示例#1
0
MT_CmMatrix4x4::MT_CmMatrix4x4(const MT_Point3& orig,
							 const MT_Vector3& dir,
							 const MT_Vector3 up)
{
	MT_Vector3 z = -(dir.normalized());
	MT_Vector3 x = (up.cross(z)).normalized();
	MT_Vector3 y = (z.cross(x));
	
	m_V[0][0] = x.x();
	m_V[0][1] = y.x();
	m_V[0][2] = z.x();
	m_V[0][3] = 0.0f;
	
	m_V[1][0] = x.y();
	m_V[1][1] = y.y();
	m_V[1][2] = z.y();
	m_V[1][3] = 0.0f;
	
	m_V[2][0] = x.z();
	m_V[2][1] = y.z();
	m_V[2][2] = z.z();
	m_V[2][3] = 0.0f;
	
	m_V[3][0] = orig.x();//0.0f;
	m_V[3][1] = orig.y();//0.0f;
	m_V[3][2] = orig.z();//0.0f;
	m_V[3][3] = 1.0f;
	
	//Translate(-orig);
}
示例#2
0
/**
 * Returns if a quad (coplanar) is convex.
 * @return true if the quad is convex, false otherwise
 */
bool BOP_convex(const MT_Point3& p1, const MT_Point3& p2, const MT_Point3& p3, const MT_Point3& p4)
{
	MT_Vector3 v1 = p3 - p1;
	MT_Vector3 v2 = p4 - p2;
	MT_Vector3 quadPlane = v1.cross(v2);
	// plane1 is the perpendicular plane that contains the quad diagonal (p2,p4)
	MT_Plane3 plane1(quadPlane.cross(v2),p2);
	// if p1 and p3 are classified in the same region, the quad is not convex 
	if (BOP_classify(p1,plane1) == BOP_classify(p3,plane1)) return false;
	else {
		// Test the other quad diagonal (p1,p3) and perpendicular plane
		MT_Plane3 plane2(quadPlane.cross(v1),p1);
		// if p2 and p4 are classified in the same region, the quad is not convex
		return (BOP_classify(p2,plane2) != BOP_classify(p4,plane2));
	}
}
bool RAS_OpenGLRasterizer::RayHit(struct KX_ClientObjectInfo *client, KX_RayCast *result, void * const data)
{
	double* const oglmatrix = (double* const) data;

	RAS_Polygon* poly = result->m_hitMesh->GetPolygon(result->m_hitPolygon);
	if (!poly->IsVisible())
		return false;

	MT_Point3 resultpoint(result->m_hitPoint);
	MT_Vector3 resultnormal(result->m_hitNormal);
	MT_Vector3 left(oglmatrix[0],oglmatrix[1],oglmatrix[2]);
	MT_Vector3 dir = -(left.cross(resultnormal)).safe_normalized();
	left = (dir.cross(resultnormal)).safe_normalized();
	// for the up vector, we take the 'resultnormal' returned by the physics

	double maat[16] = {left[0],         left[1],         left[2],         0,
	                   dir[0],          dir[1],          dir[2],          0,
	                   resultnormal[0], resultnormal[1], resultnormal[2], 0,
	                   0,               0,               0,               1};

	glTranslated(resultpoint[0],resultpoint[1],resultpoint[2]);
	//glMultMatrixd(oglmatrix);
	glMultMatrixd(maat);
	return true;
}
示例#4
0
bool RAS_OpenGLRasterizer::RayHit(struct KX_ClientObjectInfo *client, KX_RayCast *result, float *oglmatrix)
{
	if (result->m_hitMesh) {

		RAS_Polygon* poly = result->m_hitMesh->GetPolygon(result->m_hitPolygon);
		if (!poly->IsVisible())
			return false;

		MT_Vector3 resultnormal(result->m_hitNormal);
		MT_Vector3 left(oglmatrix[0],oglmatrix[1],oglmatrix[2]);
		MT_Vector3 dir = -(left.cross(resultnormal)).safe_normalized();
		left = (dir.cross(resultnormal)).safe_normalized();
		// for the up vector, we take the 'resultnormal' returned by the physics

		float maat[16] = {left[0],         left[1],         left[2],         0,
			               dir[0],          dir[1],          dir[2],          0,
		                  resultnormal[0], resultnormal[1], resultnormal[2], 0,
		                  0,               0,               0,               1};

		glTranslatef(oglmatrix[12],oglmatrix[13],oglmatrix[14]);
		//glMultMatrixd(oglmatrix);
		glMultMatrixf(maat);
		return true;
	}
	else {
		return false;
	}
}
示例#5
0
/* vectomat function obtained from constrain.c and modified to work with MOTO library */
static MT_Matrix3x3 vectomat(MT_Vector3 vec, short axis, short upflag, short threedimup)
{
	MT_Matrix3x3 mat;
	MT_Vector3 y(MT_Scalar(0.0f), MT_Scalar(1.0f), MT_Scalar(0.0f));
	MT_Vector3 z(MT_Scalar(0.0f), MT_Scalar(0.0f), MT_Scalar(1.0f)); /* world Z axis is the global up axis */
	MT_Vector3 proj;
	MT_Vector3 right;
	MT_Scalar mul;
	int right_index;

