64-bit integer

 * in round-to-nearest-even mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ long long int          __float2ll_rn(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a float to a signed 64-bit integer in round-towards-zero mode.

 *

 * Convert the single-precision floating-point value \p x to a signed 64-bit integer

 * in round-towards-zero mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ long long int          __float2ll_rz(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a float to a signed 64-bit integer in round-up mode.

 *

 * Convert the single-precision floating-point value \p x to a signed 64-bit integer

 * in round-up (to positive infinity) mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ long long int          __float2ll_ru(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a float to a signed 64-bit integer in round-down mode.

 *

 * Convert the single-precision floating-point value \p x to a signed 64-bit integer

 * in round-down (to negative infinity) mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ long long int          __float2ll_rd(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a float to an unsigned 64-bit integer in round-to-nearest-even mode.

 *

 * Convert the single-precision floating-point value \p x to an unsigned 64-bit integer

 * in round-to-nearest-even mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned long long int __float2ull_rn(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a float to an unsigned 64-bit integer in round-towards-zero mode.

 *

 * Convert the single-precision floating-point value \p x to an unsigned 64-bit integer

 * in round-towards-zero mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned long long int __float2ull_rz(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a float to an unsigned 64-bit integer in round-up mode.

 *

 * Convert the single-precision floating-point value \p x to an unsigned 64-bit integer

 * in round-up (to positive infinity) mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned long long int __float2ull_ru(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a float to an unsigned 64-bit integer in round-down mode.

 *

 * Convert the single-precision floating-point value \p x to an unsigned 64-bit integer

 * in round-down (to negative infinity) mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned long long int __float2ull_rd(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a signed 64-bit integer to a float in round-to-nearest-even mode.

 *

 * Convert the signed 64-bit integer value \p x to a single-precision floating-point value

 * in round-to-nearest-even mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __ll2float_rn(long long int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a signed integer to a float in round-towards-zero mode.

 *

 * Convert the signed integer value \p x to a single-precision floating-point value

 * in round-towards-zero mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __ll2float_rz(long long int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a signed integer to a float in round-up mode.

 *

 * Convert the signed integer value \p x to a single-precision floating-point value

 * in round-up (to positive infinity) mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __ll2float_ru(long long int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a signed integer to a float in round-down mode.

 *

 * Convert the signed integer value \p x to a single-precision floating-point value

 * in round-down (to negative infinity) mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __ll2float_rd(long long int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert an unsigned integer to a float in round-to-nearest-even mode.

 *

 * Convert the unsigned integer value \p x to a single-precision floating-point value

 * in round-to-nearest-even mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __ull2float_rn(unsigned long long int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert an unsigned integer to a float in round-towards-zero mode.

 *

 * Convert the unsigned integer value \p x to a single-precision floating-point value

 * in round-towards-zero mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __ull2float_rz(unsigned long long int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert an unsigned integer to a float in round-up mode.

 *

 * Convert the unsigned integer value \p x to a single-precision floating-point value

 * in round-up (to positive infinity) mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __ull2float_ru(unsigned long long int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert an unsigned integer to a float in round-down mode.

 *

 * Convert the unsigned integer value \p x to a single-precision floating-point value

 * in round-down (to negative infinity) mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __ull2float_rd(unsigned long long int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Add two floating-point values in round-to-nearest-even mode.

 * 

 * Compute the sum of \p x and \p y in round-to-nearest-even rounding mode.

 *

 * \return Returns \p x + \p y.

 *

 * \note_accuracy_single

 * \note_nofma

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fadd_rn(float x, float y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Add two floating-point values in round-towards-zero mode.

 * 

 * Compute the sum of \p x and \p y in round-towards-zero mode.

 *

 * \return Returns \p x + \p y.

 *

 * \note_accuracy_single

 * \note_nofma

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fadd_rz(float x, float y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Add two floating-point values in round-up mode.

 * 

 * Compute the sum of \p x and \p y in round-up (to positive infinity) mode.

 *

 * \return Returns \p x + \p y.

 *

 * \note_accuracy_single

 * \note_nofma

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fadd_ru(float x, float y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Add two floating-point values in round-down mode.

 * 

 * Compute the sum of \p x and \p y in round-down (to negative infinity) mode.

 *

 * \return Returns \p x + \p y.

 *

 * \note_accuracy_single

 * \note_nofma

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fadd_rd(float x, float y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Subtract two floating-point values in round-to-nearest-even mode.

 * 

 * Compute the difference of \p x and \p y in round-to-nearest-even rounding mode.

 *

 * \return Returns \p x - \p y.

 *

 * \note_accuracy_single

 * \note_nofma

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fsub_rn(float x, float y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Subtract two floating-point values in round-towards-zero mode.

 * 

 * Compute the difference of \p x and \p y in round-towards-zero mode.

 *

 * \return Returns \p x - \p y.

 *

 * \note_accuracy_single

 * \note_nofma

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fsub_rz(float x, float y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Subtract two floating-point values in round-up mode.

 * 

 * Compute the difference of \p x and \p y in round-up (to positive infinity) mode.

 *

 * \return Returns \p x - \p y.

 *

 * \note_accuracy_single

 * \note_nofma

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fsub_ru(float x, float y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Subtract two floating-point values in round-down mode.

 * 

 * Compute the difference of \p x and \p y in round-down (to negative infinity) mode.

 *

 * \return Returns \p x - \p y.

 *

 * \note_accuracy_single

 * \note_nofma

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fsub_rd(float x, float y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Multiply two floating-point values in round-to-nearest-even mode.

 * 

 * Compute the product of \p x and \p y in round-to-nearest-even mode.

 *

 * \return Returns \p x * \p y.

 *

 * \note_accuracy_single

 * \note_nofma

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fmul_rn(float x, float y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Multiply two floating-point values in round-towards-zero mode.

 * 

 * Compute the product of \p x and \p y in round-towards-zero mode.

 *

 * \return Returns \p x * \p y.

 *

 * \note_accuracy_single

 * \note_nofma

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fmul_rz(float x, float y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Multiply two floating-point values in round-up mode.

 * 

 * Compute the product of \p x and \p y in round-up (to positive infinity) mode.

 *

 * \return Returns \p x * \p y.

 *

 * \note_accuracy_single

 * \note_nofma

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fmul_ru(float x, float y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Multiply two floating-point values in round-down mode.

 * 

 * Compute the product of \p x and \p y in round-down (to negative infinity) mode.

 *

 * \return Returns \p x * \p y.

 *

 * \note_accuracy_single

 * \note_nofma

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fmul_rd(float x, float y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Compute 

 * \latexonly $x \times y + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  as a single operation, in round-to-nearest-even mode.

