clang/lib/Headers/openmp_wrappers/complex_cmath.h - llvm-project - Git at Google

 //===------------------------- __complex_cmath.h --------------------------===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//
 //
 // std::complex header copied from the libcxx source and simplified for use in
 // OpenMP target offload regions.
 //
 //===----------------------------------------------------------------------===//

 #ifndef _OPENMP
 #error "This file is for OpenMP compilation only."
 #endif

 #ifndef __cplusplus
 #error "This file is for C++ compilation only."
 #endif

 #ifndef _LIBCPP_COMPLEX
 #define _LIBCPP_COMPLEX

 #include <cmath>
 #include <type_traits>

 #define __DEVICE__ static constexpr __attribute__((nothrow))

 namespace std {

 // abs

 template <class _Tp> __DEVICE__ _Tp abs(const std::complex<_Tp> &__c) {
   return hypot(__c.real(), __c.imag());
 }

 // arg

 template <class _Tp> __DEVICE__ _Tp arg(const std::complex<_Tp> &__c) {
   return atan2(__c.imag(), __c.real());
 }

 template <class _Tp>
 typename enable_if<is_integral<_Tp>::value || is_same<_Tp, double>::value,
                    double>::type
 arg(_Tp __re) {
   return atan2(0., __re);
 }

 template <class _Tp>
 typename enable_if<is_same<_Tp, float>::value, float>::type arg(_Tp __re) {
   return atan2f(0.F, __re);
 }

 // norm

 template <class _Tp> __DEVICE__ _Tp norm(const std::complex<_Tp> &__c) {
   if (std::isinf(__c.real()))
     return abs(__c.real());
   if (std::isinf(__c.imag()))
     return abs(__c.imag());
   return __c.real() * __c.real() + __c.imag() * __c.imag();
 }

 // conj

 template <class _Tp> std::complex<_Tp> conj(const std::complex<_Tp> &__c) {
   return std::complex<_Tp>(__c.real(), -__c.imag());
 }

 // proj

 template <class _Tp> std::complex<_Tp> proj(const std::complex<_Tp> &__c) {
   std::complex<_Tp> __r = __c;
   if (std::isinf(__c.real()) || std::isinf(__c.imag()))
     __r = std::complex<_Tp>(INFINITY, copysign(_Tp(0), __c.imag()));
   return __r;
 }

 // polar

 template <class _Tp>
 complex<_Tp> polar(const _Tp &__rho, const _Tp &__theta = _Tp()) {
   if (std::isnan(__rho) || signbit(__rho))
     return std::complex<_Tp>(_Tp(NAN), _Tp(NAN));
   if (std::isnan(__theta)) {
     if (std::isinf(__rho))
       return std::complex<_Tp>(__rho, __theta);
     return std::complex<_Tp>(__theta, __theta);
   }
   if (std::isinf(__theta)) {
     if (std::isinf(__rho))
       return std::complex<_Tp>(__rho, _Tp(NAN));
     return std::complex<_Tp>(_Tp(NAN), _Tp(NAN));
   }
   _Tp __x = __rho * cos(__theta);
   if (std::isnan(__x))
     __x = 0;
   _Tp __y = __rho * sin(__theta);
   if (std::isnan(__y))
     __y = 0;
   return std::complex<_Tp>(__x, __y);
 }

 // log

 template <class _Tp> std::complex<_Tp> log(const std::complex<_Tp> &__x) {
   return std::complex<_Tp>(log(abs(__x)), arg(__x));
 }

 // log10

 template <class _Tp> std::complex<_Tp> log10(const std::complex<_Tp> &__x) {
   return log(__x) / log(_Tp(10));
 }