	/* Normalized Vec vector*/
	vec = vec.safe_normalized_vec(z);

	/* if 2D doesn't move the up vector */
	if (!threedimup) {
		vec.setValue(MT_Scalar(vec[0]), MT_Scalar(vec[1]), MT_Scalar(0.0f));
		vec = (vec - z.dot(vec)*z).safe_normalized_vec(z);
	}

	if (axis > 2)
		axis -= 3;
	else
		vec = -vec;

	/* project the up vector onto the plane specified by vec */
	/* first z onto vec... */
	mul = z.dot(vec) / vec.dot(vec);
	proj = vec * mul;
	/* then onto the plane */
	proj = z - proj;
	/* proj specifies the transformation of the up axis */
	proj = proj.safe_normalized_vec(y);

	/* Normalized cross product of vec and proj specifies transformation of the right axis */
	right = proj.cross(vec);
	right.normalize();

	if (axis != upflag) {
		right_index = 3 - axis - upflag;

		/* account for up direction, track direction */
		right = right * basis_cross(axis, upflag);
		mat.setRow(right_index, right);
		mat.setRow(upflag, proj);
		mat.setRow(axis, vec);
		mat = mat.inverse();
	}
	/* identity matrix - don't do anything if the two axes are the same */
	else {
		mat.setIdentity();
	}

	return mat;
}
示例#6
0
bool GPC_RenderTools::RayHit(KX_ClientObjectInfo* client, KX_RayCast* result, void * const data)
{
	double* const oglmatrix = (double* const) data;
	MT_Point3 resultpoint(result->m_hitPoint);
	MT_Vector3 resultnormal(result->m_hitNormal);
	MT_Vector3 left(oglmatrix[0],oglmatrix[1],oglmatrix[2]);
	MT_Vector3 dir = -(left.cross(resultnormal)).safe_normalized();
	left = (dir.cross(resultnormal)).safe_normalized();
	// for the up vector, we take the 'resultnormal' returned by the physics
	
	double maat[16]={
			left[0],        left[1],        left[2], 0,
				dir[0],         dir[1],         dir[2], 0,
		resultnormal[0],resultnormal[1],resultnormal[2], 0,
				0,              0,              0, 1};
	glTranslated(resultpoint[0],resultpoint[1],resultpoint[2]);
	//glMultMatrixd(oglmatrix);
	glMultMatrixd(maat);
	return true;
}
示例#7
0
bool KX_ConstraintActuator::Update(double curtime, bool frame)
{

	bool result = false;
	bool bNegativeEvent = IsNegativeEvent();
	RemoveAllEvents();

	if (!bNegativeEvent) {
		/* Constraint clamps the values to the specified range, with a sort of    */
		/* low-pass filtered time response, if the damp time is unequal to 0.     */

		/* Having to retrieve location/rotation and setting it afterwards may not */
		/* be efficient enough... Something to look at later.                     */
		KX_GameObject  *obj = (KX_GameObject*) GetParent();
		MT_Vector3    position = obj->NodeGetWorldPosition();
		MT_Vector3    newposition;
		MT_Vector3   normal, direction, refDirection;
		MT_Matrix3x3 rotation = obj->NodeGetWorldOrientation();
		MT_Scalar    filter, newdistance, cosangle;
		int axis, sign;

