scriptc/rs_quaternion.rsh - fp2-dev/platform/frameworks/rs - Gitiles

 /*
  * Copyright (C) 2015 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 // Don't edit this file!  It is auto-generated by frameworks/rs/api/gen_runtime.

 /*
  * rs_quaternion.rsh: Quaternion routines
  *
  */
 #ifndef RENDERSCRIPT_RS_QUATERNION_RSH
 #define RENDERSCRIPT_RS_QUATERNION_RSH

 /*
  * Add two quaternions
  *
  * Parameters:
  *   q destination quaternion to add to
  *   rhs right hand side quaternion to add
  */
 static inline void __attribute__((overloadable))
     rsQuaternionAdd(rs_quaternion* q, const rs_quaternion* rhs) {
     q->w *= rhs->w;
     q->x *= rhs->x;
     q->y *= rhs->y;
     q->z *= rhs->z;
 }

 /*
  * Conjugates the quaternion
  *
  * Parameters:
  *   q quaternion to conjugate
  */
 static inline void __attribute__((overloadable))
     rsQuaternionConjugate(rs_quaternion* q) {
     q->x = -q->x;
     q->y = -q->y;
     q->z = -q->z;
 }

 /*
  * Dot product of two quaternions
  *
  * Parameters:
  *   q0 first quaternion
  *   q1 second quaternion
  *
  * Returns: dot product between q0 and q1
  */
 static inline float __attribute__((overloadable))
     rsQuaternionDot(const rs_quaternion* q0, const rs_quaternion* q1) {
     return q0->w*q1->w + q0->x*q1->x + q0->y*q1->y + q0->z*q1->z;
 }

 /*
  * Computes rotation matrix from the normalized quaternion
  *
  * Parameters:
  *   m resulting matrix
  *   q normalized quaternion
  */
 static inline void __attribute__((overloadable))
     rsQuaternionGetMatrixUnit(rs_matrix4x4* m, const rs_quaternion* q) {
     float xx = q->x * q->x;
     float xy = q->x * q->y;
     float xz = q->x * q->z;
     float xw = q->x * q->w;
     float yy = q->y * q->y;
     float yz = q->y * q->z;
     float yw = q->y * q->w;
     float zz = q->z * q->z;
     float zw = q->z * q->w;

     m->m[0]  = 1.0f - 2.0f * ( yy + zz );
     m->m[4]  =        2.0f * ( xy - zw );
     m->m[8]  =        2.0f * ( xz + yw );
     m->m[1]  =        2.0f * ( xy + zw );
     m->m[5]  = 1.0f - 2.0f * ( xx + zz );
     m->m[9]  =        2.0f * ( yz - xw );
     m->m[2]  =        2.0f * ( xz - yw );
     m->m[6]  =        2.0f * ( yz + xw );
     m->m[10] = 1.0f - 2.0f * ( xx + yy );
     m->m[3]  = m->m[7] = m->m[11] = m->m[12] = m->m[13] = m->m[14] = 0.0f;
     m->m[15] = 1.0f;
 }

 /*
  * Loads a quaternion that represents a rotation about an arbitrary unit vector
  *
  * Parameters:
  *   q quaternion to set
  *   rot rot angle to rotate by
  *   x component of a vector
  *   y component of a vector
  *   z component of a vector
  */
 static inline void __attribute__((overloadable))
     rsQuaternionLoadRotateUnit(rs_quaternion* q, float rot, float x, float y, float z) {
     rot *= (float)(M_PI / 180.0f) * 0.5f;
     float c = cos(rot);
     float s = sin(rot);

     q->w = c;
     q->x = x * s;
     q->y = y * s;
     q->z = z * s;
 }

 /*
  * Set the quaternion from components or from another quaternion.
  *
  * Parameters:
  *   q destination quaternion
  *   w component
  *   x component
  *   y component
  *   z component
  *   rhs source quaternion
  */
 static inline void __attribute__((overloadable))
     rsQuaternionSet(rs_quaternion* q, float w, float x, float y, float z) {
     q->w = w;
     q->x = x;
     q->y = y;
     q->z = z;
 }

 static inline void __attribute__((overloadable))
     rsQuaternionSet(rs_quaternion* q, const rs_quaternion* rhs) {
     q->w = rhs->w;
     q->x = rhs->x;
     q->y = rhs->y;
     q->z = rhs->z;
 }