 * 

 * Computes the value of 

 * \latexonly $x \times y + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  as a single ternary operation, rounding the

 * result once in round-to-nearest-even mode.

 *

 * \return Returns the rounded value of 

 * \latexonly $x \times y + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  as a single operation.

 * - fmaf(

 * \latexonly $\pm \infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x00B1;<!-- &PlusMinus --></m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , 

 * \latexonly $\pm 0$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x00B1;<!-- &PlusMinus --></m:mo>

 *   <m:mn>0</m:mn>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , \p z) returns NaN.

 * - fmaf(

 * \latexonly $\pm 0$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x00B1;<!-- &PlusMinus --></m:mo>

 *   <m:mn>0</m:mn>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , 

 * \latexonly $\pm \infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x00B1;<!-- &PlusMinus --></m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , \p z) returns NaN.

 * - fmaf(\p x, \p y, 

 * \latexonly $-\infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x2212;<!-- &Minus --></m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * ) returns NaN if 

 * \latexonly $x \times y$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  is an exact 

 * \latexonly $+\infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>+</m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 * - fmaf(\p x, \p y, 

 * \latexonly $+\infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>+</m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * ) returns NaN if 

 * \latexonly $x \times y$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  is an exact 

 * \latexonly $-\infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x2212;<!-- &Minus --></m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fmaf_rn(float x, float y, float z);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Compute 

 * \latexonly $x \times y + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  as a single operation, in round-towards-zero mode.

 * 

 * Computes the value of 

 * \latexonly $x \times y + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  as a single ternary operation, rounding the

 * result once in round-towards-zero mode.

 *

 * \return Returns the rounded value of 

 * \latexonly $x \times y + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  as a single operation.

 * - fmaf(

 * \latexonly $\pm \infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x00B1;<!-- &PlusMinus --></m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , 

 * \latexonly $\pm 0$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x00B1;<!-- &PlusMinus --></m:mo>

 *   <m:mn>0</m:mn>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , \p z) returns NaN.

 * - fmaf(

 * \latexonly $\pm 0$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x00B1;<!-- &PlusMinus --></m:mo>

 *   <m:mn>0</m:mn>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , 

 * \latexonly $\pm \infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x00B1;<!-- &PlusMinus --></m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , \p z) returns NaN.

 * - fmaf(\p x, \p y, 

 * \latexonly $-\infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x2212;<!-- &Minus --></m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * ) returns NaN if 

 * \latexonly $x \times y$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  is an exact 

 * \latexonly $+\infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>+</m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 * - fmaf(\p x, \p y, 

 * \latexonly $+\infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>+</m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * ) returns NaN if 

 * \latexonly $x \times y$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  is an exact 

 * \latexonly $-\infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x2212;<!-- &Minus --></m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fmaf_rz(float x, float y, float z);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Compute 

 * \latexonly $x \times y + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  as a single operation, in round-up mode.

 * 

 * Computes the value of 

 * \latexonly $x \times y + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  as a single ternary operation, rounding the

 * result once in round-up (to positive infinity) mode.

 *

 * \return Returns the rounded value of 

 * \latexonly $x \times y + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  as a single operation.

 * - fmaf(

 * \latexonly $\pm \infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x00B1;<!-- &PlusMinus --></m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , 

 * \latexonly $\pm 0$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x00B1;<!-- &PlusMinus --></m:mo>

 *   <m:mn>0</m:mn>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , \p z) returns NaN.

 * - fmaf(

 * \latexonly $\pm 0$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x00B1;<!-- &PlusMinus --></m:mo>

 *   <m:mn>0</m:mn>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , 

 * \latexonly $\pm \infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x00B1;<!-- &PlusMinus --></m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , \p z) returns NaN.

 * - fmaf(\p x, \p y, 

 * \latexonly $-\infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x2212;<!-- &Minus --></m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * ) returns NaN if 

 * \latexonly $x \times y$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  is an exact 

 * \latexonly $+\infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>+</m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 * - fmaf(\p x, \p y, 

 * \latexonly $+\infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>+</m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * ) returns NaN if 

 * \latexonly $x \times y$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  is an exact 

 * \latexonly $-\infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x2212;<!-- &Minus --></m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fmaf_ru(float x, float y, float z);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Compute 

 * \latexonly $x \times y + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  as a single operation, in round-down mode.

 * 

 * Computes the value of 

 * \latexonly $x \times y + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  as a single ternary operation, rounding the

 * result once in round-down (to negative infinity) mode.

 *

 * \return Returns the rounded value of 

 * \latexonly $x \times y + z$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 *   <m:mo>+</m:mo>

 *   <m:mi>z</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  as a single operation.

 * - fmaf(

 * \latexonly $\pm \infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x00B1;<!-- &PlusMinus --></m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , 

 * \latexonly $\pm 0$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x00B1;<!-- &PlusMinus --></m:mo>

 *   <m:mn>0</m:mn>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , \p z) returns NaN.

 * - fmaf(

 * \latexonly $\pm 0$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x00B1;<!-- &PlusMinus --></m:mo>

 *   <m:mn>0</m:mn>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , 

 * \latexonly $\pm \infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x00B1;<!-- &PlusMinus --></m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * , \p z) returns NaN.

 * - fmaf(\p x, \p y, 

 * \latexonly $-\infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x2212;<!-- &Minus --></m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * ) returns NaN if 

 * \latexonly $x \times y$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  is an exact 

 * \latexonly $+\infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>+</m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 * - fmaf(\p x, \p y, 

 * \latexonly $+\infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>+</m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 * ) returns NaN if 

 * \latexonly $x \times y$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mi>x</m:mi>

 *   <m:mo>&#x00D7;<!-- &Multiply --></m:mo>

 *   <m:mi>y</m:mi>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  is an exact 

 * \latexonly $-\infty$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mo>&#x2212;<!-- &Minus --></m:mo>

 *   <m:mi mathvariant="normal">&#x221E;<!-- &Infinity --></m:mi>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fmaf_rd(float x, float y, float z);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Compute 

 * \latexonly $\frac{1}{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mfrac>

 *     <m:mn>1</m:mn>

 *     <m:mi>x</m:mi>

 *   </m:mfrac>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  in round-to-nearest-even mode.

 * 

 * Compute the reciprocal of \p x in round-to-nearest-even mode.

 *

 * \return Returns 

 * \latexonly $\frac{1}{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mfrac>

 *     <m:mn>1</m:mn>

 *     <m:mi>x</m:mi>

 *   </m:mfrac>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __frcp_rn(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Compute 

 * \latexonly $\frac{1}{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mfrac>

 *     <m:mn>1</m:mn>

 *     <m:mi>x</m:mi>

 *   </m:mfrac>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  in round-towards-zero mode.