		if (m_posDampTime) {
			filter = m_posDampTime/(1.0f+m_posDampTime);
		} else {
			filter = 0.0f;
		}
		switch (m_locrot) {
		case KX_ACT_CONSTRAINT_ORIX:
		case KX_ACT_CONSTRAINT_ORIY:
		case KX_ACT_CONSTRAINT_ORIZ:
			switch (m_locrot) {
			case KX_ACT_CONSTRAINT_ORIX:
				direction[0] = rotation[0][0];
				direction[1] = rotation[1][0];
				direction[2] = rotation[2][0];
				axis = 0;
				break;
			case KX_ACT_CONSTRAINT_ORIY:
				direction[0] = rotation[0][1];
				direction[1] = rotation[1][1];
				direction[2] = rotation[2][1];
				axis = 1;
				break;
			default:
				direction[0] = rotation[0][2];
				direction[1] = rotation[1][2];
				direction[2] = rotation[2][2];
				axis = 2;
				break;
			}
			if ((m_maximumBound < (1.0f-FLT_EPSILON)) || (m_minimumBound < (1.0f-FLT_EPSILON))) {
				// reference direction needs to be evaluated
				// 1. get the cosine between current direction and target
				cosangle = direction.dot(m_refDirVector);
				if (cosangle >= (m_maximumBound-FLT_EPSILON) && cosangle <= (m_minimumBound+FLT_EPSILON)) {
					// no change to do
					result = true;
					goto CHECK_TIME;
				}
				// 2. define a new reference direction
				//    compute local axis with reference direction as X and
				//    Y in direction X refDirection plane
				MT_Vector3 zaxis = m_refDirVector.cross(direction);
				if (MT_fuzzyZero2(zaxis.length2())) {
					// direction and refDirection are identical,
					// choose any other direction to define plane
					if (direction[0] < 0.9999f)
						zaxis = m_refDirVector.cross(MT_Vector3(1.0f,0.0f,0.0f));
					else
						zaxis = m_refDirVector.cross(MT_Vector3(0.0f,1.0f,0.0f));
				}
				MT_Vector3 yaxis = zaxis.cross(m_refDirVector);
				yaxis.normalize();
				if (cosangle > m_minimumBound) {
					// angle is too close to reference direction,
					// choose a new reference that is exactly at minimum angle
					refDirection = m_minimumBound * m_refDirVector + m_minimumSine * yaxis;
				} else {
					// angle is too large, choose new reference direction at maximum angle
					refDirection = m_maximumBound * m_refDirVector + m_maximumSine * yaxis;
				}
			} else {
				refDirection = m_refDirVector;
			}
			// apply damping on the direction
			direction = filter*direction + (1.0f-filter)*refDirection;
			obj->AlignAxisToVect(direction, axis);
			result = true;
			goto CHECK_TIME;
		case KX_ACT_CONSTRAINT_DIRPX:
		case KX_ACT_CONSTRAINT_DIRPY:
		case KX_ACT_CONSTRAINT_DIRPZ:
		case KX_ACT_CONSTRAINT_DIRNX:
		case KX_ACT_CONSTRAINT_DIRNY:
		case KX_ACT_CONSTRAINT_DIRNZ:
			switch (m_locrot) {
			case KX_ACT_CONSTRAINT_DIRPX:
				normal[0] = rotation[0][0];
				normal[1] = rotation[1][0];
				normal[2] = rotation[2][0];
				axis = 0;		// axis according to KX_GameObject::AlignAxisToVect()
				sign = 0;		// X axis will be parrallel to direction of ray
				break;
			case KX_ACT_CONSTRAINT_DIRPY:
				normal[0] = rotation[0][1];
				normal[1] = rotation[1][1];
				normal[2] = rotation[2][1];
				axis = 1;
				sign = 0;
				break;
			case KX_ACT_CONSTRAINT_DIRPZ:
				normal[0] = rotation[0][2];
				normal[1] = rotation[1][2];
				normal[2] = rotation[2][2];
				axis = 2;
				sign = 0;
				break;
			case KX_ACT_CONSTRAINT_DIRNX:
				normal[0] = -rotation[0][0];
				normal[1] = -rotation[1][0];
				normal[2] = -rotation[2][0];
				axis = 0;
				sign = 1;
				break;
			case KX_ACT_CONSTRAINT_DIRNY:
				normal[0] = -rotation[0][1];
				normal[1] = -rotation[1][1];
				normal[2] = -rotation[2][1];
				axis = 1;
				sign = 1;
				break;
			case KX_ACT_CONSTRAINT_DIRNZ:
				normal[0] = -rotation[0][2];
				normal[1] = -rotation[1][2];
				normal[2] = -rotation[2][2];
				axis = 2;
				sign = 1;
				break;
			}
			normal.normalize();
			if (m_option & KX_ACT_CONSTRAINT_LOCAL) {
				// direction of the ray is along the local axis
				direction = normal;
			} else {
				switch (m_locrot) {
				case KX_ACT_CONSTRAINT_DIRPX:
					direction = MT_Vector3(1.0f,0.0f,0.0f);
					break;
				case KX_ACT_CONSTRAINT_DIRPY:
					direction = MT_Vector3(0.0f,1.0f,0.0f);
					break;
				case KX_ACT_CONSTRAINT_DIRPZ:
					direction = MT_Vector3(0.0f,0.0f,1.0f);
					break;
				case KX_ACT_CONSTRAINT_DIRNX:
					direction = MT_Vector3(-1.0f,0.0f,0.0f);
					break;
				case KX_ACT_CONSTRAINT_DIRNY:
					direction = MT_Vector3(0.0f,-1.0f,0.0f);
					break;
				case KX_ACT_CONSTRAINT_DIRNZ:
					direction = MT_Vector3(0.0f,0.0f,-1.0f);
					break;
				}
			}
			{
				MT_Vector3 topoint = position + (m_maximumBound) * direction;
				PHY_IPhysicsEnvironment* pe = KX_GetActiveScene()->GetPhysicsEnvironment();
				PHY_IPhysicsController *spc = obj->GetPhysicsController();

