third_party/PowerVR_SDK/Tools/PVRTQuaternionF.cpp - SwiftShader - Git at Google

 /******************************************************************************

  @File         PVRTQuaternionF.cpp

  @Title        PVRTQuaternionF

  @Version

  @Copyright    Copyright (c) Imagination Technologies Limited.

  @Platform     ANSI compatible

  @Description  Set of mathematical functions for quaternions.

 ******************************************************************************/
 #include "PVRTGlobal.h"
 #include <math.h>
 #include <string.h>
 #include "PVRTFixedPoint.h"		// Only needed for trig function float lookups
 #include "PVRTQuaternion.h"


 /****************************************************************************
 ** Functions
 ****************************************************************************/

 /*!***************************************************************************
  @Function			PVRTMatrixQuaternionIdentityF
  @Output			qOut	Identity quaternion
  @Description		Sets the quaternion to (0, 0, 0, 1), the identity quaternion.
 *****************************************************************************/
 void PVRTMatrixQuaternionIdentityF(PVRTQUATERNIONf &qOut)
 {
 	qOut.x = 0;
 	qOut.y = 0;
 	qOut.z = 0;
 	qOut.w = 1;
 }

 /*!***************************************************************************
  @Function			PVRTMatrixQuaternionRotationAxisF
  @Output			qOut	Rotation quaternion
  @Input				vAxis	Axis to rotate around
  @Input				fAngle	Angle to rotate
  @Description		Create quaternion corresponding to a rotation of fAngle
 					radians around submitted vector.
 *****************************************************************************/
 void PVRTMatrixQuaternionRotationAxisF(
 	PVRTQUATERNIONf		&qOut,
 	const PVRTVECTOR3f	&vAxis,
 	const float			fAngle)
 {
 	float	fSin, fCos;

 	fSin = (float)PVRTFSIN(fAngle * 0.5f);
 	fCos = (float)PVRTFCOS(fAngle * 0.5f);

 	/* Create quaternion */
 	qOut.x = vAxis.x * fSin;
 	qOut.y = vAxis.y * fSin;
 	qOut.z = vAxis.z * fSin;
 	qOut.w = fCos;

 	/* Normalise it */
 	PVRTMatrixQuaternionNormalizeF(qOut);
 }

 /*!***************************************************************************
  @Function			PVRTMatrixQuaternionToAxisAngleF
  @Input				qIn		Quaternion to transform
  @Output			vAxis	Axis of rotation
  @Output			fAngle	Angle of rotation
  @Description		Convert a quaternion to an axis and angle. Expects a unit
 					quaternion.
 *****************************************************************************/
 void PVRTMatrixQuaternionToAxisAngleF(
 	const PVRTQUATERNIONf	&qIn,
 	PVRTVECTOR3f			&vAxis,
 	float					&fAngle)
 {
 	float	fCosAngle, fSinAngle;
 	double	temp;

 	/* Compute some values */
 	fCosAngle	= qIn.w;
 	temp		= 1.0f - fCosAngle*fCosAngle;
 	fAngle		= (float)PVRTFACOS(fCosAngle)*2.0f;
 	fSinAngle	= (float)sqrt(temp);

 	/* This is to avoid a division by zero */
 	if ((float)fabs(fSinAngle)<0.0005f)
 		fSinAngle = 1.0f;

 	/* Get axis vector */
 	vAxis.x = qIn.x / fSinAngle;
 	vAxis.y = qIn.y / fSinAngle;
 	vAxis.z = qIn.z / fSinAngle;
 }

