doom3-bfg/neo/idlib/math/Complex.h

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/*
===========================================================================
Doom 3 BFG Edition GPL Source Code
Copyright (C) 1993-2012 id Software LLC, a ZeniMax Media company.
This file is part of the Doom 3 BFG Edition GPL Source Code ("Doom 3 BFG Edition Source Code").
Doom 3 BFG Edition Source Code is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
Doom 3 BFG Edition Source Code is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with Doom 3 BFG Edition Source Code. If not, see <http://www.gnu.org/licenses/>.
In addition, the Doom 3 BFG Edition Source Code is also subject to certain additional terms. You should have received a copy of these additional terms immediately following the terms and conditions of the GNU General Public License which accompanied the Doom 3 BFG Edition Source Code. If not, please request a copy in writing from id Software at the address below.
If you have questions concerning this license or the applicable additional terms, you may contact in writing id Software LLC, c/o ZeniMax Media Inc., Suite 120, Rockville, Maryland 20850 USA.
===========================================================================
*/
#ifndef __MATH_COMPLEX_H__
#define __MATH_COMPLEX_H__
/*
===============================================================================
Complex number
===============================================================================
*/
class idComplex {
public:
float r; // real part
float i; // imaginary part
idComplex();
idComplex( const float r, const float i );
void Set( const float r, const float i );
void Zero();
float operator[]( int index ) const;
float & operator[]( int index );
idComplex operator-() const;
idComplex & operator=( const idComplex &a );
idComplex operator*( const idComplex &a ) const;
idComplex operator/( const idComplex &a ) const;
idComplex operator+( const idComplex &a ) const;
idComplex operator-( const idComplex &a ) const;
idComplex & operator*=( const idComplex &a );
idComplex & operator/=( const idComplex &a );
idComplex & operator+=( const idComplex &a );
idComplex & operator-=( const idComplex &a );
idComplex operator*( const float a ) const;
idComplex operator/( const float a ) const;
idComplex operator+( const float a ) const;
idComplex operator-( const float a ) const;
idComplex & operator*=( const float a );
idComplex & operator/=( const float a );
idComplex & operator+=( const float a );
idComplex & operator-=( const float a );
friend idComplex operator*( const float a, const idComplex &b );
friend idComplex operator/( const float a, const idComplex &b );
friend idComplex operator+( const float a, const idComplex &b );
friend idComplex operator-( const float a, const idComplex &b );
bool Compare( const idComplex &a ) const; // exact compare, no epsilon
bool Compare( const idComplex &a, const float epsilon ) const; // compare with epsilon
bool operator==( const idComplex &a ) const; // exact compare, no epsilon
bool operator!=( const idComplex &a ) const; // exact compare, no epsilon
idComplex Reciprocal() const;
idComplex Sqrt() const;
float Abs() const;
int GetDimension() const;
const float * ToFloatPtr() const;
float * ToFloatPtr();
const char * ToString( int precision = 2 ) const;
};
extern idComplex complex_origin;
#define complex_zero complex_origin
ID_INLINE idComplex::idComplex() {
}
ID_INLINE idComplex::idComplex( const float r, const float i ) {
this->r = r;
this->i = i;
}
ID_INLINE void idComplex::Set( const float r, const float i ) {
this->r = r;
this->i = i;
}
ID_INLINE void idComplex::Zero() {
r = i = 0.0f;
}
ID_INLINE float idComplex::operator[]( int index ) const {
assert( index >= 0 && index < 2 );
return ( &r )[ index ];
}
ID_INLINE float& idComplex::operator[]( int index ) {
assert( index >= 0 && index < 2 );
return ( &r )[ index ];
}
ID_INLINE idComplex idComplex::operator-() const {
return idComplex( -r, -i );
}
ID_INLINE idComplex &idComplex::operator=( const idComplex &a ) {
r = a.r;
i = a.i;
return *this;
}
ID_INLINE idComplex idComplex::operator*( const idComplex &a ) const {
return idComplex( r * a.r - i * a.i, i * a.r + r * a.i );
}
ID_INLINE idComplex idComplex::operator/( const idComplex &a ) const {
float s, t;
if ( idMath::Fabs( a.r ) >= idMath::Fabs( a.i ) ) {
s = a.i / a.r;
t = 1.0f / ( a.r + s * a.i );
