// xcomplex internal header #pragma once #ifndef _XCOMPLEX_ #define _XCOMPLEX_ // TEMPLATE FUNCTION imag _TMPLT(_Ty) inline _Ty __cdecl imag(const _CMPLX(_Ty)& _Left) { // return imaginary component return (_Left.imag()); } // TEMPLATE FUNCTION real _TMPLT(_Ty) inline _Ty __cdecl real(const _CMPLX(_Ty)& _Left) { // return real component return (_Left.real()); } // TEMPLATE FUNCTION _Fabs _TMPLT(_Ty) inline _Ty __cdecl _Fabs(const _CMPLX(_Ty)& _Left, int *_Pexp) { // return magnitude and scale factor *_Pexp = 0; _Ty _Av = real(_Left); _Ty _Bv = imag(_Left); if (_CTR(_Ty)::_Isinf(_Av) || _CTR(_Ty)::_Isinf(_Bv)) return (_CTR(_Ty)::_Infv(_Bv)); // at least one component is INF else if (_CTR(_Ty)::_Isnan(_Av)) return (_Av); // real component is NaN else if (_CTR(_Ty)::_Isnan(_Bv)) return (_Bv); // imaginary component is NaN else { // neither component is NaN or INF if (_Av < 0) _Av = -_Av; if (_Bv < 0) _Bv = -_Bv; if (_Av < _Bv) { // ensure that |_Bv| <= |_Av| _Ty _Tmp = _Av; _Av = _Bv; _Bv = _Tmp; } if (_Av == 0) return (_Av); // |0| == 0 if (1 <= _Av) *_Pexp = 2, _Av = _Av * (_Ty)0.25, _Bv = _Bv * (_Ty)0.25; else *_Pexp = -2, _Av = _Av * 4, _Bv = _Bv * 4; _Ty _Tmp = _Av - _Bv; if (_Tmp == _Av) return (_Av); // _Bv unimportant else if (_Bv < _Tmp) { // use simple approximation const _Ty _Qv = _Av / _Bv; return (_Av + _Bv / (_Qv + _CTR(_Ty)::sqrt(_Qv * _Qv + 1))); } else { // use 1 1/2 precision to preserve bits static const _Ty _Root2 = (_Ty)1.4142135623730950488016887242096981L; static const _Ty _Oneplusroot2high = (_Ty)2.4142L; static const _Ty _Oneplusroot2low = (_Ty)0.0000135623730950488016887242096980785697L; const _Ty _Qv = _Tmp / _Bv; const _Ty _Rv = (_Qv + 2) * _Qv; const _Ty _Sv = _Rv / (_Root2 + _CTR(_Ty)::sqrt(_Rv + 2)) + _Oneplusroot2low + _Qv + _Oneplusroot2high; return (_Av + _Bv / _Sv); } } } // TEMPLATE FUNCTION operator+ _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl operator+(const _CMPLX(_Ty)& _Left, const _CMPLX(_Ty)& _Right) { // add complex to complex _CMPLX(_Ty) _Tmp(_Left); return (_Tmp += _Right); } _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl operator+(const _CMPLX(_Ty)& _Left, const _Ty& _Right) { // add real to complex _CMPLX(_Ty) _Tmp(_Left); _Tmp.real(_Tmp.real() + _Right); return (_Tmp); } _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl operator+(const _Ty& _Left, const _CMPLX(_Ty)& _Right) { // add complex to real _CMPLX(_Ty) _Tmp(_Left); return (_Tmp += _Right); } // TEMPLATE FUNCTION operator- _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl operator-(const _CMPLX(_Ty)& _Left, const _CMPLX(_Ty)& _Right) { // subtract complex from complex _CMPLX(_Ty) _Tmp(_Left); return (_Tmp -= _Right); } _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl operator-(const _CMPLX(_Ty)& _Left, const _Ty& _Right) { // subtract real from complex _CMPLX(_Ty) _Tmp(_Left); _Tmp.real(_Tmp.real() - _Right); return (_Tmp); } _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl operator-(const _Ty& _Left, const _CMPLX(_Ty)& _Right) { // subtract complex from real _CMPLX(_Ty) _Tmp(_Left); return (_Tmp -= _Right); } // TEMPLATE FUNCTION operator* _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl operator*(const _CMPLX(_Ty)& _Left, const _CMPLX(_Ty)& _Right) { // multiply complex by complex _CMPLX(_Ty) _Tmp(_Left); return (_Tmp *= _Right); } _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl operator*(const _CMPLX(_Ty)& _Left, const _Ty& _Right) { // multiply complex by real _CMPLX(_Ty) _Tmp(_Left); _Tmp.real(_Tmp.real() * _Right); _Tmp.imag(_Tmp.imag() * _Right); return (_Tmp); } _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl operator*(const _Ty& _Left, const _CMPLX(_Ty)& _Right) { // multiply real by complex _CMPLX(_Ty) _Tmp(_Left); return (_Tmp *= _Right); } // TEMPLATE FUNCTION operator/ _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl operator/(const _CMPLX(_Ty)& _Left, const _CMPLX(_Ty)& _Right) { // divide complex by complex _CMPLX(_Ty) _Tmp(_Left); return (_Tmp /= _Right); } _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl operator/(const _CMPLX(_Ty)& _Left, const _Ty& _Right) { // divide complex by real _CMPLX(_Ty) _Tmp(_Left); _Tmp.real(_Tmp.real() / _Right); _Tmp.imag(_Tmp.imag() / _Right); return (_Tmp); } _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl operator/(const _Ty& _Left, const _CMPLX(_Ty)& _Right) { // divide real by complex _CMPLX(_Ty) _Tmp(_Left); return (_Tmp /= _Right); } // TEMPLATE FUNCTION UNARY operator+ _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl operator+(const _CMPLX(_Ty)& _Left) { // return +complex return (_CMPLX(_Ty)(_Left)); } // TEMPLATE FUNCTION UNARY operator- _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl operator-(const _CMPLX(_Ty)& _Left) { // return -complex return (_CMPLX(_Ty)(-real(_Left), -imag(_Left))); } // TEMPLATE FUNCTION operator== _TMPLT(_Ty) inline bool __cdecl operator==(const _CMPLX(_Ty)& _Left, const _CMPLX(_Ty)& _Right) { // test complex equal to complex return (real(_Left) == real(_Right) && imag(_Left) == imag(_Right)); } _TMPLT(_Ty) inline bool __cdecl operator==(const _CMPLX(_Ty)& _Left, const _Ty& _Right) { // test real equal to complex return (real(_Left) == _Right && imag(_Left) == 0); } _TMPLT(_Ty) inline bool __cdecl operator==(const _Ty& _Left, const _CMPLX(_Ty)& _Right) { // test complex equal to real return (_Left == real(_Right) && 0 == imag(_Right)); } // TEMPLATE FUNCTION operator!= _TMPLT(_Ty) inline bool __cdecl operator!=(const _CMPLX(_Ty)& _Left, const _CMPLX(_Ty)& _Right) { // test complex not equal to complex return (!(_Left == _Right)); } _TMPLT(_Ty) inline bool __cdecl operator!=(const _CMPLX(_Ty)& _Left, const _Ty& _Right) { // test real not equal to complex return (!(_Left == _Right)); } _TMPLT(_Ty) inline bool __cdecl operator!=(const _Ty& _Left, const _CMPLX(_Ty)& _Right) { // test complex not equal to real return (!(_Left == _Right)); } // TEMPLATE FUNCTION abs _TMPLT(_Ty) inline _Ty __cdecl abs(const _CMPLX(_Ty)& _Left) { // return |complex| as real int _Leftexp; _Ty _Rho = _Fabs(_Left, &_Leftexp); // get magnitude and scale factor if (_Leftexp == 0) return (_Rho); // no scale factor else return (_CTR(_Ty)::ldexp(_Rho, _Leftexp)); // scale result } // TEMPLATE FUNCTION arg _TMPLT(_Ty) inline _Ty __cdecl arg(const _CMPLX(_Ty)& _Left) { // return phase angle of complex as real return (_CTR(_Ty)::atan2(imag(_Left), real(_Left))); } // TEMPLATE FUNCTION conj _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl conj(const _CMPLX(_Ty)& _Left) { // return complex conjugate return (_CMPLX(_Ty)(real(_Left), -imag(_Left))); } // TEMPLATE FUNCTION cos _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl cos(const _CMPLX(_Ty)& _Left) { // return cos(complex) return (_CMPLX(_Ty)( _CTR(_Ty)::_Cosh(imag(_Left), _CTR(_Ty)::cos(real(_Left))), -_CTR(_Ty)::_Sinh(imag(_Left), _CTR(_Ty)::sin(real(_Left))))); } // TEMPLATE FUNCTION cosh _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl cosh(const _CMPLX(_Ty)& _Left) { // return cosh(complex) return (_CMPLX(_Ty)( _CTR(_Ty)::_Cosh(real(_Left), _CTR(_Ty)::cos(imag(_Left))), _CTR(_Ty)::_Sinh(real(_Left), _CTR(_Ty)::sin(imag(_Left))))); } // TEMPLATE FUNCTION exp _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl exp(const _CMPLX(_Ty)& _Left) { // return exp(complex) _Ty _Real(real(_Left)), _Imag(real(_Left)); _CTR(_Ty)::_Exp(&_Real, _CTR(_Ty)::cos(imag(_Left)), 0); _CTR(_Ty)::_Exp(&_Imag, _CTR(_Ty)::sin(imag(_Left)), 0); return (_CMPLX(_Ty)(_Real, _Imag)); } // TEMPLATE FUNCTION log _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl log(const _CMPLX(_Ty)& _Left) { // return log(complex) _Ty _Theta = _CTR(_Ty)::atan2(imag(_Left), real(_Left)); // get phase if (_CTR(_Ty)::_Isnan(_Theta)) return (_CMPLX(_Ty)(_Theta, _Theta)); // real or imag is NaN else { // use 1 1/2 precision to preserve bits static const _Ty _Cm = (_Ty)(22713.0L / 32768.0L); static const _Ty _Cl = (_Ty)1.4286068203094172321214581765680755e-6L; int _Leftexp; _Ty _Rho = _Fabs(_Left, &_Leftexp); // get magnitude and scale factor _Ty _Leftn = (_Ty)_Leftexp; _CMPLX(_Ty) _Tmp( _Rho == 0 ? -_CTR(_Ty)::_Infv(_Rho) // log(0) == -INF : _CTR(_Ty)::_Isinf(_Rho) ? _Rho // log(INF) == INF : _CTR(_Ty)::log(_Rho) + _Leftn * _Cl + _Leftn * _Cm, _Theta); return (_Tmp); } } // TEMPLATE FUNCTION log10 _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl log10(const _CMPLX(_Ty)& _Left) { // return log10(complex) return (log(_Left) * (_Ty)0.43429448190325182765112891891660508L); } // TEMPLATE FUNCTION norm _TMPLT(_Ty) inline _Ty __cdecl norm(const _CMPLX(_Ty)& _Left) { // return squared magnitude return (real(_Left) * real(_Left) + imag(_Left) * imag(_Left)); } // TEMPLATE FUNCTION polar _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl polar(const _Ty& _Rho, const _Ty& _Theta) { // return _Rho * exp(i * _Theta) as complex return (_CMPLX(_Ty)(_Rho * _CTR(_Ty)::cos(_Theta), _Rho * _CTR(_Ty)::sin(_Theta))); } _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl polar(const _Ty& _Rho) { // return _Rho * exp(i * 0) as complex return (_CMPLX(_Ty)(_Rho, (_Ty)0)); } // TEMPLATE FUNCTION pow _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl pow(const _CMPLX(_Ty)& _Left, const _Ty& _Right) { // return complex ^ real if (imag(_Left) == 0 && 0 <= real(_Left)) return (_CMPLX(_Ty)(_CTR(_Ty)::pow(real(_Left), _Right))); else return (exp(_Right * log(_Left))); } _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl pow(const _CMPLX(_Ty)& _Left, int _Right) { // return complex ^ integer _CMPLX(_Ty) _Tmp = _Left; unsigned int _Count = _Right; if (_Right < 0) _Count = 0 - _Count; // safe negation as unsigned for (_CMPLX(_Ty) _Zv = _CMPLX(_Ty)(1); ; _Tmp *= _Tmp) { // fold in _Left ^ (2 ^ _Count) as needed if ((_Count & 1) != 0) _Zv *= _Tmp; if ((_Count >>= 1) == 0) return (_Right < 0 ? _CMPLX(_Ty)(1) / _Zv : _Zv); } } _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl pow(const _Ty& _Left, const _CMPLX(_Ty)& _Right) { // return real ^ complex if (imag(_Right) == 0) return (_CMPLX(_Ty)(_CTR(_Ty)::pow(_Left, real(_Right)))); else return (exp(_Right * _CTR(_Ty)::log(_Left))); } _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl pow(const _CMPLX(_Ty)& _Left, const _CMPLX(_Ty)& _Right) { // return complex ^ complex if (imag(_Right) == 0) return (pow(_Left, real(_Right))); else if (imag(_Left) == 0) return (_CMPLX(_Ty)(pow(real(_Left), _Right))); else return (exp(_Right * log(_Left))); } // TEMPLATE FUNCTION sin _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl sin(const _CMPLX(_Ty)& _Left) { // return sin(complex) return (_CMPLX(_Ty)( _CTR(_Ty)::_Cosh(imag(_Left), _CTR(_Ty)::sin(real(_Left))), _CTR(_Ty)::_Sinh(imag(_Left), _CTR(_Ty)::cos(real(_Left))))); } // TEMPLATE FUNCTION sinh _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl sinh(const _CMPLX(_Ty)& _Left) { // return sinh(complex) return (_CMPLX(_Ty)( _CTR(_Ty)::_Sinh(real(_Left), _CTR(_Ty)::cos(imag(_Left))), _CTR(_Ty)::_Cosh(real(_Left), _CTR(_Ty)::sin(imag(_Left))))); } // TEMPLATE FUNCTION sqrt _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl sqrt(const _CMPLX(_Ty)& _Left) { // return sqrt(complex) int _Leftexp; _Ty _Rho = _Fabs(_Left, &_Leftexp); // get magnitude and scale factor if (_Leftexp == 0) return (_CMPLX(_Ty)(_Rho, _Rho)); // argument is zero, INF, or NaN else { // compute in safest quadrant _Ty _Realmag = _CTR(_Ty)::ldexp(real(_Left) < 0 ? - real(_Left) : real(_Left), -_Leftexp); _Rho = _CTR(_Ty)::ldexp(_CTR(_Ty)::sqrt( 2 * (_Realmag + _Rho)), _Leftexp / 2 - 1); if (0 <= real(_Left)) return (_CMPLX(_Ty)(_Rho, imag(_Left) / (2 * _Rho))); else if (imag(_Left) < 0) return (_CMPLX(_Ty)(-imag(_Left) / (2 * _Rho), -_Rho)); else return (_CMPLX(_Ty)(imag(_Left) / (2 * _Rho), _Rho)); } } // TEMPLATE FUNCTION tanh _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl tanh(const _CMPLX(_Ty)& _Left) { // return tanh(complex) _Ty _Tv = _CTR(_Ty)::tan(imag(_Left)); _Ty _Sv = _CTR(_Ty)::_Sinh(real(_Left), (_Ty)(1)); _Ty _Bv = _Sv *((_Ty)(1) + _Tv * _Tv); _Ty _Dv = (_Ty)(1) + _Bv * _Sv; return (_CMPLX(_Ty)((_CTR(_Ty)::sqrt((_Ty)(1) + _Sv * _Sv)) * _Bv / _Dv, _Tv / _Dv)); } // TEMPLATE FUNCTION tan _TMPLT(_Ty) inline _CMPLX(_Ty) __cdecl tan(const _CMPLX(_Ty)& _Left) { // return tan(complex) _CMPLX(_Ty) _Zv(tanh(_CMPLX(_Ty)(-imag(_Left), real(_Left)))); return (_CMPLX(_Ty)(imag(_Zv), -real(_Zv))); } #ifdef _DLL_CPPLIB #ifndef CRTDLL2 template _CRTIMP2 float __cdecl imag(const complex&); template _CRTIMP2 float __cdecl real(const complex&); template _CRTIMP2 float __cdecl _Fabs(const complex&, int *); template _CRTIMP2 complex __cdecl operator+(const complex&, const complex&); template _CRTIMP2 complex __cdecl operator+(const complex&, const float&); template _CRTIMP2 complex __cdecl operator+(const float&, const complex&); template _CRTIMP2 complex __cdecl operator-(const complex&, const complex&); template _CRTIMP2 complex __cdecl operator-(const complex&, const float&); template _CRTIMP2 complex __cdecl operator-(const float&, const complex&); template _CRTIMP2 complex __cdecl operator*(const complex&, const complex&); template _CRTIMP2 complex __cdecl operator*(const complex&, const float&); template _CRTIMP2 complex __cdecl operator*(const float&, const complex&); template _CRTIMP2 complex __cdecl operator/(const complex&, const complex&); template _CRTIMP2 complex __cdecl operator/(const complex&, const float&); template _CRTIMP2 complex __cdecl operator/(const float&, const complex&); template _CRTIMP2 complex __cdecl operator+(const complex&); template _CRTIMP2 complex __cdecl operator-(const complex&); template _CRTIMP2 bool __cdecl operator==(const complex&, const complex&); template _CRTIMP2 bool __cdecl operator==(const complex&, const float&); template _CRTIMP2 bool __cdecl operator==(const float&, const complex&); template _CRTIMP2 bool __cdecl operator!=(const complex&, const complex&); template _CRTIMP2 bool __cdecl operator!=(const complex&, const float&); template _CRTIMP2 bool __cdecl operator!