 /*!***************************************************************************
  @Function			PVRTMatrixQuaternionSlerpF
  @Output			qOut	Result of the interpolation
  @Input				qA		First quaternion to interpolate from
  @Input				qB		Second quaternion to interpolate from
  @Input				t		Coefficient of interpolation
  @Description		Perform a Spherical Linear intERPolation between quaternion A
 					and quaternion B at time t. t must be between 0.0f and 1.0f
 *****************************************************************************/
 void PVRTMatrixQuaternionSlerpF(
 	PVRTQUATERNIONf			&qOut,
 	const PVRTQUATERNIONf	&qA,
 	const PVRTQUATERNIONf	&qB,
 	const float				t)
 {
 	float		fCosine, fAngle, A, B;

 	/* Parameter checking */
 	if (t<0.0f || t>1.0f)
 	{
 		_RPT0(_CRT_WARN, "PVRTMatrixQuaternionSlerp : Bad parameters\n");
 		qOut.x = 0;
 		qOut.y = 0;
 		qOut.z = 0;
 		qOut.w = 1;
 		return;
 	}

 	/* Find sine of Angle between Quaternion A and B (dot product between quaternion A and B) */
 	fCosine = qA.w*qB.w + qA.x*qB.x + qA.y*qB.y + qA.z*qB.z;

 	if (fCosine < 0)
 	{
 		PVRTQUATERNIONf qi;

 		/*
 			<http://www.magic-software.com/Documentation/Quaternions.pdf>

 			"It is important to note that the quaternions q and -q represent
 			the same rotation... while either quaternion will do, the
 			interpolation methods require choosing one over the other.

 			"Although q1 and -q1 represent the same rotation, the values of
 			Slerp(t; q0, q1) and Slerp(t; q0,-q1) are not the same. It is
 			customary to choose the sign... on q1 so that... the angle
 			between q0 and q1 is acute. This choice avoids extra
 			spinning caused by the interpolated rotations."
 		*/
 		qi.x = -qB.x;
 		qi.y = -qB.y;
 		qi.z = -qB.z;
 		qi.w = -qB.w;

 		PVRTMatrixQuaternionSlerpF(qOut, qA, qi, t);
 		return;
 	}

 	fCosine = PVRT_MIN(fCosine, 1.0f);
 	fAngle = (float)PVRTFACOS(fCosine);

 	/* Avoid a division by zero */
 	if (fAngle==0.0f)
 	{
 		qOut = qA;
 		return;
 	}

 	/* Precompute some values */
 	A = (float)(PVRTFSIN((1.0f-t)*fAngle) / PVRTFSIN(fAngle));
 	B = (float)(PVRTFSIN(t*fAngle) / PVRTFSIN(fAngle));

 	/* Compute resulting quaternion */
 	qOut.x = A * qA.x + B * qB.x;
 	qOut.y = A * qA.y + B * qB.y;
 	qOut.z = A * qA.z + B * qB.z;
 	qOut.w = A * qA.w + B * qB.w;

 	/* Normalise result */
 	PVRTMatrixQuaternionNormalizeF(qOut);
 }

 /*!***************************************************************************
  @Function			PVRTMatrixQuaternionNormalizeF
  @Modified			quat	Vector to normalize
  @Description		Normalize quaternion.
 *****************************************************************************/
 void PVRTMatrixQuaternionNormalizeF(PVRTQUATERNIONf &quat)
 {
 	float	fMagnitude;
 	double	temp;

 	/* Compute quaternion magnitude */
 	temp = quat.w*quat.w + quat.x*quat.x + quat.y*quat.y + quat.z*quat.z;
 	fMagnitude = (float)sqrt(temp);

 	/* Divide each quaternion component by this magnitude */
 	if (fMagnitude!=0.0f)
 	{
 		fMagnitude = 1.0f / fMagnitude;
 		quat.x *= fMagnitude;
 		quat.y *= fMagnitude;
 		quat.z *= fMagnitude;
 		quat.w *= fMagnitude;
 	}
 }