return idComplex( ( r + s * i ) * t, ( i - s * r ) * t );
} else {
s = a.r / a.i;
t = 1.0f / ( s * a.r + a.i );
return idComplex( ( r * s + i ) * t, ( i * s - r ) * t );
}
}
ID_INLINE idComplex idComplex::operator+( const idComplex &a ) const {
return idComplex( r + a.r, i + a.i );
}
ID_INLINE idComplex idComplex::operator-( const idComplex &a ) const {
return idComplex( r - a.r, i - a.i );
}
ID_INLINE idComplex &idComplex::operator*=( const idComplex &a ) {
*this = idComplex( r * a.r - i * a.i, i * a.r + r * a.i );
return *this;
}
ID_INLINE idComplex &idComplex::operator/=( const idComplex &a ) {
float s, t;
if ( idMath::Fabs( a.r ) >= idMath::Fabs( a.i ) ) {
s = a.i / a.r;
t = 1.0f / ( a.r + s * a.i );
*this = idComplex( ( r + s * i ) * t, ( i - s * r ) * t );
} else {
s = a.r / a.i;
t = 1.0f / ( s * a.r + a.i );
*this = idComplex( ( r * s + i ) * t, ( i * s - r ) * t );
}
return *this;
}
ID_INLINE idComplex &idComplex::operator+=( const idComplex &a ) {
r += a.r;
i += a.i;
return *this;
}
ID_INLINE idComplex &idComplex::operator-=( const idComplex &a ) {
r -= a.r;
i -= a.i;
return *this;
}
ID_INLINE idComplex idComplex::operator*( const float a ) const {
return idComplex( r * a, i * a );
}
ID_INLINE idComplex idComplex::operator/( const float a ) const {
float s = 1.0f / a;
return idComplex( r * s, i * s );
}
ID_INLINE idComplex idComplex::operator+( const float a ) const {
return idComplex( r + a, i );
}
ID_INLINE idComplex idComplex::operator-( const float a ) const {
return idComplex( r - a, i );
}
ID_INLINE idComplex &idComplex::operator*=( const float a ) {
r *= a;
i *= a;
return *this;
}
ID_INLINE idComplex &idComplex::operator/=( const float a ) {
float s = 1.0f / a;
r *= s;
i *= s;
return *this;
}
ID_INLINE idComplex &idComplex::operator+=( const float a ) {
r += a;
return *this;
}
ID_INLINE idComplex &idComplex::operator-=( const float a ) {
r -= a;
return *this;
}
ID_INLINE idComplex operator*( const float a, const idComplex &b ) {
return idComplex( a * b.r, a * b.i );
}
ID_INLINE idComplex operator/( const float a, const idComplex &b ) {
float s, t;
if ( idMath::Fabs( b.r ) >= idMath::Fabs( b.i ) ) {
s = b.i / b.r;
t = a / ( b.r + s * b.i );
return idComplex( t, - s * t );
} else {
s = b.r / b.i;
t = a / ( s * b.r + b.i );
return idComplex( s * t, - t );
}
}
ID_INLINE idComplex operator+( const float a, const idComplex &b ) {
return idComplex( a + b.r, b.i );
}
ID_INLINE idComplex operator-( const float a, const idComplex &b ) {
return idComplex( a - b.r, -b.i );
}
ID_INLINE idComplex idComplex::Reciprocal() const {
float s, t;
if ( idMath::Fabs( r ) >= idMath::Fabs( i ) ) {
s = i / r;
t = 1.0f / ( r + s * i );
return idComplex( t, - s * t );
} else {
s = r / i;
t = 1.0f / ( s * r + i );
return idComplex( s * t, - t );
}
}
ID_INLINE idComplex idComplex::Sqrt() const {
float x, y, w;
if ( r == 0.0f && i == 0.0f ) {
return idComplex( 0.0f, 0.0f );
}
x = idMath::Fabs( r );
y = idMath::Fabs( i );
if ( x >= y ) {
w = y / x;
w = idMath::Sqrt( x ) * idMath::Sqrt( 0.5f * ( 1.0f + idMath::Sqrt( 1.0f + w * w ) ) );
} else {
w = x / y;
w = idMath::Sqrt( y ) * idMath::Sqrt( 0.5f * ( w + idMath::Sqrt( 1.0f + w * w ) ) );
}
if ( w == 0.0f ) {
return idComplex( 0.0f, 0.0f );
}
if ( r >= 0.0f ) {
return idComplex( w, 0.5f * i / w );
} else {
return idComplex( 0.5f * y / w, ( i >= 0.0f ) ? w : -w );
}
}
ID_INLINE float idComplex::Abs() const {
float x, y, t;
x = idMath::Fabs( r );
y = idMath::Fabs( i );
if ( x == 0.0f ) {
return y;
} else if ( y == 0.0f ) {
return x;
} else if ( x > y ) {
t = y / x;
return x * idMath::Sqrt( 1.0f + t * t );
} else {
t = x / y;
return y * idMath::Sqrt( 1.0f + t * t );
}
}
ID_INLINE bool idComplex::Compare( const idComplex &a ) const {
return ( ( r == a.r ) && ( i == a.i ) );
}
ID_INLINE bool idComplex::Compare( const idComplex &a, const float epsilon ) const {
if ( idMath::Fabs( r - a.r ) > epsilon ) {
return false;
}
if ( idMath::Fabs( i - a.i ) > epsilon ) {
return false;
}
return true;
}
ID_INLINE bool idComplex::operator==( const idComplex &a ) const {
return Compare( a );
}
ID_INLINE bool idComplex::operator!=( const idComplex &a ) const {
return !Compare( a );
}
ID_INLINE int idComplex::GetDimension() const {
return 2;
}
ID_INLINE const float *idComplex::ToFloatPtr() const {
return &r;
}
ID_INLINE float *idComplex::ToFloatPtr() {
return &r;
}
#endif /* !__MATH_COMPLEX_H__ */