				if (!pe) {
					CM_LogicBrickWarning(this, "there is no physics environment!");
					goto CHECK_TIME;
				}	 
				if (!spc) {
					// the object is not physical, we probably want to avoid hitting its own parent
					KX_GameObject *parent = obj->GetParent();
					if (parent) {
						spc = parent->GetPhysicsController();
					}
				}
				KX_RayCast::Callback<KX_ConstraintActuator, void> callback(this,dynamic_cast<PHY_IPhysicsController*>(spc));
				result = KX_RayCast::RayTest(pe, position, topoint, callback);
				if (result)	{
					MT_Vector3 newnormal = callback.m_hitNormal;
					// compute new position & orientation
					if ((m_option & (KX_ACT_CONSTRAINT_NORMAL|KX_ACT_CONSTRAINT_DISTANCE)) == 0) {
						// if none option is set, the actuator does nothing but detect ray 
						// (works like a sensor)
						goto CHECK_TIME;
					}
					if (m_option & KX_ACT_CONSTRAINT_NORMAL) {
						MT_Scalar rotFilter;
						// apply damping on the direction
						if (m_rotDampTime) {
							rotFilter = m_rotDampTime/(1.0f+m_rotDampTime);
						} else {
							rotFilter = filter;
						}
						newnormal = rotFilter*normal - (1.0f-rotFilter)*newnormal;
						obj->AlignAxisToVect((sign)?-newnormal:newnormal, axis);
						if (m_option & KX_ACT_CONSTRAINT_LOCAL) {
							direction = newnormal;
							direction.normalize();
						}
					}
					if (m_option & KX_ACT_CONSTRAINT_DISTANCE) {
						if (m_posDampTime) {
							newdistance = filter*(position-callback.m_hitPoint).length()+(1.0f-filter)*m_minimumBound;
						} else {
							newdistance = m_minimumBound;
						}
						// logically we should cancel the speed along the ray direction as we set the
						// position along that axis
						spc = obj->GetPhysicsController();
						if (spc && spc->IsDynamic()) {
							MT_Vector3 linV = spc->GetLinearVelocity();
							// cancel the projection along the ray direction
							MT_Scalar fallspeed = linV.dot(direction);
							if (!MT_fuzzyZero(fallspeed))
								spc->SetLinearVelocity(linV-fallspeed*direction,false);
						}
					} else {
						newdistance = (position-callback.m_hitPoint).length();
					}
					newposition = callback.m_hitPoint-newdistance*direction;
				} else if (m_option & KX_ACT_CONSTRAINT_PERMANENT) {
					// no contact but still keep running
					result = true;
					goto CHECK_TIME;
				}
			}
			break; 
		case KX_ACT_CONSTRAINT_FHPX:
		case KX_ACT_CONSTRAINT_FHPY:
		case KX_ACT_CONSTRAINT_FHPZ:
		case KX_ACT_CONSTRAINT_FHNX:
		case KX_ACT_CONSTRAINT_FHNY:
		case KX_ACT_CONSTRAINT_FHNZ:
			switch (m_locrot) {
			case KX_ACT_CONSTRAINT_FHPX:
				normal[0] = -rotation[0][0];
				normal[1] = -rotation[1][0];
				normal[2] = -rotation[2][0];
				direction = MT_Vector3(1.0f,0.0f,0.0f);
				break;
			case KX_ACT_CONSTRAINT_FHPY:
				normal[0] = -rotation[0][1];
				normal[1] = -rotation[1][1];
				normal[2] = -rotation[2][1];
				direction = MT_Vector3(0.0f,1.0f,0.0f);
				break;
			case KX_ACT_CONSTRAINT_FHPZ:
				normal[0] = -rotation[0][2];
				normal[1] = -rotation[1][2];
				normal[2] = -rotation[2][2];
				direction = MT_Vector3(0.0f,0.0f,1.0f);
				break;
			case KX_ACT_CONSTRAINT_FHNX:
				normal[0] = rotation[0][0];
				normal[1] = rotation[1][0];
				normal[2] = rotation[2][0];
				direction = MT_Vector3(-1.0f,0.0f,0.0f);
				break;
			case KX_ACT_CONSTRAINT_FHNY:
				normal[0] = rotation[0][1];
				normal[1] = rotation[1][1];
				normal[2] = rotation[2][1];
				direction = MT_Vector3(0.0f,-1.0f,0.0f);
				break;
			case KX_ACT_CONSTRAINT_FHNZ:
				normal[0] = rotation[0][2];
				normal[1] = rotation[1][2];
				normal[2] = rotation[2][2];
				direction = MT_Vector3(0.0f,0.0f,-1.0f);
				break;
			}
			normal.normalize();
			{
				PHY_IPhysicsEnvironment* pe = KX_GetActiveScene()->GetPhysicsEnvironment();
				PHY_IPhysicsController *spc = obj->GetPhysicsController();