 /*
  * Loads a quaternion that represents a rotation about an arbitrary vector
  * (doesn't have to be unit)
  *
  * Parameters:
  *   q quaternion to set
  *   rot angle to rotate by
  *   x component of a vector
  *   y component of a vector
  *   z component of a vector
  */
 static inline void __attribute__((overloadable))
     rsQuaternionLoadRotate(rs_quaternion* q, float rot, float x, float y, float z) {
     const float len = x*x + y*y + z*z;
     if (len != 1) {
         const float recipLen = 1.f / sqrt(len);
         x *= recipLen;
         y *= recipLen;
         z *= recipLen;
     }
     rsQuaternionLoadRotateUnit(q, rot, x, y, z);
 }

 /*
  * Normalizes the quaternion
  *
  * Parameters:
  *   q quaternion to normalize
  */
 static inline void __attribute__((overloadable))
     rsQuaternionNormalize(rs_quaternion* q) {
     const float len = rsQuaternionDot(q, q);
     if (len != 1) {
         const float recipLen = 1.f / sqrt(len);
         q->w *= recipLen;
         q->x *= recipLen;
         q->y *= recipLen;
         q->z *= recipLen;
     }
 }

 /*
  * Multiply quaternion by a scalar or another quaternion
  *
  * Parameters:
  *   q destination quaternion
  *   s scalar
  *   rhs right hand side quaternion to multiply by
  */
 static inline void __attribute__((overloadable))
     rsQuaternionMultiply(rs_quaternion* q, float s) {
     q->w *= s;
     q->x *= s;
     q->y *= s;
     q->z *= s;
 }

 static inline void __attribute__((overloadable))
     rsQuaternionMultiply(rs_quaternion* q, const rs_quaternion* rhs) {
     rs_quaternion qtmp;
     rsQuaternionSet(&qtmp, q);

     q->w = qtmp.w*rhs->w - qtmp.x*rhs->x - qtmp.y*rhs->y - qtmp.z*rhs->z;
     q->x = qtmp.w*rhs->x + qtmp.x*rhs->w + qtmp.y*rhs->z - qtmp.z*rhs->y;
     q->y = qtmp.w*rhs->y + qtmp.y*rhs->w + qtmp.z*rhs->x - qtmp.x*rhs->z;
     q->z = qtmp.w*rhs->z + qtmp.z*rhs->w + qtmp.x*rhs->y - qtmp.y*rhs->x;
     rsQuaternionNormalize(q);
 }

 /*
  * Performs spherical linear interpolation between two quaternions
  *
  * Parameters:
  *   q result quaternion from interpolation
  *   q0 first param
  *   q1 second param
  *   t how much to interpolate by
  */
 static inline void __attribute__((overloadable))
     rsQuaternionSlerp(rs_quaternion* q, const rs_quaternion* q0, const rs_quaternion* q1, float t) {
     if (t <= 0.0f) {
         rsQuaternionSet(q, q0);
         return;
     }
     if (t >= 1.0f) {
         rsQuaternionSet(q, q1);
         return;
     }

     rs_quaternion tempq0, tempq1;
     rsQuaternionSet(&tempq0, q0);
     rsQuaternionSet(&tempq1, q1);

     float angle = rsQuaternionDot(q0, q1);
     if (angle < 0) {
         rsQuaternionMultiply(&tempq0, -1.0f);
         angle *= -1.0f;
     }

     float scale, invScale;
     if (angle + 1.0f > 0.05f) {
         if (1.0f - angle >= 0.05f) {
             float theta = acos(angle);
             float invSinTheta = 1.0f / sin(theta);
             scale = sin(theta * (1.0f - t)) * invSinTheta;
             invScale = sin(theta * t) * invSinTheta;
         } else {
             scale = 1.0f - t;
             invScale = t;
         }
     } else {
         rsQuaternionSet(&tempq1, tempq0.z, -tempq0.y, tempq0.x, -tempq0.w);
         scale = sin(M_PI * (0.5f - t));
         invScale = sin(M_PI * t);
     }

     rsQuaternionSet(q, tempq0.w*scale + tempq1.w*invScale, tempq0.x*scale + tempq1.x*invScale,
                         tempq0.y*scale + tempq1.y*invScale, tempq0.z*scale + tempq1.z*invScale);
 }

 #endif // RENDERSCRIPT_RS_QUATERNION_RSH
	/*
	* Copyright (C) 2015 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	// Don't edit this file! It is auto-generated by frameworks/rs/api/gen_runtime.