 /*!***************************************************************************
  @Function			PVRTMatrixRotationQuaternionF
  @Output			mOut	Resulting rotation matrix
  @Input				quat	Quaternion to transform
  @Description		Create rotation matrix from submitted quaternion.
 					Assuming the quaternion is of the form [X Y Z W]:

 						|       2     2									|
 						| 1 - 2Y  - 2Z    2XY - 2ZW      2XZ + 2YW		 0	|
 						|													|
 						|                       2     2					|
 					M = | 2XY + 2ZW       1 - 2X  - 2Z   2YZ - 2XW		 0	|
 						|													|
 						|                                      2     2		|
 						| 2XZ - 2YW       2YZ + 2XW      1 - 2X  - 2Y	 0	|
 						|													|
 						|     0			   0			  0          1  |
 *****************************************************************************/
 void PVRTMatrixRotationQuaternionF(
 	PVRTMATRIXf				&mOut,
 	const PVRTQUATERNIONf	&quat)
 {
 	const PVRTQUATERNIONf *pQ;

 #if defined(BUILD_DX11)
 	PVRTQUATERNIONf qInv;

 	qInv.x = -quat.x;
 	qInv.y = -quat.y;
 	qInv.z = -quat.z;
 	qInv.w = quat.w;

 	pQ = &qInv;
 #else
 	pQ = &quat;
 #endif

     /* Fill matrix members */
 	mOut.f[0] = 1.0f - 2.0f*pQ->y*pQ->y - 2.0f*pQ->z*pQ->z;
 	mOut.f[1] = 2.0f*pQ->x*pQ->y - 2.0f*pQ->z*pQ->w;
 	mOut.f[2] = 2.0f*pQ->x*pQ->z + 2.0f*pQ->y*pQ->w;
 	mOut.f[3] = 0.0f;

 	mOut.f[4] = 2.0f*pQ->x*pQ->y + 2.0f*pQ->z*pQ->w;
 	mOut.f[5] = 1.0f - 2.0f*pQ->x*pQ->x - 2.0f*pQ->z*pQ->z;
 	mOut.f[6] = 2.0f*pQ->y*pQ->z - 2.0f*pQ->x*pQ->w;
 	mOut.f[7] = 0.0f;

 	mOut.f[8] = 2.0f*pQ->x*pQ->z - 2*pQ->y*pQ->w;
 	mOut.f[9] = 2.0f*pQ->y*pQ->z + 2.0f*pQ->x*pQ->w;
 	mOut.f[10] = 1.0f - 2.0f*pQ->x*pQ->x - 2*pQ->y*pQ->y;
 	mOut.f[11] = 0.0f;

 	mOut.f[12] = 0.0f;
 	mOut.f[13] = 0.0f;
 	mOut.f[14] = 0.0f;
 	mOut.f[15] = 1.0f;
 }

 /*!***************************************************************************
  @Function			PVRTMatrixQuaternionMultiplyF
  @Output			qOut	Resulting quaternion
  @Input				qA		First quaternion to multiply
  @Input				qB		Second quaternion to multiply
  @Description		Multiply quaternion A with quaternion B and return the
 					result in qOut.
 *****************************************************************************/
 void PVRTMatrixQuaternionMultiplyF(
 	PVRTQUATERNIONf			&qOut,
 	const PVRTQUATERNIONf	&qA,
 	const PVRTQUATERNIONf	&qB)
 {
 	PVRTVECTOR3f	CrossProduct;
 	PVRTQUATERNIONf qRet;

 	/* Compute scalar component */
 	qRet.w = (qA.w*qB.w) - (qA.x*qB.x + qA.y*qB.y + qA.z*qB.z);

 	/* Compute cross product */
 	CrossProduct.x = qA.y*qB.z - qA.z*qB.y;
 	CrossProduct.y = qA.z*qB.x - qA.x*qB.z;
 	CrossProduct.z = qA.x*qB.y - qA.y*qB.x;

 	/* Compute result vector */
 	qRet.x = (qA.w * qB.x) + (qB.w * qA.x) + CrossProduct.x;
 	qRet.y = (qA.w * qB.y) + (qB.w * qA.y) + CrossProduct.y;
 	qRet.z = (qA.w * qB.z) + (qB.w * qA.z) + CrossProduct.z;