				if (!pe) {
					CM_LogicBrickWarning(this, "there is no physics environment!");
					goto CHECK_TIME;
				}	 
				if (!spc || !spc->IsDynamic()) {
					// the object is not dynamic, it won't support setting speed
					goto CHECK_TIME;
				}
				m_hitObject = NULL;
				// distance of Fh area is stored in m_minimum
				MT_Vector3 topoint = position + (m_minimumBound+spc->GetRadius()) * direction;
				KX_RayCast::Callback<KX_ConstraintActuator, void> callback(this, spc);
				result = KX_RayCast::RayTest(pe, position, topoint, callback);
				// we expect a hit object
				if (!m_hitObject)
					result = false;
				if (result)
				{
					MT_Vector3 newnormal = callback.m_hitNormal;
					// compute new position & orientation
					MT_Scalar distance = (callback.m_hitPoint-position).length()-spc->GetRadius(); 
					// estimate the velocity of the hit point
					MT_Vector3 relativeHitPoint;
					relativeHitPoint = (callback.m_hitPoint-m_hitObject->NodeGetWorldPosition());
					MT_Vector3 velocityHitPoint = m_hitObject->GetVelocity(relativeHitPoint);
					MT_Vector3 relativeVelocity = spc->GetLinearVelocity() - velocityHitPoint;
					MT_Scalar relativeVelocityRay = direction.dot(relativeVelocity);
					MT_Scalar springExtent = 1.0f - distance/m_minimumBound;
					// Fh force is stored in m_maximum
					MT_Scalar springForce = springExtent * m_maximumBound;
					// damping is stored in m_refDirection [0] = damping, [1] = rot damping
					MT_Scalar springDamp = relativeVelocityRay * m_refDirVector[0];
					MT_Vector3 newVelocity = spc->GetLinearVelocity()-(springForce+springDamp)*direction;
					if (m_option & KX_ACT_CONSTRAINT_NORMAL)
					{
						newVelocity+=(springForce+springDamp)*(newnormal-newnormal.dot(direction)*direction);
					}
					spc->SetLinearVelocity(newVelocity, false);
					if (m_option & KX_ACT_CONSTRAINT_DOROTFH)
					{
						MT_Vector3 angSpring = (normal.cross(newnormal))*m_maximumBound;
						MT_Vector3 angVelocity = spc->GetAngularVelocity();
						// remove component that is parallel to normal
						angVelocity -= angVelocity.dot(newnormal)*newnormal;
						MT_Vector3 angDamp = angVelocity * ((m_refDirVector[1]>MT_EPSILON)?m_refDirVector[1]:m_refDirVector[0]);
						spc->SetAngularVelocity(spc->GetAngularVelocity()+(angSpring-angDamp), false);
					}
				} else if (m_option & KX_ACT_CONSTRAINT_PERMANENT) {
					// no contact but still keep running
					result = true;
				}
				// don't set the position with this constraint
				goto CHECK_TIME;
			}
			break; 
		case KX_ACT_CONSTRAINT_LOCX:
		case KX_ACT_CONSTRAINT_LOCY:
		case KX_ACT_CONSTRAINT_LOCZ:
			newposition = position = obj->GetSGNode()->GetLocalPosition();
			switch (m_locrot) {
			case KX_ACT_CONSTRAINT_LOCX:
				Clamp(newposition[0], m_minimumBound, m_maximumBound);
				break;
			case KX_ACT_CONSTRAINT_LOCY:
				Clamp(newposition[1], m_minimumBound, m_maximumBound);
				break;
			case KX_ACT_CONSTRAINT_LOCZ:
				Clamp(newposition[2], m_minimumBound, m_maximumBound);
				break;
			}
			result = true;
			if (m_posDampTime) {
				newposition = filter*position + (1.0f-filter)*newposition;
			}
			obj->NodeSetLocalPosition(newposition);
			goto CHECK_TIME;
		}
		if (result) {
			// set the new position but take into account parent if any
			obj->NodeSetWorldPosition(newposition);
		}
	CHECK_TIME:
		if (result && m_activeTime > 0 ) {
			if (++m_currentTime >= m_activeTime)
				result = false;
		}
	}
	if (!result) {
		m_currentTime = 0;
	}
	return result;
} /* end of KX_ConstraintActuator::Update(double curtime,double deltatime)   */
示例#8
0
void GPC_RenderTools::applyTransform(RAS_IRasterizer* rasty,double* oglmatrix,int objectdrawmode )
{
	/* FIXME:
	blender: intern/moto/include/MT_Vector3.inl:42: MT_Vector3 operator/(const
	MT_Vector3&, double): Assertion `!MT_fuzzyZero(s)' failed. 
	