 * 

 * Compute the reciprocal of \p x in round-towards-zero mode.

 *

 * \return Returns 

 * \latexonly $\frac{1}{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mfrac>

 *     <m:mn>1</m:mn>

 *     <m:mi>x</m:mi>

 *   </m:mfrac>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __frcp_rz(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Compute 

 * \latexonly $\frac{1}{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mfrac>

 *     <m:mn>1</m:mn>

 *     <m:mi>x</m:mi>

 *   </m:mfrac>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  in round-up mode.

 * 

 * Compute the reciprocal of \p x in round-up (to positive infinity) mode.

 *

 * \return Returns 

 * \latexonly $\frac{1}{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mfrac>

 *     <m:mn>1</m:mn>

 *     <m:mi>x</m:mi>

 *   </m:mfrac>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __frcp_ru(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Compute 

 * \latexonly $\frac{1}{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mfrac>

 *     <m:mn>1</m:mn>

 *     <m:mi>x</m:mi>

 *   </m:mfrac>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  in round-down mode.

 * 

 * Compute the reciprocal of \p x in round-down (to negative infinity) mode.

 *

 * \return Returns 

 * \latexonly $\frac{1}{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mfrac>

 *     <m:mn>1</m:mn>

 *     <m:mi>x</m:mi>

 *   </m:mfrac>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __frcp_rd(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Compute 

 * \latexonly $\sqrt{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msqrt>

 *     <m:mi>x</m:mi>

 *   </m:msqrt>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  in round-to-nearest-even mode.

 * 

 * Compute the square root of \p x in round-to-nearest-even mode.

 *

 * \return Returns 

 * \latexonly $\sqrt{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msqrt>

 *     <m:mi>x</m:mi>

 *   </m:msqrt>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fsqrt_rn(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Compute 

 * \latexonly $\sqrt{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msqrt>

 *     <m:mi>x</m:mi>

 *   </m:msqrt>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  in round-towards-zero mode.

 * 

 * Compute the square root of \p x in round-towards-zero mode.

 *

 * \return Returns 

 * \latexonly $\sqrt{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msqrt>

 *     <m:mi>x</m:mi>

 *   </m:msqrt>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fsqrt_rz(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Compute 

 * \latexonly $\sqrt{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msqrt>

 *     <m:mi>x</m:mi>

 *   </m:msqrt>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  in round-up mode.

 * 

 * Compute the square root of \p x in round-up (to positive infinity) mode.

 *

 * \return Returns 

 * \latexonly $\sqrt{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msqrt>

 *     <m:mi>x</m:mi>

 *   </m:msqrt>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fsqrt_ru(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Compute 

 * \latexonly $\sqrt{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msqrt>

 *     <m:mi>x</m:mi>

 *   </m:msqrt>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  in round-down mode.

 * 

 * Compute the square root of \p x in round-down (to negative infinity) mode.

 *

 * \return Returns 

 * \latexonly $\sqrt{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:msqrt>

 *     <m:mi>x</m:mi>

 *   </m:msqrt>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fsqrt_rd(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Compute

 * \latexonly $1/\sqrt{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mn>1</m:mn>

 *   <m:mrow class="MJX-TeXAtom-ORD">

 *     <m:mo>/</m:mo>

 *   </m:mrow>

 *   <m:msqrt>

 *     <m:mi>x</m:mi>

 *   </m:msqrt>

 * </m:math>

 * </d4p_MathML>

 * \endxmlonly

 *  in round-to-nearest-even mode.

 * 

 * Compute the reciprocal square root of \p x in round-to-nearest-even mode.

 *

 * \return Returns

 * \latexonly $1/\sqrt{x}$ \endlatexonly

 * \xmlonly

 * <d4p_MathML outputclass="xmlonly">

 * <m:math xmlns:m="http://www.w3.org/1998/Math/MathML">

 *   <m:mn>1</m:mn>

 *   <m:mrow class="MJX-TeXAtom-ORD">

 *     <m:mo>/</m:mo>

 *   </m:mrow>

 *   <m:msqrt>

 *     <m:mi>x</m:mi>

 *   </m:msqrt>

 * </m:math>

 * </d4p_MathML>\endxmlonly.

 *

 * \note_accuracy_single

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __frsqrt_rn(float x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Divide two floating-point values in round-to-nearest-even mode.

 *

 * Divide two floating-point values \p x by \p y in round-to-nearest-even mode.

 *

 * \return Returns \p x / \p y.

 *

 * \note_accuracy_single

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fdiv_rn(float x, float y);
/**      

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Divide two floating-point values in round-towards-zero mode.

 *

 * Divide two floating-point values \p x by \p y in round-towards-zero mode.

 *

 * \return Returns \p x / \p y.

 *

 * \note_accuracy_single

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fdiv_rz(float x, float y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Divide two floating-point values in round-up mode.

 * 

 * Divide two floating-point values \p x by \p y in round-up (to positive infinity) mode.

 *    

 * \return Returns \p x / \p y.

 *

 * \note_accuracy_single

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fdiv_ru(float x, float y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_SINGLE

 * \brief Divide two floating-point values in round-down mode.

 *

 * Divide two floating-point values \p x by \p y in round-down (to negative infinity) mode.

 *

 * \return Returns \p x / \p y.

 *

 * \note_accuracy_single

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ float                  __fdiv_rd(float x, float y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Return the number of consecutive high-order zero bits in a 32-bit integer.

 *

 * Count the number of consecutive leading zero bits, starting at the most significant bit (bit 31) of \p x.

 *

 * \return Returns a value between 0 and 32 inclusive representing the number of zero bits.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ int                    __clz(int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Find the position of the least significant bit set to 1 in a 32-bit integer.

 *

 * Find the position of the first (least significant) bit set to 1 in \p x, where the least significant

 * bit position is 1. 

 *

 * \return Returns a value between 0 and 32 inclusive representing the position of the first bit set.

 * - __ffs(0) returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ int                    __ffs(int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Count the number of bits that are set to 1 in a 32-bit integer.

 *

 * Count the number of bits that are set to 1 in \p x.

 *

 * \return Returns a value between 0 and 32 inclusive representing the number of set bits.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ int                    __popc(unsigned int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Reverse the bit order of a 32-bit unsigned integer.

 *

 * Reverses the bit order of the 32-bit unsigned integer \p x.

 *

 * \return Returns the bit-reversed value of \p x. i.e. bit N of the return value corresponds to bit 31-N of \p x.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __brev(unsigned int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Count the number of consecutive high-order zero bits in a 64-bit integer.

 *

 * Count the number of consecutive leading zero bits, starting at the most significant bit (bit 63) of \p x.

 *

 * \return Returns a value between 0 and 64 inclusive representing the number of zero bits.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ int                    __clzll(long long int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Find the position of the least significant bit set to 1 in a 64-bit integer.