=(const float&, const complex&); template _CRTIMP2 float __cdecl abs(const complex&); template _CRTIMP2 float __cdecl arg(const complex&); template _CRTIMP2 complex __cdecl conj(const complex&); template _CRTIMP2 complex __cdecl cos(const complex&); template _CRTIMP2 complex __cdecl cosh(const complex&); template _CRTIMP2 complex __cdecl exp(const complex&); template _CRTIMP2 complex __cdecl log(const complex&); template _CRTIMP2 complex __cdecl log10(const complex&); template _CRTIMP2 float __cdecl norm(const complex&); template _CRTIMP2 complex __cdecl polar(const float&, const float&); template _CRTIMP2 complex __cdecl polar(const float&); template _CRTIMP2 complex __cdecl pow(const complex&, const float&); template _CRTIMP2 complex __cdecl pow(const complex&, int); template _CRTIMP2 complex __cdecl pow(const float&, const complex&); template _CRTIMP2 complex __cdecl pow(const complex&, const complex&); template _CRTIMP2 complex __cdecl sin(const complex&); template _CRTIMP2 complex __cdecl sinh(const complex&); template _CRTIMP2 complex __cdecl sqrt(const complex&); template _CRTIMP2 complex __cdecl tanh(const complex&); template _CRTIMP2 complex __cdecl tan(const complex&); template _CRTIMP2 double __cdecl imag(const complex&); template _CRTIMP2 double __cdecl real(const complex&); template _CRTIMP2 double __cdecl _Fabs(const complex&, int *); template _CRTIMP2 complex __cdecl operator+(const complex&, const complex&); template _CRTIMP2 complex __cdecl operator+(const complex&, const double&); template _CRTIMP2 complex __cdecl operator+(const double&, const complex&); template _CRTIMP2 complex __cdecl operator-(const complex&, const complex&); template _CRTIMP2 complex __cdecl operator-(const complex&, const double&); template _CRTIMP2 complex __cdecl operator-(const double&, const complex&); template _CRTIMP2 complex __cdecl operator*(const complex&, const complex&); template _CRTIMP2 complex __cdecl operator*(const complex&, const double&); template _CRTIMP2 complex __cdecl operator*(const double&, const complex&); template _CRTIMP2 complex __cdecl operator/(const complex&, const complex&); template _CRTIMP2 complex __cdecl operator/(const complex&, const double&); template _CRTIMP2 complex __cdecl operator/(const double&, const complex&); template _CRTIMP2 complex __cdecl operator+(const complex&); template _CRTIMP2 complex __cdecl operator-(const complex&); template _CRTIMP2 bool __cdecl operator==(const complex&, const complex&); template _CRTIMP2 bool __cdecl operator==(const complex&, const double&); template _CRTIMP2 bool __cdecl operator==(const double&, const complex&); template _CRTIMP2 bool __cdecl operator!=(const complex&, const complex&); template _CRTIMP2 bool __cdecl operator!=(const complex&, const double&); template _CRTIMP2 bool __cdecl operator!=(const double&, const complex&); template _CRTIMP2 double __cdecl abs(const complex&); template _CRTIMP2 double __cdecl arg(const complex&); template _CRTIMP2 complex __cdecl conj(const complex&); template _CRTIMP2 complex __cdecl cos(const complex&); template _CRTIMP2 complex __cdecl cosh(const complex&); template _CRTIMP2 complex __cdecl exp(const complex&); template _CRTIMP2 complex __cdecl log(const complex&); template _CRTIMP2 complex __cdecl log10(const complex&); template _CRTIMP2 double __cdecl norm(const complex&); template _CRTIMP2 complex __cdecl polar(const double&, const double&); template _CRTIMP2 complex __cdecl polar(const double&); template _CRTIMP2 complex __cdecl pow(const complex&, const double&); template _CRTIMP2 complex __cdecl pow(const complex&, int); template _CRTIMP2 complex __cdecl pow(const double&, const complex&); template _CRTIMP2 