 // sqrt

 template <class _Tp>
 __DEVICE__ std::complex<_Tp> sqrt(const std::complex<_Tp> &__x) {
   if (std::isinf(__x.imag()))
     return std::complex<_Tp>(_Tp(INFINITY), __x.imag());
   if (std::isinf(__x.real())) {
     if (__x.real() > _Tp(0))
       return std::complex<_Tp>(__x.real(), std::isnan(__x.imag())
                                                ? __x.imag()
                                                : copysign(_Tp(0), __x.imag()));
     return std::complex<_Tp>(std::isnan(__x.imag()) ? __x.imag() : _Tp(0),
                              copysign(__x.real(), __x.imag()));
   }
   return polar(sqrt(abs(__x)), arg(__x) / _Tp(2));
 }

 // exp

 template <class _Tp>
 __DEVICE__ std::complex<_Tp> exp(const std::complex<_Tp> &__x) {
   _Tp __i = __x.imag();
   if (std::isinf(__x.real())) {
     if (__x.real() < _Tp(0)) {
       if (!std::isfinite(__i))
         __i = _Tp(1);
     } else if (__i == 0 || !std::isfinite(__i)) {
       if (std::isinf(__i))
         __i = _Tp(NAN);
       return std::complex<_Tp>(__x.real(), __i);
     }
   } else if (std::isnan(__x.real()) && __x.imag() == 0)
     return __x;
   _Tp __e = exp(__x.real());
   return std::complex<_Tp>(__e * cos(__i), __e * sin(__i));
 }

 // pow

 template <class _Tp>
 std::complex<_Tp> pow(const std::complex<_Tp> &__x,
                       const std::complex<_Tp> &__y) {
   return exp(__y * log(__x));
 }

 // __sqr, computes pow(x, 2)

 template <class _Tp> std::complex<_Tp> __sqr(const std::complex<_Tp> &__x) {
   return std::complex<_Tp>((__x.real() - __x.imag()) *
                                (__x.real() + __x.imag()),
                            _Tp(2) * __x.real() * __x.imag());
 }

 // asinh

 template <class _Tp>
 __DEVICE__ std::complex<_Tp> asinh(const std::complex<_Tp> &__x) {
   const _Tp __pi(atan2(+0., -0.));
   if (std::isinf(__x.real())) {
     if (std::isnan(__x.imag()))
       return __x;
     if (std::isinf(__x.imag()))
       return std::complex<_Tp>(__x.real(),
                                copysign(__pi * _Tp(0.25), __x.imag()));
     return std::complex<_Tp>(__x.real(), copysign(_Tp(0), __x.imag()));
   }
   if (std::isnan(__x.real())) {
     if (std::isinf(__x.imag()))
       return std::complex<_Tp>(__x.imag(), __x.real());
     if (__x.imag() == 0)
       return __x;
     return std::complex<_Tp>(__x.real(), __x.real());
   }
   if (std::isinf(__x.imag()))
     return std::complex<_Tp>(copysign(__x.imag(), __x.real()),
                              copysign(__pi / _Tp(2), __x.imag()));
   std::complex<_Tp> __z = log(__x + sqrt(__sqr(__x) + _Tp(1)));
   return std::complex<_Tp>(copysign(__z.real(), __x.real()),
                            copysign(__z.imag(), __x.imag()));
 }

 // acosh

 template <class _Tp>
 __DEVICE__ std::complex<_Tp> acosh(const std::complex<_Tp> &__x) {
   const _Tp __pi(atan2(+0., -0.));
   if (std::isinf(__x.real())) {
     if (std::isnan(__x.imag()))
       return std::complex<_Tp>(abs(__x.real()), __x.imag());
     if (std::isinf(__x.imag())) {
       if (__x.real() > 0)
         return std::complex<_Tp>(__x.real(),
                                  copysign(__pi * _Tp(0.25), __x.imag()));
       else
         return std::complex<_Tp>(-__x.real(),
                                  copysign(__pi * _Tp(0.75), __x.imag()));
     }
     if (__x.real() < 0)
       return std::complex<_Tp>(-__x.real(), copysign(__pi, __x.imag()));
     return std::complex<_Tp>(__x.real(), copysign(_Tp(0), __x.imag()));
   }
   if (std::isnan(__x.real())) {
     if (std::isinf(__x.imag()))
       return std::complex<_Tp>(abs(__x.imag()), __x.real());
     return std::complex<_Tp>(__x.real(), __x.real());
   }
   if (std::isinf(__x.imag()))
     return std::complex<_Tp>(abs(__x.imag()),
                              copysign(__pi / _Tp(2), __x.imag()));
   std::complex<_Tp> __z = log(__x + sqrt(__sqr(__x) - _Tp(1)));
   return std::complex<_Tp>(copysign(__z.real(), _Tp(0)),
                            copysign(__z.imag(), __x.imag()));
 }