 	/* Normalize resulting quaternion */
 	PVRTMatrixQuaternionNormalizeF(qRet);

 	/* Copy result to mOut */
 	qOut = qRet;
 }

 /*****************************************************************************
  End of file (PVRTQuaternionF.cpp)
 *****************************************************************************/
	/******************************************************************************

	@File PVRTQuaternionF.cpp

	@Title PVRTQuaternionF

	@Version

	@Copyright Copyright (c) Imagination Technologies Limited.

	@Platform ANSI compatible

	@Description Set of mathematical functions for quaternions.

	******************************************************************************/
	#include "PVRTGlobal.h"
	#include <math.h>
	#include <string.h>
	#include "PVRTFixedPoint.h" // Only needed for trig function float lookups
	#include "PVRTQuaternion.h"


	/****************************************************************************
	** Functions
	****************************************************************************/

	/!**************************************************************************
	@Function PVRTMatrixQuaternionIdentityF
	@Output qOut Identity quaternion
	@Description Sets the quaternion to (0, 0, 0, 1), the identity quaternion.
	*****************************************************************************/
	void PVRTMatrixQuaternionIdentityF(PVRTQUATERNIONf &qOut)
	{
	qOut.x = 0;
	qOut.y = 0;
	qOut.z = 0;
	qOut.w = 1;
	}

	/!**************************************************************************
	@Function PVRTMatrixQuaternionRotationAxisF
	@Output qOut Rotation quaternion
	@Input vAxis Axis to rotate around
	@Input fAngle Angle to rotate
	@Description Create quaternion corresponding to a rotation of fAngle
	radians around submitted vector.
	*****************************************************************************/
	void PVRTMatrixQuaternionRotationAxisF(
	PVRTQUATERNIONf &qOut,
	const PVRTVECTOR3f &vAxis,
	const float fAngle)
	{
	float fSin, fCos;

	fSin = (float)PVRTFSIN(fAngle * 0.5f);
	fCos = (float)PVRTFCOS(fAngle * 0.5f);

	/* Create quaternion */
	qOut.x = vAxis.x * fSin;
	qOut.y = vAxis.y * fSin;
	qOut.z = vAxis.z * fSin;
	qOut.w = fCos;

	/* Normalise it */
	PVRTMatrixQuaternionNormalizeF(qOut);
	}

	/!**************************************************************************
	@Function PVRTMatrixQuaternionToAxisAngleF
	@Input qIn Quaternion to transform
	@Output vAxis Axis of rotation
	@Output fAngle Angle of rotation
	@Description Convert a quaternion to an axis and angle. Expects a unit
	quaternion.
	*****************************************************************************/
	void PVRTMatrixQuaternionToAxisAngleF(
	const PVRTQUATERNIONf &qIn,
	PVRTVECTOR3f &vAxis,
	float &fAngle)
	{
	float fCosAngle, fSinAngle;
	double temp;

	/* Compute some values */
	fCosAngle = qIn.w;
	temp = 1.0f - fCosAngle*fCosAngle;
	fAngle = (float)PVRTFACOS(fCosAngle)*2.0f;
	fSinAngle = (float)sqrt(temp);

	/* This is to avoid a division by zero */
	if ((float)fabs(fSinAngle)<0.0005f)
	fSinAngle = 1.0f;

	/* Get axis vector */
	vAxis.x = qIn.x / fSinAngle;
	vAxis.y = qIn.y / fSinAngle;
	vAxis.z = qIn.z / fSinAngle;
	}

