Subversion Repositories QNX 8.QNX8 LLVM/Clang compiler suite

/*===-- __clang_cuda_complex_builtins - CUDA impls of runtime complex fns ---===

 *

 * Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.

 * See https://llvm.org/LICENSE.txt for license information.

 * SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception

 *

 *===-----------------------------------------------------------------------===

 */

#ifndef __CLANG_CUDA_COMPLEX_BUILTINS

#define __CLANG_CUDA_COMPLEX_BUILTINS

// This header defines __muldc3, __mulsc3, __divdc3, and __divsc3.  These are

// libgcc functions that clang assumes are available when compiling c99 complex

// operations.  (These implementations come from libc++, and have been modified

// to work with CUDA and OpenMP target offloading [in C and C++ mode].)

#pragma push_macro("__DEVICE__")

#if defined(__OPENMP_NVPTX__) || defined(__OPENMP_AMDGCN__)

#pragma omp declare target

#define __DEVICE__ __attribute__((noinline, nothrow, cold, weak))

#else

#define __DEVICE__ __device__ inline

#endif

// To make the algorithms available for C and C++ in CUDA and OpenMP we select

// different but equivalent function versions. TODO: For OpenMP we currently

// select the native builtins as the overload support for templates is lacking.

#if !defined(__OPENMP_NVPTX__) && !defined(__OPENMP_AMDGCN__)

#define _ISNANd std::isnan

#define _ISNANf std::isnan

#define _ISINFd std::isinf

#define _ISINFf std::isinf

#define _ISFINITEd std::isfinite

#define _ISFINITEf std::isfinite

#define _COPYSIGNd std::copysign

#define _COPYSIGNf std::copysign

#define _SCALBNd std::scalbn

#define _SCALBNf std::scalbn

#define _ABSd std::abs

#define _ABSf std::abs

#define _LOGBd std::logb

#define _LOGBf std::logb

// Rather than pulling in std::max from algorithm everytime, use available ::max.

#define _fmaxd max

#define _fmaxf max

#else

#ifdef __AMDGCN__

#define _ISNANd __ocml_isnan_f64

#define _ISNANf __ocml_isnan_f32

#define _ISINFd __ocml_isinf_f64

#define _ISINFf __ocml_isinf_f32

#define _ISFINITEd __ocml_isfinite_f64

#define _ISFINITEf __ocml_isfinite_f32

#define _COPYSIGNd __ocml_copysign_f64

#define _COPYSIGNf __ocml_copysign_f32

#define _SCALBNd __ocml_scalbn_f64

#define _SCALBNf __ocml_scalbn_f32

#define _ABSd __ocml_fabs_f64

#define _ABSf __ocml_fabs_f32

#define _LOGBd __ocml_logb_f64

#define _LOGBf __ocml_logb_f32

#define _fmaxd __ocml_fmax_f64

#define _fmaxf __ocml_fmax_f32

#else

#define _ISNANd __nv_isnand

#define _ISNANf __nv_isnanf

#define _ISINFd __nv_isinfd

#define _ISINFf __nv_isinff

#define _ISFINITEd __nv_isfinited

#define _ISFINITEf __nv_finitef

#define _COPYSIGNd __nv_copysign

#define _COPYSIGNf __nv_copysignf

#define _SCALBNd __nv_scalbn

#define _SCALBNf __nv_scalbnf

#define _ABSd __nv_fabs

#define _ABSf __nv_fabsf

#define _LOGBd __nv_logb

#define _LOGBf __nv_logbf

#define _fmaxd __nv_fmax

#define _fmaxf __nv_fmaxf

#endif

#endif

#if defined(__cplusplus)

extern "C" {

#endif

__DEVICE__ double _Complex __muldc3(double __a, double __b, double __c,

                                    double __d) {

  double __ac = __a * __c;

  double __bd = __b * __d;

  double __ad = __a * __d;

  double __bc = __b * __c;

  double _Complex z;

  __real__(z) = __ac - __bd;

  __imag__(z) = __ad + __bc;

  if (_ISNANd(__real__(z)) && _ISNANd(__imag__(z))) {

    int __recalc = 0;

    if (_ISINFd(__a) || _ISINFd(__b)) {

      __a = _COPYSIGNd(_ISINFd(__a) ? 1 : 0, __a);

      __b = _COPYSIGNd(_ISINFd(__b) ? 1 : 0, __b);

      if (_ISNANd(__c))