 // atanh

 template <class _Tp>
 __DEVICE__ std::complex<_Tp> atanh(const std::complex<_Tp> &__x) {
   const _Tp __pi(atan2(+0., -0.));
   if (std::isinf(__x.imag())) {
     return std::complex<_Tp>(copysign(_Tp(0), __x.real()),
                              copysign(__pi / _Tp(2), __x.imag()));
   }
   if (std::isnan(__x.imag())) {
     if (std::isinf(__x.real()) || __x.real() == 0)
       return std::complex<_Tp>(copysign(_Tp(0), __x.real()), __x.imag());
     return std::complex<_Tp>(__x.imag(), __x.imag());
   }
   if (std::isnan(__x.real())) {
     return std::complex<_Tp>(__x.real(), __x.real());
   }
   if (std::isinf(__x.real())) {
     return std::complex<_Tp>(copysign(_Tp(0), __x.real()),
                              copysign(__pi / _Tp(2), __x.imag()));
   }
   if (abs(__x.real()) == _Tp(1) && __x.imag() == _Tp(0)) {
     return std::complex<_Tp>(copysign(_Tp(INFINITY), __x.real()),
                              copysign(_Tp(0), __x.imag()));
   }
   std::complex<_Tp> __z = log((_Tp(1) + __x) / (_Tp(1) - __x)) / _Tp(2);
   return std::complex<_Tp>(copysign(__z.real(), __x.real()),
                            copysign(__z.imag(), __x.imag()));
 }

 // sinh

 template <class _Tp>
 __DEVICE__ std::complex<_Tp> sinh(const std::complex<_Tp> &__x) {
   if (std::isinf(__x.real()) && !std::isfinite(__x.imag()))
     return std::complex<_Tp>(__x.real(), _Tp(NAN));
   if (__x.real() == 0 && !std::isfinite(__x.imag()))
     return std::complex<_Tp>(__x.real(), _Tp(NAN));
   if (__x.imag() == 0 && !std::isfinite(__x.real()))
     return __x;
   return std::complex<_Tp>(sinh(__x.real()) * cos(__x.imag()),
                            cosh(__x.real()) * sin(__x.imag()));
 }

 // cosh

 template <class _Tp>
 __DEVICE__ std::complex<_Tp> cosh(const std::complex<_Tp> &__x) {
   if (std::isinf(__x.real()) && !std::isfinite(__x.imag()))
     return std::complex<_Tp>(abs(__x.real()), _Tp(NAN));
   if (__x.real() == 0 && !std::isfinite(__x.imag()))
     return std::complex<_Tp>(_Tp(NAN), __x.real());
   if (__x.real() == 0 && __x.imag() == 0)
     return std::complex<_Tp>(_Tp(1), __x.imag());
   if (__x.imag() == 0 && !std::isfinite(__x.real()))
     return std::complex<_Tp>(abs(__x.real()), __x.imag());
   return std::complex<_Tp>(cosh(__x.real()) * cos(__x.imag()),
                            sinh(__x.real()) * sin(__x.imag()));
 }