	Program received signal SIGABRT, Aborted. 
	[Switching to Thread 16384 (LWP 1519)] 
	0x40477571 in kill () from /lib/libc.so.6 
	(gdb) bt 
	#7  0x08334368 in MT_Vector3::normalized() const () 
	#8  0x0833e6ec in GPC_RenderTools::applyTransform(RAS_IRasterizer*, double*, int) () 
	*/

	if (objectdrawmode & RAS_IPolyMaterial::BILLBOARD_SCREENALIGNED ||
		objectdrawmode & RAS_IPolyMaterial::BILLBOARD_AXISALIGNED)
	{
		// rotate the billboard/halo
		//page 360/361 3D Game Engine Design, David Eberly for a discussion
		// on screen aligned and axis aligned billboards
		// assumed is that the preprocessor transformed all billboard polygons
		// so that their normal points into the positive x direction (1.0 , 0.0 , 0.0)
		// when new parenting for objects is done, this rotation
		// will be moved into the object
		
		MT_Point3 objpos (oglmatrix[12],oglmatrix[13],oglmatrix[14]);
		MT_Point3 campos = rasty->GetCameraPosition();
		MT_Vector3 dir = (campos - objpos).safe_normalized();
		MT_Vector3 up(0,0,1.0);

		KX_GameObject* gameobj = (KX_GameObject*) this->m_clientobject;
		// get scaling of halo object
		MT_Vector3  size = gameobj->GetSGNode()->GetLocalScale();
		
		bool screenaligned = (objectdrawmode & RAS_IPolyMaterial::BILLBOARD_SCREENALIGNED)!=0;//false; //either screen or axisaligned
		if (screenaligned)
		{
			up = (up - up.dot(dir) * dir).safe_normalized();
		} else
		{
			dir = (dir - up.dot(dir)*up).safe_normalized();
		}

		MT_Vector3 left = dir.normalized();
		dir = (left.cross(up)).normalized();

		// we have calculated the row vectors, now we keep
		// local scaling into account:

		left *= size[0];
		dir  *= size[1];
		up   *= size[2];
		double maat[16]={
			left[0], left[1],left[2], 0,
				dir[0], dir[1],dir[2],0,
				up[0],up[1],up[2],0,
				0,0,0,1};
			glTranslated(objpos[0],objpos[1],objpos[2]);
			glMultMatrixd(maat);
			
	} else
	{
		if (objectdrawmode & RAS_IPolyMaterial::SHADOW)
		{
			// shadow must be cast to the ground, physics system needed here!
			MT_Point3 frompoint(oglmatrix[12],oglmatrix[13],oglmatrix[14]);
			KX_GameObject *gameobj = (KX_GameObject*) this->m_clientobject;
			MT_Vector3 direction = MT_Vector3(0,0,-1);

			direction.normalize();
			direction *= 100000;

			MT_Point3 topoint = frompoint + direction;

			KX_Scene* kxscene = (KX_Scene*) m_auxilaryClientInfo;
			PHY_IPhysicsEnvironment* physics_environment = kxscene->GetPhysicsEnvironment();
			KX_IPhysicsController* physics_controller = gameobj->GetPhysicsController();
			
			KX_GameObject *parent = gameobj->GetParent();
			if (!physics_controller && parent)
				physics_controller = parent->GetPhysicsController();
			if (parent)
				parent->Release();
				
			KX_RayCast::Callback<GPC_RenderTools> callback(this, physics_controller, oglmatrix);
			if (!KX_RayCast::RayTest(physics_environment, frompoint, topoint, callback))
			{
				// couldn't find something to cast the shadow on...
				glMultMatrixd(oglmatrix);
			}
		} else
		{

			// 'normal' object
			glMultMatrixd(oglmatrix);
		}
	}
}
示例#9
0
void KX_SteeringActuator::HandleActorFace(MT_Vector3& velocity)
{
	if (m_facingMode==0 && (!m_navmesh || !m_normalUp))
		return;
	KX_GameObject* curobj = (KX_GameObject*) GetParent();
	MT_Vector3 dir = m_facingMode==0 ?  curobj->NodeGetLocalOrientation().getColumn(1) : velocity;
	if (dir.fuzzyZero())
		return;
	dir.normalize();
	MT_Vector3 up(0,0,1);
	MT_Vector3 left;
	MT_Matrix3x3 mat;
	
	if (m_navmesh && m_normalUp)
	{
		dtStatNavMesh* navmesh =  m_navmesh->GetNavMesh();
		MT_Vector3 normal;
		MT_Vector3 trpos = m_navmesh->TransformToLocalCoords(curobj->NodeGetWorldPosition());
		if (getNavmeshNormal(navmesh, trpos, normal))
		{

			left = (dir.cross(up)).safe_normalized();
			dir = (-left.cross(normal)).safe_normalized();
			up = normal;
		}
	}

	switch (m_facingMode)
	{
	case 1: // TRACK X
		{
			left  = dir.safe_normalized();
			dir = -(left.cross(up)).safe_normalized();
			break;
		};
	case 2:	// TRACK Y
		{
			left  = (dir.cross(up)).safe_normalized();
			break;
		}

	case 3: // track Z
		{
			left = up.safe_normalized();
			up = dir.safe_normalized();
			dir = left;
			left  = (dir.cross(up)).safe_normalized();
			break;
		}

	case 4: // TRACK -X
		{
			left  = -dir.safe_normalized();
			dir = -(left.cross(up)).safe_normalized();
			break;
		};
	case 5: // TRACK -Y
		{
			left  = (-dir.cross(up)).safe_normalized();
			dir = -dir;
			break;
		}
	case 6: // track -Z
		{
			left = up.safe_normalized();
			up = -dir.safe_normalized();
			dir = left;
			left  = (dir.cross(up)).safe_normalized();
			break;
		}
	}

	mat.setValue (
		left[0], dir[0],up[0], 
		left[1], dir[1],up[1],
		left[2], dir[2],up[2]
	);

