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/**
* @file v4math.h
* @brief LLVector4 class header file.
*
* $LicenseInfo:firstyear=2000&license=viewergpl$
*
* Copyright (c) 2000-2007, Linden Research, Inc.
*
* Second Life Viewer Source Code
* The source code in this file ("Source Code") is provided by Linden Lab
* to you under the terms of the GNU General Public License, version 2.0
* ("GPL"), unless you have obtained a separate licensing agreement
* ("Other License"), formally executed by you and Linden Lab. Terms of
* the GPL can be found in doc/GPL-license.txt in this distribution, or
* online at http://secondlife.com/developers/opensource/gplv2
*
* There are special exceptions to the terms and conditions of the GPL as
* it is applied to this Source Code. View the full text of the exception
* in the file doc/FLOSS-exception.txt in this software distribution, or
* online at http://secondlife.com/developers/opensource/flossexception
*
* By copying, modifying or distributing this software, you acknowledge
* that you have read and understood your obligations described above,
* and agree to abide by those obligations.
*
* ALL LINDEN LAB SOURCE CODE IS PROVIDED "AS IS." LINDEN LAB MAKES NO
* WARRANTIES, EXPRESS, IMPLIED OR OTHERWISE, REGARDING ITS ACCURACY,
* COMPLETENESS OR PERFORMANCE.
* $/LicenseInfo$
*/
#ifndef LL_V4MATH_H
#define LL_V4MATH_H
#include "llerror.h"
#include "llmath.h"
#include "v3math.h"
class LLMatrix3;
class LLMatrix4;
class LLQuaternion;
// LLVector4 = |x y z w|
static const U32 LENGTHOFVECTOR4 = 4;
class LLVector4
{
public:
F32 mV[LENGTHOFVECTOR4];
LLVector4(); // Initializes LLVector4 to (0, 0, 0, 1)
explicit LLVector4(const F32 *vec); // Initializes LLVector4 to (vec[0]. vec[1], vec[2], vec[3])
explicit LLVector4(const F64 *vec); // Initialized LLVector4 to ((F32) vec[0], (F32) vec[1], (F32) vec[3], (F32) vec[4]);
explicit LLVector4(const LLVector3 &vec); // Initializes LLVector4 to (vec, 1)
explicit LLVector4(const LLVector3 &vec, F32 w); // Initializes LLVector4 to (vec, w)
LLVector4(F32 x, F32 y, F32 z); // Initializes LLVector4 to (x. y, z, 1)
LLVector4(F32 x, F32 y, F32 z, F32 w);
LLSD getValue() const
{
LLSD ret;
ret[0] = mV[0];
ret[1] = mV[1];
ret[2] = mV[2];
ret[3] = mV[3];
return ret;
}
inline BOOL isFinite() const; // checks to see if all values of LLVector3 are finite
inline void clearVec(); // Clears LLVector4 to (0, 0, 0, 1)
inline void zeroVec(); // zero LLVector4 to (0, 0, 0, 0)
inline void setVec(F32 x, F32 y, F32 z); // Sets LLVector4 to (x, y, z, 1)
inline void setVec(F32 x, F32 y, F32 z, F32 w); // Sets LLVector4 to (x, y, z, w)
inline void setVec(const LLVector4 &vec); // Sets LLVector4 to vec