 // tanh

 template <class _Tp>
 __DEVICE__ std::complex<_Tp> tanh(const std::complex<_Tp> &__x) {
   if (std::isinf(__x.real())) {
     if (!std::isfinite(__x.imag()))
       return std::complex<_Tp>(_Tp(1), _Tp(0));
     return std::complex<_Tp>(_Tp(1),
                              copysign(_Tp(0), sin(_Tp(2) * __x.imag())));
   }
   if (std::isnan(__x.real()) && __x.imag() == 0)
     return __x;
   _Tp __2r(_Tp(2) * __x.real());
   _Tp __2i(_Tp(2) * __x.imag());
   _Tp __d(cosh(__2r) + cos(__2i));
   _Tp __2rsh(sinh(__2r));
   if (std::isinf(__2rsh) && std::isinf(__d))
     return std::complex<_Tp>(__2rsh > _Tp(0) ? _Tp(1) : _Tp(-1),
                              __2i > _Tp(0) ? _Tp(0) : _Tp(-0.));
   return std::complex<_Tp>(__2rsh / __d, sin(__2i) / __d);
 }

 // asin

 template <class _Tp>
 __DEVICE__ std::complex<_Tp> asin(const std::complex<_Tp> &__x) {
   std::complex<_Tp> __z = asinh(complex<_Tp>(-__x.imag(), __x.real()));
   return std::complex<_Tp>(__z.imag(), -__z.real());
 }

 // acos

 template <class _Tp>
 __DEVICE__ std::complex<_Tp> acos(const std::complex<_Tp> &__x) {
   const _Tp __pi(atan2(+0., -0.));
   if (std::isinf(__x.real())) {
     if (std::isnan(__x.imag()))
       return std::complex<_Tp>(__x.imag(), __x.real());
     if (std::isinf(__x.imag())) {
       if (__x.real() < _Tp(0))
         return std::complex<_Tp>(_Tp(0.75) * __pi, -__x.imag());
       return std::complex<_Tp>(_Tp(0.25) * __pi, -__x.imag());
     }
     if (__x.real() < _Tp(0))
       return std::complex<_Tp>(__pi,
                                signbit(__x.imag()) ? -__x.real() : __x.real());
     return std::complex<_Tp>(_Tp(0),
                              signbit(__x.imag()) ? __x.real() : -__x.real());
   }
   if (std::isnan(__x.real())) {
     if (std::isinf(__x.imag()))
       return std::complex<_Tp>(__x.real(), -__x.imag());
     return std::complex<_Tp>(__x.real(), __x.real());
   }
   if (std::isinf(__x.imag()))
     return std::complex<_Tp>(__pi / _Tp(2), -__x.imag());
   if (__x.real() == 0 && (__x.imag() == 0 || isnan(__x.imag())))
     return std::complex<_Tp>(__pi / _Tp(2), -__x.imag());
   std::complex<_Tp> __z = log(__x + sqrt(__sqr(__x) - _Tp(1)));
   if (signbit(__x.imag()))
     return std::complex<_Tp>(abs(__z.imag()), abs(__z.real()));
   return std::complex<_Tp>(abs(__z.imag()), -abs(__z.real()));
 }

 // atan

 template <class _Tp>
 __DEVICE__ std::complex<_Tp> atan(const std::complex<_Tp> &__x) {
   std::complex<_Tp> __z = atanh(complex<_Tp>(-__x.imag(), __x.real()));
   return std::complex<_Tp>(__z.imag(), -__z.real());
 }

 // sin

 template <class _Tp>
 __DEVICE__ std::complex<_Tp> sin(const std::complex<_Tp> &__x) {
   std::complex<_Tp> __z = sinh(complex<_Tp>(-__x.imag(), __x.real()));
   return std::complex<_Tp>(__z.imag(), -__z.real());
 }

 // cos

 template <class _Tp> std::complex<_Tp> cos(const std::complex<_Tp> &__x) {
   return cosh(complex<_Tp>(-__x.imag(), __x.real()));
 }

 // tan

 template <class _Tp>
 __DEVICE__ std::complex<_Tp> tan(const std::complex<_Tp> &__x) {
   std::complex<_Tp> __z = tanh(complex<_Tp>(-__x.imag(), __x.real()));
   return std::complex<_Tp>(__z.imag(), -__z.real());
 }