	/*
	* rs_quaternion.rsh: Quaternion routines
	*
	*/
	#ifndef RENDERSCRIPT_RS_QUATERNION_RSH
	#define RENDERSCRIPT_RS_QUATERNION_RSH

	/*
	* Add two quaternions
	*
	* Parameters:
	* q destination quaternion to add to
	* rhs right hand side quaternion to add
	*/
	static inline void __attribute__((overloadable))
	rsQuaternionAdd(rs_quaternion* q, const rs_quaternion* rhs) {
	q->w *= rhs->w;
	q->x *= rhs->x;
	q->y *= rhs->y;
	q->z *= rhs->z;
	}

	/*
	* Conjugates the quaternion
	*
	* Parameters:
	* q quaternion to conjugate
	*/
	static inline void __attribute__((overloadable))
	rsQuaternionConjugate(rs_quaternion* q) {
	q->x = -q->x;
	q->y = -q->y;
	q->z = -q->z;
	}

	/*
	* Dot product of two quaternions
	*
	* Parameters:
	* q0 first quaternion
	* q1 second quaternion
	*
	* Returns: dot product between q0 and q1
	*/
	static inline float __attribute__((overloadable))
	rsQuaternionDot(const rs_quaternion* q0, const rs_quaternion* q1) {
	return q0->wq1->w + q0->xq1->x + q0->yq1->y + q0->zq1->z;
	}

	/*
	* Computes rotation matrix from the normalized quaternion
	*
	* Parameters:
	* m resulting matrix
	* q normalized quaternion
	*/
	static inline void __attribute__((overloadable))
	rsQuaternionGetMatrixUnit(rs_matrix4x4* m, const rs_quaternion* q) {
	float xx = q->x * q->x;
	float xy = q->x * q->y;
	float xz = q->x * q->z;
	float xw = q->x * q->w;
	float yy = q->y * q->y;
	float yz = q->y * q->z;
	float yw = q->y * q->w;
	float zz = q->z * q->z;
	float zw = q->z * q->w;

	m->m[0] = 1.0f - 2.0f * ( yy + zz );
	m->m[4] = 2.0f * ( xy - zw );
	m->m[8] = 2.0f * ( xz + yw );
	m->m[1] = 2.0f * ( xy + zw );
	m->m[5] = 1.0f - 2.0f * ( xx + zz );
	m->m[9] = 2.0f * ( yz - xw );
	m->m[2] = 2.0f * ( xz - yw );
	m->m[6] = 2.0f * ( yz + xw );
	m->m[10] = 1.0f - 2.0f * ( xx + yy );
	m->m[3] = m->m[7] = m->m[11] = m->m[12] = m->m[13] = m->m[14] = 0.0f;
	m->m[15] = 1.0f;
	}

	/*
	* Loads a quaternion that represents a rotation about an arbitrary unit vector
	*
	* Parameters:
	* q quaternion to set
	* rot rot angle to rotate by
	* x component of a vector
	* y component of a vector
	* z component of a vector
	*/
	static inline void __attribute__((overloadable))
	rsQuaternionLoadRotateUnit(rs_quaternion* q, float rot, float x, float y, float z) {
	rot = (float)(M_PI / 180.0f) 0.5f;
	float c = cos(rot);
	float s = sin(rot);

	q->w = c;
	q->x = x * s;
	q->y = y * s;
	q->z = z * s;
	}

	/*
	* Set the quaternion from components or from another quaternion.
	*
	* Parameters:
	* q destination quaternion
	* w component
	* x component
	* y component
	* z component
	* rhs source quaternion
	*/
	static inline void __attribute__((overloadable))
	rsQuaternionSet(rs_quaternion* q, float w, float x, float y, float z) {
	q->w = w;
	q->x = x;
	q->y = y;
	q->z = z;
	}

	static inline void __attribute__((overloadable))
	rsQuaternionSet(rs_quaternion* q, const rs_quaternion* rhs) {
	q->w = rhs->w;
	q->x = rhs->x;
	q->y = rhs->y;
	q->z = rhs->z;
	}