inline void setVec(const LLVector3 &vec, F32 w = 1.f); // Sets LLVector4 to LLVector3 vec
inline void setVec(const F32 *vec); // Sets LLVector4 to vec
F32 magVec() const; // Returns magnitude of LLVector4
F32 magVecSquared() const; // Returns magnitude squared of LLVector4
F32 normVec(); // Normalizes and returns the magnitude of LLVector4
// Sets all values to absolute value of their original values
// Returns TRUE if data changed
BOOL abs();
BOOL isExactlyClear() const { return (mV[VW] == 1.0f) && !mV[VX] && !mV[VY] && !mV[VZ]; }
BOOL isExactlyZero() const { return !mV[VW] && !mV[VX] && !mV[VY] && !mV[VZ]; }
const LLVector4& rotVec(F32 angle, const LLVector4 &vec); // Rotates about vec by angle radians
const LLVector4& rotVec(F32 angle, F32 x, F32 y, F32 z); // Rotates about x,y,z by angle radians
const LLVector4& rotVec(const LLMatrix4 &mat); // Rotates by MAT4 mat
const LLVector4& rotVec(const LLQuaternion &q); // Rotates by QUAT q
const LLVector4& scaleVec(const LLVector4& vec); // Scales component-wise by vec
F32 operator[](int idx) const { return mV[idx]; }
F32 &operator[](int idx) { return mV[idx]; }
friend std::ostream& operator<<(std::ostream& s, const LLVector4 &a); // Print a
friend LLVector4 operator+(const LLVector4 &a, const LLVector4 &b); // Return vector a + b
friend LLVector4 operator-(const LLVector4 &a, const LLVector4 &b); // Return vector a minus b
friend F32 operator*(const LLVector4 &a, const LLVector4 &b); // Return a dot b
friend LLVector4 operator%(const LLVector4 &a, const LLVector4 &b); // Return a cross b
friend LLVector4 operator/(const LLVector4 &a, F32 k); // Return a divided by scaler k
friend LLVector4 operator*(const LLVector4 &a, F32 k); // Return a times scaler k
friend LLVector4 operator*(F32 k, const LLVector4 &a); // Return a times scaler k
friend bool operator==(const LLVector4 &a, const LLVector4 &b); // Return a == b
friend bool operator!=(const LLVector4 &a, const LLVector4 &b); // Return a != b
friend const LLVector4& operator+=(LLVector4 &a, const LLVector4 &b); // Return vector a + b
friend const LLVector4& operator-=(LLVector4 &a, const LLVector4 &b); // Return vector a minus b
friend const LLVector4& operator%=(LLVector4 &a, const LLVector4 &b); // Return a cross b
friend const LLVector4& operator*=(LLVector4 &a, F32 k); // Return a times scaler k
friend const LLVector4& operator/=(LLVector4 &a, F32 k); // Return a divided by scaler k
friend LLVector4 operator-(const LLVector4 &a); // Return vector -a
};
// Non-member functions
F32 angle_between(const LLVector4 &a, const LLVector4 &b); // Returns angle (radians) between a and b
BOOL are_parallel(const LLVector4 &a, const LLVector4 &b, F32 epsilon=F_APPROXIMATELY_ZERO); // Returns TRUE if a and b are very close to parallel