 *

 * Find the position of the first (least significant) bit set to 1 in \p x, where the least significant

 * bit position is 1. 

 *

 * \return Returns a value between 0 and 64 inclusive representing the position of the first bit set.

 * - __ffsll(0) returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ int                    __ffsll(long long int x);


/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Count the number of bits that are set to 1 in a 64-bit integer.

 *

 * Count the number of bits that are set to 1 in \p x.

 *

 * \return Returns a value between 0 and 64 inclusive representing the number of set bits.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ int                    __popcll(unsigned long long int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Reverse the bit order of a 64-bit unsigned integer.

 *

 * Reverses the bit order of the 64-bit unsigned integer \p x.

 *

 * \return Returns the bit-reversed value of \p x. i.e. bit N of the return value corresponds to bit 63-N of \p x.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned long long int __brevll(unsigned long long int x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Return selected bytes from two 32-bit unsigned integers.

 *

 * \return Returns a 32-bit integer consisting of four bytes from eight input bytes provided in the two

 * input integers \p x and \p y, as specified by a selector, \p s.

 *

 * Create 8-byte source

 * - uint64_t \p tmp64 = ((uint64_t)\p y << 32) | \p x;

 *

 * Extract selector bits

 * - \p selector0 = (\p s >>  0) & 0x7;

 * - \p selector1 = (\p s >>  4) & 0x7;

 * - \p selector2 = (\p s >>  8) & 0x7;

 * - \p selector3 = (\p s >> 12) & 0x7;

 *

 * Return 4 selected bytes from 8-byte source:

 * - \p res[07:00] = \p tmp64[\p selector0];

 * - \p res[15:08] = \p tmp64[\p selector1];

 * - \p res[23:16] = \p tmp64[\p selector2];

 * - \p res[31:24] = \p tmp64[\p selector3];

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __byte_perm(unsigned int x, unsigned int y, unsigned int s);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Compute average of signed input arguments, avoiding overflow

 * in the intermediate sum.

 *

 * Compute average of signed input arguments \p x and \p y 

 * as ( \p x + \p y ) >> 1, avoiding overflow in the intermediate sum.

 *

 * \return Returns a signed integer value representing the signed 

 * average value of the two inputs.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ int                    __hadd(int x, int y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Compute rounded average of signed input arguments, avoiding

 * overflow in the intermediate sum.

 *

 * Compute average of signed input arguments \p x and \p y 

 * as ( \p x + \p y + 1 ) >> 1, avoiding overflow in the intermediate

 * sum.

 *

 * \return Returns a signed integer value representing the signed 

 * rounded average value of the two inputs.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ int                    __rhadd(int x, int y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Compute average of unsigned input arguments, avoiding overflow

 * in the intermediate sum.

 *

 * Compute average of unsigned input arguments \p x and \p y 

 * as ( \p x + \p y ) >> 1, avoiding overflow in the intermediate sum.

 *

 * \return Returns an unsigned integer value representing the unsigned 

 * average value of the two inputs.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __uhadd(unsigned int x, unsigned int y);
/**

 * \ingroup CUDA_MATH_INTRINSIC_INT

 * \brief Compute rounded average of unsigned input arguments, avoiding

 * overflow in the intermediate sum.

 *

 * Compute average of unsigned input arguments \p x and \p y 

 * as ( \p x + \p y + 1 ) >> 1, avoiding overflow in the intermediate

 * sum.

 *

 * \return Returns an unsigned integer value representing the unsigned 

 * rounded average value of the two inputs.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __urhadd(unsigned int x, unsigned int y);

/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a double to a signed int in round-towards-zero mode.

 *

 * Convert the double-precision floating-point value \p x to a

 * signed integer value in round-towards-zero mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ int                    __double2int_rz(double x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a double to an unsigned int in round-towards-zero mode.

 *

 * Convert the double-precision floating-point value \p x to an

 * unsigned integer value in round-towards-zero mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __double2uint_rz(double x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a double to a signed 64-bit int in round-towards-zero mode.

 *

 * Convert the double-precision floating-point value \p x to a

 * signed 64-bit integer value in round-towards-zero mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ long long int          __double2ll_rz(double x);
/**

 * \ingroup CUDA_MATH_INTRINSIC_CAST

 * \brief Convert a double to an unsigned 64-bit int in round-towards-zero mode.

 *

 * Convert the double-precision floating-point value \p x to an

 * unsigned 64-bit integer value in round-towards-zero mode.

 * \return Returns converted value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned long long int __double2ull_rz(double x);
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __pm0(void);
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __pm1(void);
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __pm2(void);
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int           __pm3(void);

/*******************************************************************************

 *                                                                             *

 *                        FP16 SIMD functions                                  *

 *                                                                             *

 *******************************************************************************/

 //  #include "fp16.h"


/*******************************************************************************

 *                                                                             *

 *                                SIMD functions                               *

 *                                                                             *

 *******************************************************************************/

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-halfword absolute value.

 *

 * Splits 4 bytes of argument into 2 parts, each consisting of 2 bytes,

 * then computes absolute value for each of parts.

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vabs2(unsigned int a);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-halfword absolute value with signed saturation.

 *

 * Splits 4 bytes of argument into 2 parts, each consisting of 2 bytes,

 * then computes absolute value with signed saturation for each of parts.

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vabsss2(unsigned int a);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword (un)signed addition, with wrap-around: a + b

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes,

 * then performs unsigned addition on corresponding parts.

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vadd2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword addition with signed saturation.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes,

 * then performs addition with signed saturation on corresponding parts.

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vaddss2 (unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword addition with unsigned saturation.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes,

 * then performs addition with unsigned saturation on corresponding parts.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vaddus2 (unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword signed rounded average computation.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes,

 * then computes signed rounded average of corresponding parts. Partial results are

 * recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vavgs2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword unsigned rounded average computation.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes,

 * then computes unsigned rounded average of corresponding parts. Partial results are

 * recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vavgu2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword unsigned average computation.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes,

 * then computes unsigned average of corresponding parts. Partial results are

 * recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vhaddu2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword (un)signed comparison.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts result is ffff if they are equal, and 0000 otherwise.

 * For example __vcmpeq2(0x1234aba5, 0x1234aba6) returns 0xffff0000.

 * \return Returns 0xffff computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmpeq2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword signed comparison: a >= b ? 0xffff : 0.

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts result is ffff if 'a' part >= 'b' part, and 0000 otherwise.

 * For example __vcmpges2(0x1234aba5, 0x1234aba6) returns 0xffff0000.

 * \return Returns 0xffff if a >= b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmpges2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword unsigned comparison: a >= b ? 0xffff : 0.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts result is ffff if 'a' part >= 'b' part, and 0000 otherwise.