        __c = _COPYSIGNd(0, __c);

      if (_ISNANd(__d))

        __d = _COPYSIGNd(0, __d);

      __recalc = 1;

    }

    if (_ISINFd(__c) || _ISINFd(__d)) {

      __c = _COPYSIGNd(_ISINFd(__c) ? 1 : 0, __c);

      __d = _COPYSIGNd(_ISINFd(__d) ? 1 : 0, __d);

      if (_ISNANd(__a))

        __a = _COPYSIGNd(0, __a);

      if (_ISNANd(__b))

        __b = _COPYSIGNd(0, __b);

      __recalc = 1;

    }

    if (!__recalc &&

        (_ISINFd(__ac) || _ISINFd(__bd) || _ISINFd(__ad) || _ISINFd(__bc))) {

      if (_ISNANd(__a))

        __a = _COPYSIGNd(0, __a);

      if (_ISNANd(__b))

        __b = _COPYSIGNd(0, __b);

      if (_ISNANd(__c))

        __c = _COPYSIGNd(0, __c);

      if (_ISNANd(__d))

        __d = _COPYSIGNd(0, __d);

      __recalc = 1;

    }

    if (__recalc) {

      // Can't use std::numeric_limits<double>::infinity() -- that doesn't have

      // a device overload (and isn't constexpr before C++11, naturally).

      __real__(z) = __builtin_huge_val() * (__a * __c - __b * __d);

      __imag__(z) = __builtin_huge_val() * (__a * __d + __b * __c);

    }

  }

  return z;

}

__DEVICE__ float _Complex __mulsc3(float __a, float __b, float __c, float __d) {

  float __ac = __a * __c;

  float __bd = __b * __d;

  float __ad = __a * __d;

  float __bc = __b * __c;

  float _Complex z;

  __real__(z) = __ac - __bd;

  __imag__(z) = __ad + __bc;

  if (_ISNANf(__real__(z)) && _ISNANf(__imag__(z))) {

    int __recalc = 0;

    if (_ISINFf(__a) || _ISINFf(__b)) {

      __a = _COPYSIGNf(_ISINFf(__a) ? 1 : 0, __a);

      __b = _COPYSIGNf(_ISINFf(__b) ? 1 : 0, __b);

      if (_ISNANf(__c))

        __c = _COPYSIGNf(0, __c);

      if (_ISNANf(__d))

        __d = _COPYSIGNf(0, __d);

      __recalc = 1;

    }

    if (_ISINFf(__c) || _ISINFf(__d)) {

      __c = _COPYSIGNf(_ISINFf(__c) ? 1 : 0, __c);

      __d = _COPYSIGNf(_ISINFf(__d) ? 1 : 0, __d);

      if (_ISNANf(__a))

        __a = _COPYSIGNf(0, __a);

      if (_ISNANf(__b))

        __b = _COPYSIGNf(0, __b);

      __recalc = 1;

    }

    if (!__recalc &&

        (_ISINFf(__ac) || _ISINFf(__bd) || _ISINFf(__ad) || _ISINFf(__bc))) {

      if (_ISNANf(__a))

        __a = _COPYSIGNf(0, __a);

      if (_ISNANf(__b))

        __b = _COPYSIGNf(0, __b);

      if (_ISNANf(__c))

        __c = _COPYSIGNf(0, __c);

      if (_ISNANf(__d))

        __d = _COPYSIGNf(0, __d);

      __recalc = 1;

    }

    if (__recalc) {

      __real__(z) = __builtin_huge_valf() * (__a * __c - __b * __d);

      __imag__(z) = __builtin_huge_valf() * (__a * __d + __b * __c);

    }

  }

  return z;

}

__DEVICE__ double _Complex __divdc3(double __a, double __b, double __c,

                                    double __d) {

  int __ilogbw = 0;

  // Can't use std::max, because that's defined in <algorithm>, and we don't

  // want to pull that in for every compile.  The CUDA headers define

  // ::max(float, float) and ::max(double, double), which is sufficient for us.

  double __logbw = _LOGBd(_fmaxd(_ABSd(__c), _ABSd(__d)));

  if (_ISFINITEd(__logbw)) {

    __ilogbw = (int)__logbw;

    __c = _SCALBNd(__c, -__ilogbw);

    __d = _SCALBNd(__d, -__ilogbw);

  }

  double __denom = __c * __c + __d * __d;

  double _Complex z;