	/*
	* Loads a quaternion that represents a rotation about an arbitrary vector
	* (doesn't have to be unit)
	*
	* Parameters:
	* q quaternion to set
	* rot angle to rotate by
	* x component of a vector
	* y component of a vector
	* z component of a vector
	*/
	static inline void __attribute__((overloadable))
	rsQuaternionLoadRotate(rs_quaternion* q, float rot, float x, float y, float z) {
	const float len = xx + yy + z*z;
	if (len != 1) {
	const float recipLen = 1.f / sqrt(len);
	x *= recipLen;
	y *= recipLen;
	z *= recipLen;
	}
	rsQuaternionLoadRotateUnit(q, rot, x, y, z);
	}

	/*
	* Normalizes the quaternion
	*
	* Parameters:
	* q quaternion to normalize
	*/
	static inline void __attribute__((overloadable))
	rsQuaternionNormalize(rs_quaternion* q) {
	const float len = rsQuaternionDot(q, q);
	if (len != 1) {
	const float recipLen = 1.f / sqrt(len);
	q->w *= recipLen;
	q->x *= recipLen;
	q->y *= recipLen;
	q->z *= recipLen;
	}
	}

	/*
	* Multiply quaternion by a scalar or another quaternion
	*
	* Parameters:
	* q destination quaternion
	* s scalar
	* rhs right hand side quaternion to multiply by
	*/
	static inline void __attribute__((overloadable))
	rsQuaternionMultiply(rs_quaternion* q, float s) {
	q->w *= s;
	q->x *= s;
	q->y *= s;
	q->z *= s;
	}

	static inline void __attribute__((overloadable))
	rsQuaternionMultiply(rs_quaternion* q, const rs_quaternion* rhs) {
	rs_quaternion qtmp;
	rsQuaternionSet(&qtmp, q);

	q->w = qtmp.wrhs->w - qtmp.xrhs->x - qtmp.yrhs->y - qtmp.zrhs->z;
	q->x = qtmp.wrhs->x + qtmp.xrhs->w + qtmp.yrhs->z - qtmp.zrhs->y;
	q->y = qtmp.wrhs->y + qtmp.yrhs->w + qtmp.zrhs->x - qtmp.xrhs->z;
	q->z = qtmp.wrhs->z + qtmp.zrhs->w + qtmp.xrhs->y - qtmp.yrhs->x;
	rsQuaternionNormalize(q);
	}

	/*
	* Performs spherical linear interpolation between two quaternions
	*
	* Parameters:
	* q result quaternion from interpolation
	* q0 first param
	* q1 second param
	* t how much to interpolate by
	*/
	static inline void __attribute__((overloadable))
	rsQuaternionSlerp(rs_quaternion* q, const rs_quaternion* q0, const rs_quaternion* q1, float t) {
	if (t <= 0.0f) {
	rsQuaternionSet(q, q0);
	return;
	}
	if (t >= 1.0f) {
	rsQuaternionSet(q, q1);
	return;
	}

	rs_quaternion tempq0, tempq1;
	rsQuaternionSet(&tempq0, q0);
	rsQuaternionSet(&tempq1, q1);

	float angle = rsQuaternionDot(q0, q1);
	if (angle < 0) {
	rsQuaternionMultiply(&tempq0, -1.0f);
	angle *= -1.0f;
	}

	float scale, invScale;
	if (angle + 1.0f > 0.05f) {
	if (1.0f - angle >= 0.05f) {
	float theta = acos(angle);
	float invSinTheta = 1.0f / sin(theta);
	scale = sin(theta * (1.0f - t)) * invSinTheta;
	invScale = sin(theta * t) * invSinTheta;
	} else {
	scale = 1.0f - t;
	invScale = t;
	}
	} else {
	rsQuaternionSet(&tempq1, tempq0.z, -tempq0.y, tempq0.x, -tempq0.w);
	scale = sin(M_PI * (0.5f - t));
	invScale = sin(M_PI * t);
	}

	rsQuaternionSet(q, tempq0.wscale + tempq1.winvScale, tempq0.xscale + tempq1.xinvScale,
	tempq0.yscale + tempq1.yinvScale, tempq0.zscale + tempq1.zinvScale);
	}

	#endif // RENDERSCRIPT_RS_QUATERNION_RSH