F32 dist_vec(const LLVector4 &a, const LLVector4 &b); // Returns distance between a and b
F32 dist_vec_squared(const LLVector4 &a, const LLVector4 &b); // Returns distance squared between a and b
LLVector3 vec4to3(const LLVector4 &vec);
LLVector4 vec3to4(const LLVector3 &vec);
LLVector4 lerp(const LLVector4 &a, const LLVector4 &b, F32 u); // Returns a vector that is a linear interpolation between a and b
// Constructors
inline LLVector4::LLVector4(void)
{
mV[VX] = 0.f;
mV[VY] = 0.f;
mV[VZ] = 0.f;
mV[VW] = 1.f;
}
inline LLVector4::LLVector4(F32 x, F32 y, F32 z)
{
mV[VX] = x;
mV[VY] = y;
mV[VZ] = z;
mV[VW] = 1.f;
}
inline LLVector4::LLVector4(F32 x, F32 y, F32 z, F32 w)
{
mV[VX] = x;
mV[VY] = y;
mV[VZ] = z;
mV[VW] = w;
}
inline LLVector4::LLVector4(const F32 *vec)
{
mV[VX] = vec[VX];
mV[VY] = vec[VY];
mV[VZ] = vec[VZ];
mV[VW] = vec[VW];
}
inline LLVector4::LLVector4(const F64 *vec)
{
mV[VX] = (F32) vec[VX];
mV[VY] = (F32) vec[VY];
mV[VZ] = (F32) vec[VZ];
mV[VW] = (F32) vec[VW];
}
inline LLVector4::LLVector4(const LLVector3 &vec)
{
mV[VX] = vec.mV[VX];
mV[VY] = vec.mV[VY];
mV[VZ] = vec.mV[VZ];
mV[VW] = 1.f;
}
inline LLVector4::LLVector4(const LLVector3 &vec, F32 w)
{
mV[VX] = vec.mV[VX];
mV[VY] = vec.mV[VY];
mV[VZ] = vec.mV[VZ];
mV[VW] = w;
}
inline BOOL LLVector4::isFinite() const
{
return (llfinite(mV[VX]) && llfinite(mV[VY]) && llfinite(mV[VZ]) && llfinite(mV[VW]));
}
// Clear and Assignment Functions
inline void LLVector4::clearVec(void)
{
mV[VX] = 0.f;
mV[VY] = 0.f;
mV[VZ] = 0.f;
mV[VW] = 1.f;
}
inline void LLVector4::zeroVec(void)
{
mV[VX] = 0.f;
mV[VY] = 0.f;
mV[VZ] = 0.f;
mV[VW] = 0.f;
}
inline void LLVector4::setVec(F32 x, F32 y, F32 z)
{
mV[VX] = x;
mV[VY] = y;
mV[VZ] = z;
mV[VW] = 1.f;
}
inline void LLVector4::setVec(F32 x, F32 y, F32 z, F32 w)
{
mV[VX] = x;
mV[VY] = y;
mV[VZ] = z;
mV[VW] = w;
}
inline void LLVector4::setVec(const LLVector4 &vec)
{
mV[VX] = vec.mV[VX];
mV[VY] = vec.mV[VY];
mV[VZ] = vec.mV[VZ];
mV[VW] = vec.mV[VW];
}
inline void LLVector4::setVec(const LLVector3 &vec, F32 w)
{
mV[VX] = vec.mV[VX];
mV[VY] = vec.mV[VY];
mV[VZ] = vec.mV[VZ];
mV[VW] = w;
}
inline void LLVector4::setVec(const F32 *vec)
{
mV[VX] = vec[VX];
mV[VY] = vec[VY];
mV[VZ] = vec[VZ];
mV[VW] = vec[VW];
}
// LLVector4 Magnitude and Normalization Functions
inline F32 LLVector4::magVec(void) const
{
return fsqrtf(mV[VX]*mV[VX] + mV[VY]*mV[VY] + mV[VZ]*mV[VZ]);
}
inline F32 LLVector4::magVecSquared(void) const
{
return mV[VX]*mV[VX] + mV[VY]*mV[VY] + mV[VZ]*mV[VZ];
}
// LLVector4 Operators
inline LLVector4 operator+(const LLVector4 &a, const LLVector4 &b)
{
LLVector4 c(a);
return c += b;
}
inline LLVector4 operator-(const LLVector4 &a, const LLVector4 &b)
{
LLVector4 c(a);
return c -= b;