 } // namespace std

 #endif
	//===------------------------- __complex_cmath.h --------------------------===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//
	//
	// std::complex header copied from the libcxx source and simplified for use in
	// OpenMP target offload regions.
	//
	//===----------------------------------------------------------------------===//

	#ifndef _OPENMP
	#error "This file is for OpenMP compilation only."
	#endif

	#ifndef __cplusplus
	#error "This file is for C++ compilation only."
	#endif

	#ifndef _LIBCPP_COMPLEX
	#define _LIBCPP_COMPLEX

	#include <cmath>
	#include <type_traits>

	#define __DEVICE__ static constexpr __attribute__((nothrow))

	namespace std {

	// abs

	template <class _Tp> __DEVICE__ _Tp abs(const std::complex<_Tp> &__c) {
	return hypot(__c.real(), __c.imag());
	}

	// arg

	template <class _Tp> __DEVICE__ _Tp arg(const std::complex<_Tp> &__c) {
	return atan2(__c.imag(), __c.real());
	}

	template <class _Tp>
	typename enable_if<is_integral<_Tp>::value \|\| is_same<_Tp, double>::value,
	double>::type
	arg(_Tp __re) {
	return atan2(0., __re);
	}

	template <class _Tp>
	typename enable_if<is_same<_Tp, float>::value, float>::type arg(_Tp __re) {
	return atan2f(0.F, __re);
	}

	// norm

	template <class _Tp> __DEVICE__ _Tp norm(const std::complex<_Tp> &__c) {
	if (std::isinf(__c.real()))
	return abs(__c.real());
	if (std::isinf(__c.imag()))
	return abs(__c.imag());
	return __c.real() * __c.real() + __c.imag() * __c.imag();
	}

	// conj

	template <class _Tp> std::complex<_Tp> conj(const std::complex<_Tp> &__c) {
	return std::complex<_Tp>(__c.real(), -__c.imag());
	}

	// proj

	template <class _Tp> std::complex<_Tp> proj(const std::complex<_Tp> &__c) {
	std::complex<_Tp> __r = __c;
	if (std::isinf(__c.real()) \|\| std::isinf(__c.imag()))
	__r = std::complex<_Tp>(INFINITY, copysign(_Tp(0), __c.imag()));
	return __r;
	}

	// polar

	template <class _Tp>
	complex<_Tp> polar(const _Tp &__rho, const _Tp &__theta = _Tp()) {
	if (std::isnan(__rho) \|\| signbit(__rho))
	return std::complex<_Tp>(_Tp(NAN), _Tp(NAN));
	if (std::isnan(__theta)) {
	if (std::isinf(__rho))
	return std::complex<_Tp>(__rho, __theta);
	return std::complex<_Tp>(__theta, __theta);
	}
	if (std::isinf(__theta)) {
	if (std::isinf(__rho))
	return std::complex<_Tp>(__rho, _Tp(NAN));
	return std::complex<_Tp>(_Tp(NAN), _Tp(NAN));
	}
	_Tp __x = __rho * cos(__theta);
	if (std::isnan(__x))
	__x = 0;
	_Tp __y = __rho * sin(__theta);
	if (std::isnan(__y))
	__y = 0;
	return std::complex<_Tp>(__x, __y);
	}

	// log

	template <class _Tp> std::complex<_Tp> log(const std::complex<_Tp> &__x) {
	return std::complex<_Tp>(log(abs(__x)), arg(__x));
	}

	// log10

	template <class _Tp> std::complex<_Tp> log10(const std::complex<_Tp> &__x) {
	return log(__x) / log(_Tp(10));
	}