	/!**************************************************************************
	@Function PVRTMatrixQuaternionSlerpF
	@Output qOut Result of the interpolation
	@Input qA First quaternion to interpolate from
	@Input qB Second quaternion to interpolate from
	@Input t Coefficient of interpolation
	@Description Perform a Spherical Linear intERPolation between quaternion A
	and quaternion B at time t. t must be between 0.0f and 1.0f
	*****************************************************************************/
	void PVRTMatrixQuaternionSlerpF(
	PVRTQUATERNIONf &qOut,
	const PVRTQUATERNIONf &qA,
	const PVRTQUATERNIONf &qB,
	const float t)
	{
	float fCosine, fAngle, A, B;

	/* Parameter checking */
	if (t<0.0f \|\| t>1.0f)
	{
	_RPT0(_CRT_WARN, "PVRTMatrixQuaternionSlerp : Bad parameters\n");
	qOut.x = 0;
	qOut.y = 0;
	qOut.z = 0;
	qOut.w = 1;
	return;
	}

	/* Find sine of Angle between Quaternion A and B (dot product between quaternion A and B) */
	fCosine = qA.wqB.w + qA.xqB.x + qA.yqB.y + qA.zqB.z;

	if (fCosine < 0)
	{
	PVRTQUATERNIONf qi;

	/*
	<http://www.magic-software.com/Documentation/Quaternions.pdf>

	"It is important to note that the quaternions q and -q represent
	the same rotation... while either quaternion will do, the
	interpolation methods require choosing one over the other.

	"Although q1 and -q1 represent the same rotation, the values of
	Slerp(t; q0, q1) and Slerp(t; q0,-q1) are not the same. It is
	customary to choose the sign... on q1 so that... the angle
	between q0 and q1 is acute. This choice avoids extra
	spinning caused by the interpolated rotations."
	*/
	qi.x = -qB.x;
	qi.y = -qB.y;
	qi.z = -qB.z;
	qi.w = -qB.w;

	PVRTMatrixQuaternionSlerpF(qOut, qA, qi, t);
	return;
	}

	fCosine = PVRT_MIN(fCosine, 1.0f);
	fAngle = (float)PVRTFACOS(fCosine);

	/* Avoid a division by zero */
	if (fAngle==0.0f)
	{
	qOut = qA;
	return;
	}

	/* Precompute some values */
	A = (float)(PVRTFSIN((1.0f-t)*fAngle) / PVRTFSIN(fAngle));
	B = (float)(PVRTFSIN(t*fAngle) / PVRTFSIN(fAngle));

	/* Compute resulting quaternion */
	qOut.x = A * qA.x + B * qB.x;
	qOut.y = A * qA.y + B * qB.y;
	qOut.z = A * qA.z + B * qB.z;
	qOut.w = A * qA.w + B * qB.w;

	/* Normalise result */
	PVRTMatrixQuaternionNormalizeF(qOut);
	}

	/!**************************************************************************
	@Function PVRTMatrixQuaternionNormalizeF
	@Modified quat Vector to normalize
	@Description Normalize quaternion.
	*****************************************************************************/
	void PVRTMatrixQuaternionNormalizeF(PVRTQUATERNIONf &quat)
	{
	float fMagnitude;
	double temp;

	/* Compute quaternion magnitude */
	temp = quat.wquat.w + quat.xquat.x + quat.yquat.y + quat.zquat.z;
	fMagnitude = (float)sqrt(temp);

	/* Divide each quaternion component by this magnitude */
	if (fMagnitude!=0.0f)
	{
	fMagnitude = 1.0f / fMagnitude;
	quat.x *= fMagnitude;
	quat.y *= fMagnitude;
	quat.z *= fMagnitude;
	quat.w *= fMagnitude;
	}
	}

	/!**************************************************************************
	@Function PVRTMatrixRotationQuaternionF
	@Output mOut Resulting rotation matrix
	@Input quat Quaternion to transform
	@Description Create rotation matrix from submitted quaternion.
	Assuming the quaternion is of the form [X Y Z W]:

	\| 2 2 \|
	\| 1 - 2Y - 2Z 2XY - 2ZW 2XZ + 2YW 0 \|
	\| \|
	\| 2 2 \|
	M = \| 2XY + 2ZW 1 - 2X - 2Z 2YZ - 2XW 0 \|
	\| \|
	\| 2 2 \|
	\| 2XZ - 2YW 2YZ + 2XW 1 - 2X - 2Y 0 \|
	\| \|
	\| 0 0 0 1 \|
	*****************************************************************************/
	void PVRTMatrixRotationQuaternionF(
	PVRTMATRIXf &mOut,
	const PVRTQUATERNIONf &quat)
	{
	const PVRTQUATERNIONf *pQ;

	#if defined(BUILD_DX11)
	PVRTQUATERNIONf qInv;

	qInv.x = -quat.x;
	qInv.y = -quat.y;
	qInv.z = -quat.z;
	qInv.w = quat.w;

	pQ = &qInv;
	#else
	pQ = &quat;
	#endif

	/* Fill matrix members */
	mOut.f[0] = 1.0f - 2.0fpQ->ypQ->y - 2.0fpQ->zpQ->z;
	mOut.f[1] = 2.0fpQ->xpQ->y - 2.0fpQ->zpQ->w;
	mOut.f[2] = 2.0fpQ->xpQ->z + 2.0fpQ->ypQ->w;
	mOut.f[3] = 0.0f;

	mOut.f[4] = 2.0fpQ->xpQ->y + 2.0fpQ->zpQ->w;
	mOut.f[5] = 1.0f - 2.0fpQ->xpQ->x - 2.0fpQ->zpQ->z;
	mOut.f[6] = 2.0fpQ->ypQ->z - 2.0fpQ->xpQ->w;
	mOut.f[7] = 0.0f;

	mOut.f[8] = 2.0fpQ->xpQ->z - 2pQ->ypQ->w;
	mOut.f[9] = 2.0fpQ->ypQ->z + 2.0fpQ->xpQ->w;
	mOut.f[10] = 1.0f - 2.0fpQ->xpQ->x - 2pQ->ypQ->y;
	mOut.f[11] = 0.0f;

	mOut.f[12] = 0.0f;
	mOut.f[13] = 0.0f;
	mOut.f[14] = 0.0f;
	mOut.f[15] = 1.0f;
	}

	/!**************************************************************************
	@Function PVRTMatrixQuaternionMultiplyF
	@Output qOut Resulting quaternion
	@Input qA First quaternion to multiply
	@Input qB Second quaternion to multiply
	@Description Multiply quaternion A with quaternion B and return the
	result in qOut.
	*****************************************************************************/
	void PVRTMatrixQuaternionMultiplyF(
	PVRTQUATERNIONf &qOut,
	const PVRTQUATERNIONf &qA,
	const PVRTQUATERNIONf &qB)
	{
	PVRTVECTOR3f CrossProduct;
	PVRTQUATERNIONf qRet;

	/* Compute scalar component */
	qRet.w = (qA.wqB.w) - (qA.xqB.x + qA.yqB.y + qA.zqB.z);

	/* Compute cross product */
	CrossProduct.x = qA.yqB.z - qA.zqB.y;
	CrossProduct.y = qA.zqB.x - qA.xqB.z;
	CrossProduct.z = qA.xqB.y - qA.yqB.x;

	/* Compute result vector */
	qRet.x = (qA.w * qB.x) + (qB.w * qA.x) + CrossProduct.x;
	qRet.y = (qA.w * qB.y) + (qB.w * qA.y) + CrossProduct.y;
	qRet.z = (qA.w * qB.z) + (qB.w * qA.z) + CrossProduct.z;

	/* Normalize resulting quaternion */
	PVRTMatrixQuaternionNormalizeF(qRet);

	/* Copy result to mOut */
	qOut = qRet;
	}

	/*****************************************************************************
	End of file (PVRTQuaternionF.cpp)
	*****************************************************************************/