 * For example __vcmpgeu2(0x1234aba5, 0x1234aba6) returns 0xffff0000.

 * \return Returns 0xffff if a >= b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmpgeu2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword signed comparison: a > b ? 0xffff : 0.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts result is ffff if 'a' part > 'b' part, and 0000 otherwise.

 * For example __vcmpgts2(0x1234aba5, 0x1234aba6) returns 0x00000000.

 * \return Returns 0xffff if a > b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmpgts2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword unsigned comparison: a > b ? 0xffff : 0.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts result is ffff if 'a' part > 'b' part, and 0000 otherwise.

 * For example __vcmpgtu2(0x1234aba5, 0x1234aba6) returns 0x00000000.

 * \return Returns 0xffff if a > b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmpgtu2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword signed comparison: a <= b ? 0xffff : 0.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts result is ffff if 'a' part <= 'b' part, and 0000 otherwise.

 * For example __vcmples2(0x1234aba5, 0x1234aba6) returns 0xffffffff.

 * \return Returns 0xffff if a <= b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmples2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword unsigned comparison: a <= b ? 0xffff : 0.

 *

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts result is ffff if 'a' part <= 'b' part, and 0000 otherwise.

 * For example __vcmpleu2(0x1234aba5, 0x1234aba6) returns 0xffffffff.

 * \return Returns 0xffff if a <= b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmpleu2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword signed comparison: a < b ? 0xffff : 0.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts result is ffff if 'a' part < 'b' part, and 0000 otherwise.

 * For example __vcmplts2(0x1234aba5, 0x1234aba6) returns 0x0000ffff.

 * \return Returns 0xffff if a < b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmplts2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword unsigned comparison: a < b ? 0xffff : 0.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts result is ffff if 'a' part < 'b' part, and 0000 otherwise.

 * For example __vcmpltu2(0x1234aba5, 0x1234aba6) returns 0x0000ffff.

 * \return Returns 0xffff if a < b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmpltu2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword (un)signed comparison: a != b ? 0xffff : 0.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts result is ffff if 'a' part != 'b' part, and 0000 otherwise.

 * For example __vcmplts2(0x1234aba5, 0x1234aba6) returns 0x0000ffff.

 * \return Returns 0xffff if a != b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmpne2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword absolute difference of unsigned integer computation: |a - b|

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function computes absolute difference. Partial results

 * are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vabsdiffu2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword signed maximum computation.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function computes signed maximum. Partial results

 * are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vmaxs2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword unsigned maximum computation.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function computes unsigned maximum. Partial results

 * are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vmaxu2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword signed minimum computation.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function computes signed minimum. Partial results

 * are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vmins2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword unsigned minimum computation.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function computes unsigned minimum. Partial results

 * are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vminu2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword (un)signed comparison.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function performs comparison 'a' part == 'b' part.

 * If both equalities are satisfied, function returns 1.

 * \return Returns 1 if a = b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vseteq2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword signed comparison.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function performs comparison 'a' part >= 'b' part.

 * If both inequalities are satisfied, function returns 1.

 * \return Returns 1 if a >= b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetges2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword unsigned minimum unsigned comparison.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function performs comparison 'a' part >= 'b' part.

 * If both inequalities are satisfied, function returns 1.

 * \return Returns 1 if a >= b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetgeu2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword signed comparison.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function performs comparison 'a' part > 'b' part.

 * If both inequalities are satisfied, function returns 1.

 * \return Returns 1 if a > b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetgts2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword unsigned comparison.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function performs comparison 'a' part > 'b' part.

 * If both inequalities are satisfied, function returns 1.

 * \return Returns 1 if a > b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetgtu2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword unsigned minimum computation.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function performs comparison 'a' part <= 'b' part.

 * If both inequalities are satisfied, function returns 1.

 * \return Returns 1 if a <= b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetles2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword signed comparison.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function performs comparison 'a' part <= 'b' part.

 * If both inequalities are satisfied, function returns 1.

 * \return Returns 1 if a <= b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetleu2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword signed comparison.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function performs comparison 'a' part <= 'b' part.

 * If both inequalities are satisfied, function returns 1.

 * \return Returns 1 if a < b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetlts2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword unsigned comparison.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function performs comparison 'a' part <= 'b' part.

 * If both inequalities are satisfied, function returns 1.

 * \return Returns 1 if a < b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetltu2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword (un)signed comparison.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function performs comparison 'a' part != 'b' part.

 * If both conditions are satisfied, function returns 1.

 * \return Returns 1 if a != b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetne2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-halfword sum of abs diff of unsigned.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function computes absolute differences and returns

 * sum of those differences.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsadu2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword (un)signed subtraction, with wrap-around.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function performs subtraction. Partial results

 * are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsub2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword (un)signed subtraction, with signed saturation.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function performs subtraction with signed saturation.

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsubss2 (unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword subtraction with unsigned saturation.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function performs subtraction with unsigned saturation.

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsubus2 (unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-halfword negation.

 *

 * Splits 4 bytes of argument into 2 parts, each consisting of 2 bytes.

 * For each part function computes negation. Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vneg2(unsigned int a);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-halfword negation with signed saturation.

 *

 * Splits 4 bytes of argument into 2 parts, each consisting of 2 bytes.

 * For each part function computes negation. Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vnegss2(unsigned int a);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-halfword sum of absolute difference of signed integer.

 *

 * Splits 4 bytes of each into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function computes absolute difference.

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vabsdiffs2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword sum of absolute difference of signed.

 *

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * For corresponding parts function computes absolute difference and sum it up.

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsads2(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-byte absolute value.

 *

 * Splits argument by bytes. Computes absolute value of each byte.

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vabs4(unsigned int a);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-byte absolute value with signed saturation.

 *

 * Splits 4 bytes of argument into 4 parts, each consisting of 1 byte,

 * then computes absolute value with signed saturation for each of parts.

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vabsss4(unsigned int a);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte (un)signed addition.

 *

 * Splits 'a' into 4 bytes, then performs unsigned addition on each of these

 * bytes with the corresponding byte from 'b', ignoring overflow.

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vadd4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte addition with signed saturation.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte,

 * then performs addition with signed saturation on corresponding parts.

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vaddss4 (unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte addition with unsigned saturation.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte,

 * then performs addition with unsigned saturation on corresponding parts.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vaddus4 (unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-byte signed rounded average.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * then computes signed rounded average of corresponding parts. Partial results are

 * recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vavgs4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte unsigned rounded average.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * then computes unsigned rounded average of corresponding parts. Partial results are

 * recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vavgu4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-byte unsigned average.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * then computes unsigned average of corresponding parts. Partial results are

 * recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vhaddu4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte (un)signed comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts result is ff if they are equal, and 00 otherwise.