	// sqrt

	template <class _Tp>
	__DEVICE__ std::complex<_Tp> sqrt(const std::complex<_Tp> &__x) {
	if (std::isinf(__x.imag()))
	return std::complex<_Tp>(_Tp(INFINITY), __x.imag());
	if (std::isinf(__x.real())) {
	if (__x.real() > _Tp(0))
	return std::complex<_Tp>(__x.real(), std::isnan(__x.imag())
	? __x.imag()
	: copysign(_Tp(0), __x.imag()));
	return std::complex<_Tp>(std::isnan(__x.imag()) ? __x.imag() : _Tp(0),
	copysign(__x.real(), __x.imag()));
	}
	return polar(sqrt(abs(__x)), arg(__x) / _Tp(2));
	}

	// exp

	template <class _Tp>
	__DEVICE__ std::complex<_Tp> exp(const std::complex<_Tp> &__x) {
	_Tp __i = __x.imag();
	if (std::isinf(__x.real())) {
	if (__x.real() < _Tp(0)) {
	if (!std::isfinite(__i))
	__i = _Tp(1);
	} else if (__i == 0 \|\| !std::isfinite(__i)) {
	if (std::isinf(__i))
	__i = _Tp(NAN);
	return std::complex<_Tp>(__x.real(), __i);
	}
	} else if (std::isnan(__x.real()) && __x.imag() == 0)
	return __x;
	_Tp __e = exp(__x.real());
	return std::complex<_Tp>(__e * cos(__i), __e * sin(__i));
	}

	// pow

	template <class _Tp>
	std::complex<_Tp> pow(const std::complex<_Tp> &__x,
	const std::complex<_Tp> &__y) {
	return exp(__y * log(__x));
	}

	// __sqr, computes pow(x, 2)

	template <class _Tp> std::complex<_Tp> __sqr(const std::complex<_Tp> &__x) {
	return std::complex<_Tp>((__x.real() - __x.imag()) *
	(__x.real() + __x.imag()),
	_Tp(2) * __x.real() * __x.imag());
	}

	// asinh

	template <class _Tp>
	__DEVICE__ std::complex<_Tp> asinh(const std::complex<_Tp> &__x) {
	const _Tp __pi(atan2(+0., -0.));
	if (std::isinf(__x.real())) {
	if (std::isnan(__x.imag()))
	return __x;
	if (std::isinf(__x.imag()))
	return std::complex<_Tp>(__x.real(),
	copysign(__pi * _Tp(0.25), __x.imag()));
	return std::complex<_Tp>(__x.real(), copysign(_Tp(0), __x.imag()));
	}
	if (std::isnan(__x.real())) {
	if (std::isinf(__x.imag()))
	return std::complex<_Tp>(__x.imag(), __x.real());
	if (__x.imag() == 0)
	return __x;
	return std::complex<_Tp>(__x.real(), __x.real());
	}
	if (std::isinf(__x.imag()))
	return std::complex<_Tp>(copysign(__x.imag(), __x.real()),
	copysign(__pi / _Tp(2), __x.imag()));
	std::complex<_Tp> __z = log(__x + sqrt(__sqr(__x) + _Tp(1)));
	return std::complex<_Tp>(copysign(__z.real(), __x.real()),
	copysign(__z.imag(), __x.imag()));
	}

	// acosh

	template <class _Tp>
	__DEVICE__ std::complex<_Tp> acosh(const std::complex<_Tp> &__x) {
	const _Tp __pi(atan2(+0., -0.));
	if (std::isinf(__x.real())) {
	if (std::isnan(__x.imag()))
	return std::complex<_Tp>(abs(__x.real()), __x.imag());
	if (std::isinf(__x.imag())) {
	if (__x.real() > 0)
	return std::complex<_Tp>(__x.real(),
	copysign(__pi * _Tp(0.25), __x.imag()));
	else
	return std::complex<_Tp>(-__x.real(),
	copysign(__pi * _Tp(0.75), __x.imag()));
	}
	if (__x.real() < 0)
	return std::complex<_Tp>(-__x.real(), copysign(__pi, __x.imag()));
	return std::complex<_Tp>(__x.real(), copysign(_Tp(0), __x.imag()));
	}
	if (std::isnan(__x.real())) {
	if (std::isinf(__x.imag()))
	return std::complex<_Tp>(abs(__x.imag()), __x.real());
	return std::complex<_Tp>(__x.real(), __x.real());
	}
	if (std::isinf(__x.imag()))
	return std::complex<_Tp>(abs(__x.imag()),
	copysign(__pi / _Tp(2), __x.imag()));
	std::complex<_Tp> __z = log(__x + sqrt(__sqr(__x) - _Tp(1)));
	return std::complex<_Tp>(copysign(__z.real(), _Tp(0)),
	copysign(__z.imag(), __x.imag()));
	}

