pifcamp-2021/osc32_9255/RTIMULib/RTMath.h

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2022-05-27 14:57:30 +02:00
////////////////////////////////////////////////////////////////////////////
//
// This file is part of RTIMULib-Arduino
//
// Copyright (c) 2014-2015, richards-tech
//
// Permission is hereby granted, free of charge, to any person obtaining a copy of
// this software and associated documentation files (the "Software"), to deal in
// the Software without restriction, including without limitation the rights to use,
// copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the
// Software, and to permit persons to whom the Software is furnished to do so,
// subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in all
// copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED,
// INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A
// PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT
// HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
// OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
// SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
#ifndef _RTMATH_H_
#define _RTMATH_H_
#include <math.h>
#include <stdint.h>
// The fundamental float type
#ifdef RTMATH_USE_DOUBLE
typedef double RTFLOAT;
#else
typedef float RTFLOAT;
#endif
// Useful constants
#define RTMATH_PI 3.1415926535
#define RTMATH_DEGREE_TO_RAD (M_PI / 180.0)
#define RTMATH_RAD_TO_DEGREE (180.0 / M_PI)
class RTVector3;
#ifndef RTARDULINK_MODE
class RTQuaternion;
#endif
class RTMath
{
public:
#ifndef RTARDULINK_MODE
// convenient display routines
static void display(const char *label, RTVector3& vec);
static void displayDegrees(const char *label, RTVector3& vec);
static void displayRollPitchYaw(const char *label, RTVector3& vec);
static void display(const char *label, RTQuaternion& quat);
// poseFromAccelMag generates pose Euler angles from measured settings
static RTVector3 poseFromAccelMag(const RTVector3& accel, const RTVector3& mag);
// Takes signed 16 bit data from a char array and converts it to a vector of scaled RTFLOATs
static void convertToVector(unsigned char *rawData, RTVector3& vec, RTFLOAT scale, bool bigEndian);
#endif // #ifndef RTARDULINK_MODE
};
class RTVector3
{
public:
RTVector3();
RTVector3(RTFLOAT x, RTFLOAT y, RTFLOAT z);
const RTVector3& operator +=(RTVector3& vec);
const RTVector3& operator -=(RTVector3& vec);
RTVector3& operator =(const RTVector3& vec);
RTFLOAT squareLength();
void zero();
inline RTFLOAT x() const { return m_data[0]; }
inline RTFLOAT y() const { return m_data[1]; }
inline RTFLOAT z() const { return m_data[2]; }
inline RTFLOAT data(const int i) const { return m_data[i]; }
inline void setX(const RTFLOAT val) { m_data[0] = val; }
inline void setY(const RTFLOAT val) { m_data[1] = val; }
inline void setZ(const RTFLOAT val) { m_data[2] = val; }
inline void setData(const int i, RTFLOAT val) { m_data[i] = val; }
#ifndef RTARDULINK_MODE
RTFLOAT length();
void normalize();
const char *display();
const char *displayDegrees();
static RTFLOAT dotProduct(const RTVector3& a, const RTVector3& b);
static void crossProduct(const RTVector3& a, const RTVector3& b, RTVector3& d);
void accelToEuler(RTVector3& rollPitchYaw) const;
void accelToQuaternion(RTQuaternion& qPose) const;
#endif // #ifndef RTARDULINK_MODE
private:
RTFLOAT m_data[3];
};
#ifndef RTARDULINK_MODE
class RTQuaternion
{
public:
RTQuaternion();
RTQuaternion(RTFLOAT scalar, RTFLOAT x, RTFLOAT y, RTFLOAT z);
RTQuaternion& operator +=(const RTQuaternion& quat);
RTQuaternion& operator -=(const RTQuaternion& quat);
RTQuaternion& operator *=(const RTQuaternion& qb);
RTQuaternion& operator *=(const RTFLOAT val);
RTQuaternion& operator -=(const RTFLOAT val);
RTQuaternion& operator =(const RTQuaternion& quat);
const RTQuaternion operator *(const RTQuaternion& qb) const;
const RTQuaternion operator *(const RTFLOAT val) const;
const RTQuaternion operator -(const RTQuaternion& qb) const;
const RTQuaternion operator -(const RTFLOAT val) const;
void normalize();
void toEuler(RTVector3& vec);
void fromEuler(RTVector3& vec);
RTQuaternion conjugate() const;
void toAngleVector(RTFLOAT& angle, RTVector3& vec);
void fromAngleVector(const RTFLOAT& angle, const RTVector3& vec);
void zero();
const char *display();
inline RTFLOAT scalar() const { return m_data[0]; }
inline RTFLOAT x() const { return m_data[1]; }
inline RTFLOAT y() const { return m_data[2]; }
inline RTFLOAT z() const { return m_data[3]; }
inline RTFLOAT data(const int i) const { return m_data[i]; }
inline void setScalar(const RTFLOAT val) { m_data[0] = val; }
inline void setX(const RTFLOAT val) { m_data[1] = val; }
inline void setY(const RTFLOAT val) { m_data[2] = val; }
inline void setZ(const RTFLOAT val) { m_data[3] = val; }
inline void setData(const int i, RTFLOAT val) { m_data[i] = val; }
private:
RTFLOAT m_data[4];
};
#endif // #ifndef RTARDULINK_MODE
#endif /* _RTMATH_H_ */