  __real__(z) = _SCALBNd((__a * __c + __b * __d) / __denom, -__ilogbw);

  __imag__(z) = _SCALBNd((__b * __c - __a * __d) / __denom, -__ilogbw);

  if (_ISNANd(__real__(z)) && _ISNANd(__imag__(z))) {

    if ((__denom == 0.0) && (!_ISNANd(__a) || !_ISNANd(__b))) {

      __real__(z) = _COPYSIGNd(__builtin_huge_val(), __c) * __a;

      __imag__(z) = _COPYSIGNd(__builtin_huge_val(), __c) * __b;

    } else if ((_ISINFd(__a) || _ISINFd(__b)) && _ISFINITEd(__c) &&

               _ISFINITEd(__d)) {

      __a = _COPYSIGNd(_ISINFd(__a) ? 1.0 : 0.0, __a);

      __b = _COPYSIGNd(_ISINFd(__b) ? 1.0 : 0.0, __b);

      __real__(z) = __builtin_huge_val() * (__a * __c + __b * __d);

      __imag__(z) = __builtin_huge_val() * (__b * __c - __a * __d);

    } else if (_ISINFd(__logbw) && __logbw > 0.0 && _ISFINITEd(__a) &&

               _ISFINITEd(__b)) {

      __c = _COPYSIGNd(_ISINFd(__c) ? 1.0 : 0.0, __c);

      __d = _COPYSIGNd(_ISINFd(__d) ? 1.0 : 0.0, __d);

      __real__(z) = 0.0 * (__a * __c + __b * __d);

      __imag__(z) = 0.0 * (__b * __c - __a * __d);

    }

  }

  return z;

}

__DEVICE__ float _Complex __divsc3(float __a, float __b, float __c, float __d) {

  int __ilogbw = 0;

  float __logbw = _LOGBf(_fmaxf(_ABSf(__c), _ABSf(__d)));

  if (_ISFINITEf(__logbw)) {

    __ilogbw = (int)__logbw;

    __c = _SCALBNf(__c, -__ilogbw);

    __d = _SCALBNf(__d, -__ilogbw);

  }

  float __denom = __c * __c + __d * __d;

  float _Complex z;

  __real__(z) = _SCALBNf((__a * __c + __b * __d) / __denom, -__ilogbw);

  __imag__(z) = _SCALBNf((__b * __c - __a * __d) / __denom, -__ilogbw);

  if (_ISNANf(__real__(z)) && _ISNANf(__imag__(z))) {

    if ((__denom == 0) && (!_ISNANf(__a) || !_ISNANf(__b))) {

      __real__(z) = _COPYSIGNf(__builtin_huge_valf(), __c) * __a;

      __imag__(z) = _COPYSIGNf(__builtin_huge_valf(), __c) * __b;

    } else if ((_ISINFf(__a) || _ISINFf(__b)) && _ISFINITEf(__c) &&

               _ISFINITEf(__d)) {

      __a = _COPYSIGNf(_ISINFf(__a) ? 1 : 0, __a);

      __b = _COPYSIGNf(_ISINFf(__b) ? 1 : 0, __b);

      __real__(z) = __builtin_huge_valf() * (__a * __c + __b * __d);

      __imag__(z) = __builtin_huge_valf() * (__b * __c - __a * __d);

    } else if (_ISINFf(__logbw) && __logbw > 0 && _ISFINITEf(__a) &&

               _ISFINITEf(__b)) {

      __c = _COPYSIGNf(_ISINFf(__c) ? 1 : 0, __c);

      __d = _COPYSIGNf(_ISINFf(__d) ? 1 : 0, __d);

      __real__(z) = 0 * (__a * __c + __b * __d);

      __imag__(z) = 0 * (__b * __c - __a * __d);

    }

  }

  return z;

}

#if defined(__cplusplus)

} // extern "C"

#endif

#undef _ISNANd

#undef _ISNANf

#undef _ISINFd

#undef _ISINFf

#undef _COPYSIGNd

#undef _COPYSIGNf

#undef _ISFINITEd

#undef _ISFINITEf

#undef _SCALBNd

#undef _SCALBNf

#undef _ABSd

#undef _ABSf

#undef _LOGBd

#undef _LOGBf

#undef _fmaxd

#undef _fmaxf

#if defined(__OPENMP_NVPTX__) || defined(__OPENMP_AMDGCN__)

#pragma omp end declare target

#endif

#pragma pop_macro("__DEVICE__")

#endif // __CLANG_CUDA_COMPLEX_BUILTINS