	// atanh

	template <class _Tp>
	__DEVICE__ std::complex<_Tp> atanh(const std::complex<_Tp> &__x) {
	const _Tp __pi(atan2(+0., -0.));
	if (std::isinf(__x.imag())) {
	return std::complex<_Tp>(copysign(_Tp(0), __x.real()),
	copysign(__pi / _Tp(2), __x.imag()));
	}
	if (std::isnan(__x.imag())) {
	if (std::isinf(__x.real()) \|\| __x.real() == 0)
	return std::complex<_Tp>(copysign(_Tp(0), __x.real()), __x.imag());
	return std::complex<_Tp>(__x.imag(), __x.imag());
	}
	if (std::isnan(__x.real())) {
	return std::complex<_Tp>(__x.real(), __x.real());
	}
	if (std::isinf(__x.real())) {
	return std::complex<_Tp>(copysign(_Tp(0), __x.real()),
	copysign(__pi / _Tp(2), __x.imag()));
	}
	if (abs(__x.real()) == _Tp(1) && __x.imag() == _Tp(0)) {
	return std::complex<_Tp>(copysign(_Tp(INFINITY), __x.real()),
	copysign(_Tp(0), __x.imag()));
	}
	std::complex<_Tp> __z = log((_Tp(1) + __x) / (_Tp(1) - __x)) / _Tp(2);
	return std::complex<_Tp>(copysign(__z.real(), __x.real()),
	copysign(__z.imag(), __x.imag()));
	}

	// sinh

	template <class _Tp>
	__DEVICE__ std::complex<_Tp> sinh(const std::complex<_Tp> &__x) {
	if (std::isinf(__x.real()) && !std::isfinite(__x.imag()))
	return std::complex<_Tp>(__x.real(), _Tp(NAN));
	if (__x.real() == 0 && !std::isfinite(__x.imag()))
	return std::complex<_Tp>(__x.real(), _Tp(NAN));
	if (__x.imag() == 0 && !std::isfinite(__x.real()))
	return __x;
	return std::complex<_Tp>(sinh(__x.real()) * cos(__x.imag()),
	cosh(__x.real()) * sin(__x.imag()));
	}

	// cosh

	template <class _Tp>
	__DEVICE__ std::complex<_Tp> cosh(const std::complex<_Tp> &__x) {
	if (std::isinf(__x.real()) && !std::isfinite(__x.imag()))
	return std::complex<_Tp>(abs(__x.real()), _Tp(NAN));
	if (__x.real() == 0 && !std::isfinite(__x.imag()))
	return std::complex<_Tp>(_Tp(NAN), __x.real());
	if (__x.real() == 0 && __x.imag() == 0)
	return std::complex<_Tp>(_Tp(1), __x.imag());
	if (__x.imag() == 0 && !std::isfinite(__x.real()))
	return std::complex<_Tp>(abs(__x.real()), __x.imag());
	return std::complex<_Tp>(cosh(__x.real()) * cos(__x.imag()),
	sinh(__x.real()) * sin(__x.imag()));
	}