complex __cdecl pow(const complex&, const complex&); template _CRTIMP2 complex __cdecl sin(const complex&); template _CRTIMP2 complex __cdecl sinh(const complex&); template _CRTIMP2 complex __cdecl sqrt(const complex&); template _CRTIMP2 complex __cdecl tanh(const complex&); template _CRTIMP2 complex __cdecl tan(const complex&); template _CRTIMP2 long double __cdecl imag(const complex&); template _CRTIMP2 long double __cdecl real(const complex&); template _CRTIMP2 long double __cdecl _Fabs(const complex&, int *); template _CRTIMP2 complex __cdecl operator+(const complex&, const complex&); template _CRTIMP2 complex __cdecl operator+(const complex&, const long double&); template _CRTIMP2 complex __cdecl operator+(const long double&, const complex&); template _CRTIMP2 complex __cdecl operator-(const complex&, const complex&); template _CRTIMP2 complex __cdecl operator-(const complex&, const long double&); template _CRTIMP2 complex __cdecl operator-(const long double&, const complex&); template _CRTIMP2 complex __cdecl operator*(const complex&, const complex&); template _CRTIMP2 complex __cdecl operator*(const complex&, const long double&); template _CRTIMP2 complex __cdecl operator*(const long double&, const complex&); template _CRTIMP2 complex __cdecl operator/(const complex&, const complex&); template _CRTIMP2 complex __cdecl operator/(const complex&, const long double&); template _CRTIMP2 complex __cdecl operator/(const long double&, const complex&); template _CRTIMP2 complex __cdecl operator+(const complex&); template _CRTIMP2 complex __cdecl operator-(const complex&); template _CRTIMP2 bool __cdecl operator==(const complex&, const complex&); template _CRTIMP2 bool __cdecl operator==(const complex&, const long double&); template _CRTIMP2 bool __cdecl operator==(const long double&, const complex&); template _CRTIMP2 bool __cdecl operator!=(const complex&, const complex&); template _CRTIMP2 bool __cdecl operator!=(const complex&, const long double&); template _CRTIMP2 bool __cdecl operator!=(const long double&, const complex&); template _CRTIMP2 long double __cdecl abs(const complex&); template _CRTIMP2 long double __cdecl arg(const complex&); template _CRTIMP2 complex __cdecl conj(const complex&); template _CRTIMP2 complex __cdecl cos(const complex&); template _CRTIMP2 complex __cdecl cosh(const complex&); template _CRTIMP2 complex __cdecl exp(const complex&); template _CRTIMP2 complex __cdecl log(const complex&); template _CRTIMP2 complex __cdecl log10(const complex&); template _CRTIMP2 long double __cdecl norm(const complex&); template _CRTIMP2 complex __cdecl polar(const long double&, const long double&); template _CRTIMP2 complex __cdecl polar(const long double&); template _CRTIMP2 complex __cdecl pow(const complex&, const long double&); template _CRTIMP2 complex __cdecl pow(const complex&, int); template _CRTIMP2 complex __cdecl pow(const long double&, const complex&); template _CRTIMP2 complex __cdecl pow(const complex&, const complex&); template _CRTIMP2 complex __cdecl sin(const complex&); template _CRTIMP2 complex __cdecl sinh(const complex&); template _CRTIMP2 complex __cdecl sqrt(const complex&); template _CRTIMP2 complex __cdecl tanh(const complex&); template _CRTIMP2 complex __cdecl tan(const complex&); #endif // CRTDLL2 #endif // _DLL_CPPLIB #undef _XCOMPLEX_ /* SIC: may be included multiple times */ #endif /* _XCOMPLEX_ */ /* * Copyright (c) 1992-2001 by P.J. Plauger. ALL RIGHTS RESERVED. * Consult your license regarding permissions and restrictions. V3.10:0009 */