}
inline F32 operator*(const LLVector4 &a, const LLVector4 &b)
{
return (a.mV[VX]*b.mV[VX] + a.mV[VY]*b.mV[VY] + a.mV[VZ]*b.mV[VZ]);
}
inline LLVector4 operator%(const LLVector4 &a, const LLVector4 &b)
{
return LLVector4(a.mV[VY]*b.mV[VZ] - b.mV[VY]*a.mV[VZ], a.mV[VZ]*b.mV[VX] - b.mV[VZ]*a.mV[VX], a.mV[VX]*b.mV[VY] - b.mV[VX]*a.mV[VY]);
}
inline LLVector4 operator/(const LLVector4 &a, F32 k)
{
F32 t = 1.f / k;
return LLVector4( a.mV[VX] * t, a.mV[VY] * t, a.mV[VZ] * t );
}
inline LLVector4 operator*(const LLVector4 &a, F32 k)
{
return LLVector4( a.mV[VX] * k, a.mV[VY] * k, a.mV[VZ] * k );
}
inline LLVector4 operator*(F32 k, const LLVector4 &a)
{
return LLVector4( a.mV[VX] * k, a.mV[VY] * k, a.mV[VZ] * k );
}
inline bool operator==(const LLVector4 &a, const LLVector4 &b)
{
return ( (a.mV[VX] == b.mV[VX])
&&(a.mV[VY] == b.mV[VY])
&&(a.mV[VZ] == b.mV[VZ]));
}
inline bool operator!=(const LLVector4 &a, const LLVector4 &b)
{
return ( (a.mV[VX] != b.mV[VX])
||(a.mV[VY] != b.mV[VY])
||(a.mV[VZ] != b.mV[VZ]));
}
inline const LLVector4& operator+=(LLVector4 &a, const LLVector4 &b)
{
a.mV[VX] += b.mV[VX];
a.mV[VY] += b.mV[VY];
a.mV[VZ] += b.mV[VZ];
return a;
}
inline const LLVector4& operator-=(LLVector4 &a, const LLVector4 &b)
{
a.mV[VX] -= b.mV[VX];
a.mV[VY] -= b.mV[VY];
a.mV[VZ] -= b.mV[VZ];
return a;
}
inline const LLVector4& operator%=(LLVector4 &a, const LLVector4 &b)
{
LLVector4 ret(a.mV[VY]*b.mV[VZ] - b.mV[VY]*a.mV[VZ], a.mV[VZ]*b.mV[VX] - b.mV[VZ]*a.mV[VX], a.mV[VX]*b.mV[VY] - b.mV[VX]*a.mV[VY]);
a = ret;
return a;
}
inline const LLVector4& operator*=(LLVector4 &a, F32 k)
{
a.mV[VX] *= k;
a.mV[VY] *= k;
a.mV[VZ] *= k;
return a;
}
inline const LLVector4& operator/=(LLVector4 &a, F32 k)
{
F32 t = 1.f / k;
a.mV[VX] *= t;
a.mV[VY] *= t;
a.mV[VZ] *= t;
return a;
}
inline LLVector4 operator-(const LLVector4 &a)
{
return LLVector4( -a.mV[VX], -a.mV[VY], -a.mV[VZ] );
}
inline F32 dist_vec(const LLVector4 &a, const LLVector4 &b)
{
LLVector4 vec = a - b;
return (vec.magVec());
}
inline F32 dist_vec_squared(const LLVector4 &a, const LLVector4 &b)
{
LLVector4 vec = a - b;
return (vec.magVecSquared());
}
inline LLVector4 lerp(const LLVector4 &a, const LLVector4 &b, F32 u)
{
return LLVector4(
a.mV[VX] + (b.mV[VX] - a.mV[VX]) * u,
a.mV[VY] + (b.mV[VY] - a.mV[VY]) * u,
a.mV[VZ] + (b.mV[VZ] - a.mV[VZ]) * u,
a.mV[VW] + (b.mV[VW] - a.mV[VW]) * u);
}
inline F32 LLVector4::normVec(void)
{
F32 mag = fsqrtf(mV[VX]*mV[VX] + mV[VY]*mV[VY] + mV[VZ]*mV[VZ]);
F32 oomag;
if (mag > FP_MAG_THRESHOLD)
{
oomag = 1.f/mag;
mV[VX] *= oomag;
mV[VY] *= oomag;
mV[VZ] *= oomag;
}
else
{
mV[0] = 0.f;
mV[1] = 0.f;
mV[2] = 0.f;
mag = 0;
}
return (mag);
}
#endif
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