 * For example __vcmpeq4(0x1234aba5, 0x1234aba6) returns 0xffffff00.

 * \return Returns 0xff if a = b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmpeq4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte signed comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts result is ff if 'a' part >= 'b' part, and 00 otherwise.

 * For example __vcmpges4(0x1234aba5, 0x1234aba6) returns 0xffffff00.

 * \return Returns 0xff if a >= b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmpges4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte unsigned comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts result is ff if 'a' part >= 'b' part, and 00 otherwise.

 * For example __vcmpgeu4(0x1234aba5, 0x1234aba6) returns 0xffffff00.

 * \return Returns 0xff if a = b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmpgeu4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte signed comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts result is ff if 'a' part > 'b' part, and 00 otherwise.

 * For example __vcmpgts4(0x1234aba5, 0x1234aba6) returns 0x00000000.

 * \return Returns 0xff if a > b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmpgts4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte unsigned comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts result is ff if 'a' part > 'b' part, and 00 otherwise.

 * For example __vcmpgtu4(0x1234aba5, 0x1234aba6) returns 0x00000000.

 * \return Returns 0xff if a > b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmpgtu4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte signed comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts result is ff if 'a' part <= 'b' part, and 00 otherwise.

 * For example __vcmples4(0x1234aba5, 0x1234aba6) returns 0xffffffff.

 * \return Returns 0xff if a <= b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmples4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte unsigned comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts result is ff if 'a' part <= 'b' part, and 00 otherwise.

 * For example __vcmpleu4(0x1234aba5, 0x1234aba6) returns 0xffffffff.

 * \return Returns 0xff if a <= b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmpleu4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte signed comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts result is ff if 'a' part < 'b' part, and 00 otherwise.

 * For example __vcmplts4(0x1234aba5, 0x1234aba6) returns 0x000000ff.

 * \return Returns 0xff if a < b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmplts4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte unsigned comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts result is ff if 'a' part < 'b' part, and 00 otherwise.

 * For example __vcmpltu4(0x1234aba5, 0x1234aba6) returns 0x000000ff.

 * \return Returns 0xff if a < b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmpltu4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte (un)signed comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts result is ff if 'a' part != 'b' part, and 00 otherwise.

 * For example __vcmplts4(0x1234aba5, 0x1234aba6) returns 0x000000ff.

 * \return Returns 0xff if a != b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vcmpne4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-byte absolute difference of unsigned integer.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function computes absolute difference. Partial results

 * are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vabsdiffu4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-byte signed maximum.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function computes signed maximum. Partial results

 * are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vmaxs4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-byte unsigned maximum.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function computes unsigned maximum. Partial results

 * are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vmaxu4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-byte signed minimum.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function computes signed minimum. Partial results

 * are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vmins4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-byte unsigned minimum.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function computes unsigned minimum. Partial results

 * are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vminu4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte (un)signed comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function performs comparison 'a' part == 'b' part.

 * If both equalities are satisfied, function returns 1.

 * \return Returns 1 if a = b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vseteq4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte signed comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function performs comparison 'a' part <= 'b' part.

 * If both inequalities are satisfied, function returns 1.

 * \return Returns 1 if a <= b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetles4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte unsigned comparison.

 *

 * Splits 4 bytes of each argument into 4 part, each consisting of 1 byte.

 * For corresponding parts function performs comparison 'a' part <= 'b' part.

 * If both inequalities are satisfied, function returns 1.

 * \return Returns 1 if a <= b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetleu4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte signed comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function performs comparison 'a' part <= 'b' part.

 * If both inequalities are satisfied, function returns 1.

 * \return Returns 1 if a < b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetlts4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte unsigned comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function performs comparison 'a' part <= 'b' part.

 * If both inequalities are satisfied, function returns 1.

 * \return Returns 1 if a < b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetltu4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte signed comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function performs comparison 'a' part >= 'b' part.

 * If both inequalities are satisfied, function returns 1.

 * \return Returns 1 if a >= b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetges4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte unsigned comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function performs comparison 'a' part >= 'b' part.

 * If both inequalities are satisfied, function returns 1.

 * \return Returns 1 if a >= b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetgeu4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte signed comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function performs comparison 'a' part > 'b' part.

 * If both inequalities are satisfied, function returns 1.

 * \return Returns 1 if a > b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetgts4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte unsigned comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function performs comparison 'a' part > 'b' part.

 * If both inequalities are satisfied, function returns 1.

 * \return Returns 1 if a > b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetgtu4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte (un)signed comparison.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function performs comparison 'a' part != 'b' part.

 * If both conditions are satisfied, function returns 1.

 * \return Returns 1 if a != b, else returns 0.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsetne4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-byte sum of abs difference of unsigned.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function computes absolute differences and returns

 * sum of those differences.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsadu4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte subtraction.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function performs subtraction. Partial results

 * are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsub4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte subtraction with signed saturation.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function performs subtraction with signed saturation.

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsubss4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte subtraction with unsigned saturation.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function performs subtraction with unsigned saturation.

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsubus4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte negation.

 *

 * Splits 4 bytes of argument into 4 parts, each consisting of 1 byte.

 * For each part function computes negation. Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vneg4(unsigned int a);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-byte negation with signed saturation.

 *

 * Splits 4 bytes of argument into 4 parts, each consisting of 1 byte.

 * For each part function computes negation. Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vnegss4(unsigned int a);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-byte absolute difference of signed integer.

 *

 * Splits 4 bytes of each into 4 parts, each consisting of 1 byte.

 * For corresponding parts function computes absolute difference.

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vabsdiffs4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes per-byte sum of abs difference of signed.

 *

 * Splits 4 bytes of each argument into 4 parts, each consisting of 1 byte.

 * For corresponding parts function computes absolute difference and sum it up.

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_FUNCTIONS_DECL__ __device_builtin__ unsigned int __vsads4(unsigned int a, unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes max(max(a, b), 0)

 *

 * Calculates the maximum of \p a and \p b of two signed ints, if this is less than \p 0 then \p 0 is returned.

 * \return Returns computed value.

 */

__DEVICE_HOST_FUNCTIONS_STATIC_DECL__ int __vimax_s32_relu(const int a, const int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword max(max(a, b), 0)

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as signed shorts.

 * For corresponding parts function performs a max with relu ( = max(a_part, b_part, 0) ). Partial results

 * are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __vimax_s16x2_relu(const unsigned int a, const unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes max(min(a, b), 0)

 *

 * Calculates the minimum of \p a and \p b of two signed ints, if this is less than \p 0 then \p 0 is returned.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  int __vimin_s32_relu(const int a, const int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword max(min(a, b), 0)

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as signed shorts.