	
	
	KX_GameObject* parentObject = curobj->GetParent();
	if (parentObject)
	{ 
		MT_Vector3 localpos;
		localpos = curobj->GetSGNode()->GetLocalPosition();
		MT_Matrix3x3 parentmatinv;
		parentmatinv = parentObject->NodeGetWorldOrientation ().inverse ();
		mat = parentmatinv * mat;
		mat = m_parentlocalmat * mat;
		curobj->NodeSetLocalOrientation(mat);
		curobj->NodeSetLocalPosition(localpos);
	}
	else
	{
		curobj->NodeSetLocalOrientation(mat);
	}

}
示例#10
0
void IKTree::solveJoint(int frame, int i, IKEffectorList &effList)
{
  double x, y, z;
  double ang = 0;

  MT_Quaternion q;
  MT_Quaternion totalPosRot = MT_Quaternion(0,0,0,0);
  MT_Quaternion totalDirRot = MT_Quaternion(0,0,0,0);
  MT_Vector3 axis(0,0,0);
  BVHNode *n;
  int numPosRot = 0, numDirRot = 0;

  if (bone[i].numChildren == 0) {     // reached end site
    if (bone[i].node->ikOn) {
      effList.index[effList.num++] = i;
    }
    return;
  }

  for (int j=0; j<bone[i].numChildren; j++) {
    IKEffectorList el;
    el.num = 0;
    solveJoint(frame, bone[i].child[j], el);
    for (int k=0; k<el.num; k++) {
      effList.index[effList.num++] = el.index[k];
    }
  }

  updateBones(i);

  for (int j=0; j<effList.num; j++) {
    int effIndex = effList.index[j];
    n = bone[effIndex].node;
    MT_Vector3 effGoalPos(n->ikGoalPos[0],
			  n->ikGoalPos[1],
			  n->ikGoalPos[2]);
    const MT_Vector3 pC =
      (bone[effIndex].pos - bone[i].pos).safe_normalized();
    const MT_Vector3 pD =
      (effGoalPos - bone[i].pos).safe_normalized();
    MT_Vector3 rotAxis = pC.cross(pD);
    if (rotAxis.length2() > MT_EPSILON) {
      totalPosRot += MT_Quaternion(rotAxis, bone[i].weight * acos(pC.dot(pD)));
      numPosRot++;
    }

    const MT_Vector3 uC =
      (bone[effIndex].pos - bone[effIndex-1].pos).safe_normalized();
    const MT_Vector3 uD =
      (MT_Vector3(n->ikGoalDir[0], n->ikGoalDir[1], n->ikGoalDir[2])).safe_normalized();
    rotAxis = uC.cross(uD);
    if (rotAxis.length2() > MT_EPSILON) {
      double weight = 0.0;
      if (i == effIndex-1) weight = 0.5;
      totalDirRot += MT_Quaternion(rotAxis, weight * acos(uC.dot(uD)));
      numDirRot++;
    }
  }

  if ((numPosRot + numDirRot) > MT_EPSILON) {
    n = bone[i].node;
    n->ikOn = true;
    // average the quaternions from all effectors
    if (numPosRot)
      totalPosRot /= numPosRot;
    else
      totalPosRot = identity;
    if (numDirRot)
      totalDirRot /= numDirRot;
    else
      totalDirRot = identity;
    MT_Quaternion targetRot = 0.9 * totalPosRot + 0.1 * totalDirRot;
    targetRot = targetRot * bone[i].lRot;
    toEuler(targetRot, n->channelOrder, x, y, z);
    if (jointLimits) {
      bone[i].lRot = identity;
      for (int k=0; k<n->numChannels; k++) {  // clamp each axis in order
        switch (n->channelType[k]) {
          case BVH_XROT: ang = x; axis = xAxis; break;
          case BVH_YROT: ang = y; axis = yAxis; break;
          case BVH_ZROT: ang = z; axis = zAxis; break;
          default: break;
        }
        // null axis leads to crash in q.setRotation(), so check first
        if(axis.length())
        {
          if (ang < n->channelMin[k]) ang = n->channelMin[k];
          else if (ang > n->channelMax[k]) ang = n->channelMax[k];
          q.setRotation(axis, ang * M_PI / 180);
          bone[i].lRot = q * bone[i].lRot;
        }
      }
    }
    else
      bone[i].lRot = targetRot;
  }
}
示例#11
0
bool KX_TrackToActuator::Update(double curtime, bool frame)
{
	bool result = false;	
	bool bNegativeEvent = IsNegativeEvent();
	RemoveAllEvents();

	if (bNegativeEvent)
	{
		// do nothing on negative events
	}
	else if (m_object)
	{
		KX_GameObject* curobj = (KX_GameObject*) GetParent();
		MT_Vector3 dir = ((KX_GameObject*)m_object)->NodeGetWorldPosition() - curobj->NodeGetWorldPosition();
		if (dir.length2())
			dir.normalize();
		MT_Vector3 up(0,0,1);
		