	// tanh

	template <class _Tp>
	__DEVICE__ std::complex<_Tp> tanh(const std::complex<_Tp> &__x) {
	if (std::isinf(__x.real())) {
	if (!std::isfinite(__x.imag()))
	return std::complex<_Tp>(_Tp(1), _Tp(0));
	return std::complex<_Tp>(_Tp(1),
	copysign(_Tp(0), sin(_Tp(2) * __x.imag())));
	}
	if (std::isnan(__x.real()) && __x.imag() == 0)
	return __x;
	_Tp __2r(_Tp(2) * __x.real());
	_Tp __2i(_Tp(2) * __x.imag());
	_Tp __d(cosh(__2r) + cos(__2i));
	_Tp __2rsh(sinh(__2r));
	if (std::isinf(__2rsh) && std::isinf(__d))
	return std::complex<_Tp>(__2rsh > _Tp(0) ? _Tp(1) : _Tp(-1),
	__2i > _Tp(0) ? _Tp(0) : _Tp(-0.));
	return std::complex<_Tp>(__2rsh / __d, sin(__2i) / __d);
	}

	// asin

	template <class _Tp>
	__DEVICE__ std::complex<_Tp> asin(const std::complex<_Tp> &__x) {
	std::complex<_Tp> __z = asinh(complex<_Tp>(-__x.imag(), __x.real()));
	return std::complex<_Tp>(__z.imag(), -__z.real());
	}

	// acos

	template <class _Tp>
	__DEVICE__ std::complex<_Tp> acos(const std::complex<_Tp> &__x) {
	const _Tp __pi(atan2(+0., -0.));
	if (std::isinf(__x.real())) {
	if (std::isnan(__x.imag()))
	return std::complex<_Tp>(__x.imag(), __x.real());
	if (std::isinf(__x.imag())) {
	if (__x.real() < _Tp(0))
	return std::complex<_Tp>(_Tp(0.75) * __pi, -__x.imag());
	return std::complex<_Tp>(_Tp(0.25) * __pi, -__x.imag());
	}
	if (__x.real() < _Tp(0))
	return std::complex<_Tp>(__pi,
	signbit(__x.imag()) ? -__x.real() : __x.real());
	return std::complex<_Tp>(_Tp(0),
	signbit(__x.imag()) ? __x.real() : -__x.real());
	}
	if (std::isnan(__x.real())) {
	if (std::isinf(__x.imag()))
	return std::complex<_Tp>(__x.real(), -__x.imag());
	return std::complex<_Tp>(__x.real(), __x.real());
	}
	if (std::isinf(__x.imag()))
	return std::complex<_Tp>(__pi / _Tp(2), -__x.imag());
	if (__x.real() == 0 && (__x.imag() == 0 \|\| isnan(__x.imag())))
	return std::complex<_Tp>(__pi / _Tp(2), -__x.imag());
	std::complex<_Tp> __z = log(__x + sqrt(__sqr(__x) - _Tp(1)));
	if (signbit(__x.imag()))
	return std::complex<_Tp>(abs(__z.imag()), abs(__z.real()));
	return std::complex<_Tp>(abs(__z.imag()), -abs(__z.real()));
	}

	// atan

	template <class _Tp>
	__DEVICE__ std::complex<_Tp> atan(const std::complex<_Tp> &__x) {
	std::complex<_Tp> __z = atanh(complex<_Tp>(-__x.imag(), __x.real()));
	return std::complex<_Tp>(__z.imag(), -__z.real());
	}

	// sin

	template <class _Tp>
	__DEVICE__ std::complex<_Tp> sin(const std::complex<_Tp> &__x) {
	std::complex<_Tp> __z = sinh(complex<_Tp>(-__x.imag(), __x.real()));
	return std::complex<_Tp>(__z.imag(), -__z.real());
	}

	// cos

	template <class _Tp> std::complex<_Tp> cos(const std::complex<_Tp> &__x) {
	return cosh(complex<_Tp>(-__x.imag(), __x.real()));
	}

	// tan

	template <class _Tp>
	__DEVICE__ std::complex<_Tp> tan(const std::complex<_Tp> &__x) {
	std::complex<_Tp> __z = tanh(complex<_Tp>(-__x.imag(), __x.real()));
	return std::complex<_Tp>(__z.imag(), -__z.real());
	}

	} // namespace std

	#endif