 * For corresponding parts function performs a min with relu ( = max(min(a_part, b_part), 0) ). Partial results

 * are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __vimin_s16x2_relu(const unsigned int a, const unsigned int b);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes max(max(a, b), c)

 * 

 * Calculates the 3-way max of signed integers \p a, \p b and \p c.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  int __vimax3_s32(const int a, const int b, const int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword max(max(a, b), c)

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as signed shorts.

 * For corresponding parts function performs a 3-way max ( = max(max(a_part, b_part), c_part) ).

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __vimax3_s16x2(const unsigned int a, const unsigned int b, const unsigned int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes max(max(a, b), c)

 * 

 * Calculates the 3-way max of unsigned integers \p a, \p b and \p c.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __vimax3_u32(const unsigned int a, const unsigned int b, const unsigned int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword max(max(a, b), c)

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as unsigned shorts.

 * For corresponding parts function performs a 3-way max ( = max(max(a_part, b_part), c_part) ).

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __vimax3_u16x2(const unsigned int a, const unsigned int b, const unsigned int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes min(min(a, b), c)

 * 

 * Calculates the 3-way min of signed integers \p a, \p b and \p c.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  int __vimin3_s32(const int a, const int b, const int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword min(min(a, b), c)

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as signed shorts.

 * For corresponding parts function performs a 3-way min ( = min(min(a_part, b_part), c_part) ).

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __vimin3_s16x2(const unsigned int a, const unsigned int b, const unsigned int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes min(min(a, b), c)

 * 

 * Calculates the 3-way min of unsigned integers \p a, \p b and \p c.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __vimin3_u32(const unsigned int a, const unsigned int b, const unsigned int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword min(min(a, b), c)

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as unsigned shorts.

 * For corresponding parts function performs a 3-way min ( = min(min(a_part, b_part), c_part) ).

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __vimin3_u16x2(const unsigned int a, const unsigned int b, const unsigned int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes max(max(max(a, b), c), 0)

 *

 * Calculates the maximum of three signed ints, if this is less than \p 0 then \p 0 is returned.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  int __vimax3_s32_relu(const int a, const int b, const int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword max(max(max(a, b), c), 0)

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as signed shorts.

 * For corresponding parts function performs a three-way max with relu ( = max(a_part, b_part, c_part, 0) ).

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __vimax3_s16x2_relu(const unsigned int a, const unsigned int b, const unsigned int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes max(min(min(a, b), c), 0)

 *

 * Calculates the minimum of three signed ints, if this is less than \p 0 then \p 0 is returned.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  int __vimin3_s32_relu(const int a, const int b, const int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword max(min(min(a, b), c), 0)

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as signed shorts.

 * For corresponding parts function performs a three-way min with relu ( = max(min(a_part, b_part, c_part), 0) ).

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __vimin3_s16x2_relu(const unsigned int a, const unsigned int b, const unsigned int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes max(a + b, c)

 *

 * Calculates the sum of signed integers \p a and \p b and takes the max with \p c.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  int __viaddmax_s32(const int a, const int b, const int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword max(a + b, c)

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as signed shorts.

 * For corresponding parts function performs an add and compare: max(a_part + b_part), c_part)

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __viaddmax_s16x2(const unsigned int a, const unsigned int b, const unsigned int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes max(a + b, c)

 *

 * Calculates the sum of unsigned integers \p a and \p b and takes the max with \p c.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __viaddmax_u32(const unsigned int a, const unsigned int b, const unsigned int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword max(a + b, c)

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as unsigned shorts.

 * For corresponding parts function performs an add and compare: max(a_part + b_part), c_part)

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __viaddmax_u16x2(const unsigned int a, const unsigned int b, const unsigned int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes min(a + b, c)

 *

 * Calculates the sum of signed integers \p a and \p b and takes the min with \p c.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  int __viaddmin_s32(const int a, const int b, const int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword min(a + b, c)

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as signed shorts.

 * For corresponding parts function performs an add and compare: min(a_part + b_part), c_part)

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __viaddmin_s16x2(const unsigned int a, const unsigned int b, const unsigned int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes min(a + b, c)

 *

 * Calculates the sum of unsigned integers \p a and \p b and takes the min with \p c.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __viaddmin_u32(const unsigned int a, const unsigned int b, const unsigned int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword min(a + b, c)

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as unsigned shorts.

 * For corresponding parts function performs an add and compare: min(a_part + b_part), c_part)

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __viaddmin_u16x2(const unsigned int a, const unsigned int b, const unsigned int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes max(max(a + b, c), 0)

 *

 * Calculates the sum of signed integers \p a and \p b and takes the max with \p c.

 * If the result is less than \p 0 then \0 is returned.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  int __viaddmax_s32_relu(const int a, const int b, const int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword max(max(a + b, c), 0)

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as signed shorts.

 * For corresponding parts function performs an add, followed by a max with relu: max(max(a_part + b_part), c_part), 0)

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __viaddmax_s16x2_relu(const unsigned int a, const unsigned int b, const unsigned int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes max(min(a + b, c), 0)

 *

 * Calculates the sum of signed integers \p a and \p b and takes the min with \p c.

 * If the result is less than \p 0 then \0 is returned.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  int __viaddmin_s32_relu(const int a, const int b, const int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword max(min(a + b, c), 0)

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as signed shorts.

 * For corresponding parts function performs an add, followed by a min with relu: max(min(a_part + b_part), c_part), 0)

 * Partial results are recombined and returned as unsigned int.

 * \return Returns computed value.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __viaddmin_s16x2_relu(const unsigned int a, const unsigned int b, const unsigned int c);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes max(a, b), also sets the value pointed to by pred to (a >= b).

 *

 * Calculates the maximum of \p a and \p b of two signed ints. Also sets the value pointed to by \p pred to the value (a >= b).

 * \return Returns computed values.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  int __vibmax_s32(const int a, const int b, bool* const pred);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes max(a, b), also sets the value pointed to by pred to (a >= b).

 *

 * Calculates the maximum of \p a and \p b of two unsigned ints. Also sets the value pointed to by \p pred to the value (a >= b).

 * \return Returns computed values.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __vibmax_u32(const unsigned int a, const unsigned int b, bool* const pred);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes min(a, b), also sets the value pointed to by pred to (a <= b).

 *

 * Calculates the minimum of \p a and \p b of two signed ints. Also sets the value pointed to by \p pred to the value (a <= b).

 * \return Returns computed values.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  int __vibmin_s32(const int a, const int b, bool* const pred);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Computes min(a, b), also sets the value pointed to by pred to (a <= b).

 *

 * Calculates the minimum of \p a and \p b of two unsigned ints. Also sets the value pointed to by \p pred to the value (a <= b).