		
#ifdef DSADSA
		switch (m_upflag)
		{
		case 0:
			{
				up.setValue(1.0,0,0);
				break;
			} 
		case 1:
			{
				up.setValue(0,1.0,0);
				break;
			}
		case 2:
		default:
			{
				up.setValue(0,0,1.0);
			}
		}
#endif 
		if (m_allow3D)
		{
			up = (up - up.dot(dir) * dir).safe_normalized();
			
		}
		else
		{
			dir = (dir - up.dot(dir)*up).safe_normalized();
		}
		
		MT_Vector3 left;
		MT_Matrix3x3 mat;
		
		switch (m_trackflag)
		{
		case 0: // TRACK X
			{
				// (1.0 , 0.0 , 0.0 ) x direction is forward, z (0.0 , 0.0 , 1.0 ) up
				left  = dir.safe_normalized();
				dir = (left.cross(up)).safe_normalized();
				mat.setValue (
					left[0], dir[0],up[0], 
					left[1], dir[1],up[1],
					left[2], dir[2],up[2]
					);
				
				break;
			};
		case 1:	// TRACK Y
			{
				// (0.0 , 1.0 , 0.0 ) y direction is forward, z (0.0 , 0.0 , 1.0 ) up
				left  = (dir.cross(up)).safe_normalized();
				mat.setValue (
					left[0], dir[0],up[0], 
					left[1], dir[1],up[1],
					left[2], dir[2],up[2]
					);
				
				break;
			}
			
		case 2: // track Z
			{
				left = up.safe_normalized();
				up = dir.safe_normalized();
				dir = left;
				left  = (dir.cross(up)).safe_normalized();
				mat.setValue (
					left[0], dir[0],up[0], 
					left[1], dir[1],up[1],
					left[2], dir[2],up[2]
					);
				break;
			}
			
		case 3: // TRACK -X
			{
				// (1.0 , 0.0 , 0.0 ) x direction is forward, z (0.0 , 0.0 , 1.0 ) up
				left  = -dir.safe_normalized();
				dir = -(left.cross(up)).safe_normalized();
				mat.setValue (
					left[0], dir[0],up[0], 
					left[1], dir[1],up[1],
					left[2], dir[2],up[2]
					);
				
				break;
			};
		case 4: // TRACK -Y
			{
				// (0.0 , -1.0 , 0.0 ) -y direction is forward, z (0.0 , 0.0 , 1.0 ) up
				left  = (-dir.cross(up)).safe_normalized();
				mat.setValue (
					left[0], -dir[0],up[0], 
					left[1], -dir[1],up[1],
					left[2], -dir[2],up[2]
					);
				break;
			}
		case 5: // track -Z
			{
				left = up.safe_normalized();
				up = -dir.safe_normalized();
				dir = left;
				left  = (dir.cross(up)).safe_normalized();
				mat.setValue (
					left[0], dir[0],up[0], 
					left[1], dir[1],up[1],
					left[2], dir[2],up[2]
					);
				
				break;
			}
			
		default:
			{
				// (1.0 , 0.0 , 0.0 ) -x direction is forward, z (0.0 , 0.0 , 1.0 ) up
				left  = -dir.safe_normalized();
				dir = -(left.cross(up)).safe_normalized();
				mat.setValue (
					left[0], dir[0],up[0], 
					left[1], dir[1],up[1],
					left[2], dir[2],up[2]
					);
			}
		}
		
		MT_Matrix3x3 oldmat;
		oldmat= curobj->NodeGetWorldOrientation();
		
		/* erwin should rewrite this! */
		mat= matrix3x3_interpol(oldmat, mat, m_time);
		

		if(m_parentobj){ // check if the model is parented and calculate the child transform
				
			MT_Point3 localpos;
			localpos = curobj->GetSGNode()->GetLocalPosition();
			// Get the inverse of the parent matrix
			MT_Matrix3x3 parentmatinv;
			parentmatinv = m_parentobj->NodeGetWorldOrientation ().inverse ();				
			// transform the local coordinate system into the parents system
			mat = parentmatinv * mat;
			// append the initial parent local rotation matrix
			mat = m_parentlocalmat * mat;

			// set the models tranformation properties
			curobj->NodeSetLocalOrientation(mat);
			curobj->NodeSetLocalPosition(localpos);
			//curobj->UpdateTransform();
		}
		else
		{
			curobj->NodeSetLocalOrientation(mat);
		}

		result = true;
	}

	return result;
}