 * \return Returns computed values.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __vibmin_u32(const unsigned int a, const unsigned int b, bool* const pred);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword max(a, b), also sets the value pointed to by pred_hi and pred_lo to the per-halfword result of (a >= b).

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as signed shorts.

 * For corresponding parts function performs a maximum ( = max(a_part, b_part) ).

 * Partial results are recombined and returned as unsigned int.

 * Sets the value pointed to by \p pred_hi to the value (a_high_part >= b_high_part).

 * Sets the value pointed to by \p pred_lo to the value (a_low_part >= b_low_part).

 * \return Returns computed values.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __vibmax_s16x2(const unsigned int a, const unsigned int b, bool* const pred_hi, bool* const pred_lo);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword max(a, b), also sets the value pointed to by pred_hi and pred_lo to the per-halfword result of (a >= b).

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as unsigned shorts.

 * For corresponding parts function performs a maximum ( = max(a_part, b_part) ).

 * Partial results are recombined and returned as unsigned int.

 * Sets the value pointed to by \p pred_hi to the value (a_high_part >= b_high_part).

 * Sets the value pointed to by \p pred_lo to the value (a_low_part >= b_low_part).

 * \return Returns computed values.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __vibmax_u16x2(const unsigned int a, const unsigned int b, bool* const pred_hi, bool* const pred_lo);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword min(a, b), also sets the value pointed to by pred_hi and pred_lo to the per-halfword result of (a <= b).

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as signed shorts.

 * For corresponding parts function performs a maximum ( = max(a_part, b_part) ).

 * Partial results are recombined and returned as unsigned int.

 * Sets the value pointed to by \p pred_hi to the value (a_high_part <= b_high_part).

 * Sets the value pointed to by \p pred_lo to the value (a_low_part <= b_low_part).

 * \return Returns computed values.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __vibmin_s16x2(const unsigned int a, const unsigned int b, bool* const pred_hi, bool* const pred_lo);

/**

 * \ingroup CUDA_MATH_INTRINSIC_SIMD

 * \brief Performs per-halfword min(a, b), also sets the value pointed to by pred_hi and pred_lo to the per-halfword result of (a <= b).

 * 

 * Splits 4 bytes of each argument into 2 parts, each consisting of 2 bytes.

 * These 2 byte parts are interpreted as unsigned shorts.

 * For corresponding parts function performs a maximum ( = max(a_part, b_part) ).

 * Partial results are recombined and returned as unsigned int.

 * Sets the value pointed to by \p pred_hi to the value (a_high_part <= b_high_part).

 * Sets the value pointed to by \p pred_lo to the value (a_low_part <= b_low_part).

 * \return Returns computed values.

 */
__DEVICE_HOST_FUNCTIONS_STATIC_DECL__  unsigned int __vibmin_u16x2(const unsigned int a, const unsigned int b, bool* const pred_hi, bool* const pred_lo);

/*******************************************************************************

 *                                                                             *

 *                            END SIMD functions                               *

 *                                                                             *

 *******************************************************************************/
} //extern "c"
#undef EXCLUDE_FROM_RTC

#undef __DEVICE_FUNCTIONS_DECL__
#undef __DEVICE_FUNCTIONS_STATIC_DECL__
#undef __DEVICE_HOST_FUNCTIONS_STATIC_DECL__

#endif /* __cplusplus && __CUDACC__ */

/*******************************************************************************

*                                                                              *

*                                                                              *

*                                                                              *

*******************************************************************************/

#if !defined(__CUDACC_RTC__)
#include "device_functions.hpp"
#endif /* !defined(__CUDACC_RTC__) */

#include "device_atomic_functions.h"
#include "device_double_functions.h"
#include "sm_20_atomic_functions.h"
#include "sm_32_atomic_functions.h"
#include "sm_35_atomic_functions.h"
#include "sm_60_atomic_functions.h"
#include "sm_20_intrinsics.h"
#include "sm_30_intrinsics.h"
#include "sm_32_intrinsics.h"
#include "sm_35_intrinsics.h"
#include "sm_61_intrinsics.h"
#include "sm_70_rt.h"
#include "sm_80_rt.h"
#include "sm_90_rt.h"
#ifndef __CUDACC_RTC_MINIMAL__
#include "texture_indirect_functions.h"
#include "surface_indirect_functions.h"
#endif  /* !__CUDACC_RTC_MINIMAL__ */
#include "cudacc_ext.h"

#ifdef __CUDACC__
extern "C" __host__ __device__  unsigned CUDARTAPI __cudaPushCallConfiguration(dim3 gridDim,
                                      dim3 blockDim, 
                                      size_t sharedMem = 0, 
                                      struct CUstream_st *stream = 0);

#if !defined(__CUDACC_RTC__) &&!defined(__NV_LEGACY_LAUNCH)
extern "C" cudaError_t CUDARTAPI __cudaGetKernel(cudaKernel_t *, const void *);

extern "C"  cudaError_t CUDARTAPI __cudaLaunchKernel(
        cudaKernel_t kernel,
        dim3 gridDim,
        dim3 blockDim,
        void **args,
        size_t sharedMem,
        cudaStream_t stream
);

extern "C" cudaError_t CUDARTAPI __cudaLaunchKernel_ptsz(
        cudaKernel_t kernel,
        dim3 gridDim,
        dim3 blockDim,
        void **args,
        size_t sharedMem,
        cudaStream_t stream
);

//referenced from compiler generated kernel launch code
static inline cudaError_t __cudaLaunchKernel_helper(
                                  cudaKernel_t kernel,
                                  dim3 gridDim,
                                  dim3 blockDim,
                                  void **args,
                                  size_t sharedMem,
                                  cudaStream_t stream)
{
#if defined(__CUDART_API_PER_THREAD_DEFAULT_STREAM)
  return __cudaLaunchKernel_ptsz(kernel, gridDim, blockDim, args, sharedMem,
                                 stream);
#else  /* !__CUDART_API_PER_THREAD_DEFAULT_STREAM */
  return __cudaLaunchKernel(kernel, gridDim, blockDim, args, sharedMem,
                            stream);
#endif  /* __CUDART_API_PER_THREAD_DEFAULT_STREAM */
}
#endif  /* !defined(__CUDACC_RTC__) && !defined(__NV_LEGACY_LAUNCH) */



#endif  /* __CUDACC__ */

#endif /* !__DEVICE_FUNCTIONS_H__ */

#if defined(__UNDEF_CUDA_INCLUDE_COMPILER_INTERNAL_HEADERS_DEVICE_FUNCTIONS_H__)
#undef __CUDA_INCLUDE_COMPILER_INTERNAL_HEADERS__
#undef __UNDEF_CUDA_INCLUDE_COMPILER_INTERNAL_HEADERS_DEVICE_FUNCTIONS_H__
#endif