Ejemplo n.º 1
0
void AiCarStandard::AnalyzeOthers(float dt, const CarDynamics cars[], const int cars_num)
{
	const float half_carlength = 1.25;
	const btVector3 throttle_axis = Direction::forward;

	for (int i = 0; i != cars_num; ++i)
	{
		const CarDynamics * icar = &cars[i];
		if (icar != car)
		{
			OtherCarInfo & info = othercars[icar];

			// find direction of other cars in our frame
			btVector3 relative_position = icar->GetCenterOfMass() - car->GetCenterOfMass();
			relative_position = quatRotate(-car->GetOrientation(), relative_position);

			// only make a move if the other car is within our distance limit
			float fore_position = relative_position.dot(throttle_axis);

			btVector3 myvel = quatRotate(-car->GetOrientation(), car->GetVelocity());
			btVector3 othervel = quatRotate(-icar->GetOrientation(), icar->GetVelocity());
			float speed_diff = othervel.dot(throttle_axis) - myvel.dot(throttle_axis);

			const float fore_position_offset = -half_carlength;
			if (fore_position > fore_position_offset)
			{
				const Bezier * othercarpatch = GetCurrentPatch(icar);
				const Bezier * mycarpatch = GetCurrentPatch(car);

				if (othercarpatch && mycarpatch)
				{
					Vec3 mypos = ToMathVector<float>(car->GetCenterOfMass());
					Vec3 otpos = ToMathVector<float>(icar->GetCenterOfMass());
					float my_track_placement = GetHorizontalDistanceAlongPatch(*mycarpatch, mypos);
					float their_track_placement = GetHorizontalDistanceAlongPatch(*othercarpatch, otpos);

					float speed_diff_denom = clamp(speed_diff, -100, -0.01);
					float eta = (fore_position - fore_position_offset) / -speed_diff_denom;

					if (!info.active)
						info.eta = eta;
					else
						info.eta = RateLimit(info.eta, eta, 10.f*dt, 10000.f*dt);

					info.horizontal_distance = their_track_placement - my_track_placement;
					info.fore_distance = fore_position;
					info.active = true;
				}
				else
				{
					info.active = false;
				}
			}
			else
			{
				info.active = false;
			}
		}
	}
}
Ejemplo n.º 2
0
void SpaceObject::fire_laser() {
	if(weapons[activeWeapon]->ammo<600)
		return;
	btTransform trans;
	body->getMotionState()->getWorldTransform(trans);
	btVector3 from = trans.getOrigin() + quatRotate(trans.getRotation() , btVector3(0,0,-10));
	std::cout << body->getOrientation().getX() << "," << body->getOrientation().getY() << "," << body->getOrientation().getZ() << "," << body->getOrientation().getW() << "\n";
	btVector3 to = from + quatRotate(trans.getRotation() , btVector3(0,0,-500));
		
	//Perform ray test.
	btCollisionWorld::ClosestRayResultCallback rayCallback( from, to );
	world->dynamicsWorld->rayTest(from,to,rayCallback);
	//get results.
	if ( rayCallback.hasHit() ) {
		to = rayCallback.m_hitPointWorld;
		// to = ((SpaceObject*)rayCallback.m_collisionObject->getUserPointer())->getRigidBody()->getCenterOfMassPosition();
		ship_hit = (SpaceObject*)rayCallback.m_collisionObject->getUserPointer();
		if(ship_hit->getType() != SKYRISE_TALL && ship_hit->getType()!= SKYRISE_FAT && ship_hit->getType()!= ENDPOINT)
			wasHit = true;
	} //else, do nothing.
	weapons[activeWeapon] -> fireProjectile(from,to);
	fireFrom = from;
	fireTo = to;
	fired = true;
}
Ejemplo n.º 3
0
	btVector3 GetWheelPosition(btScalar displacement_fraction)
	{
		btVector3 up (0, 0, 1);
		btVector3 hinge_end = strut.end - strut.hinge;
		btVector3 end_top = strut.top - strut.end;
		btVector3 hinge_top = strut.top - strut.hinge;

		btVector3 rotaxis = up.cross(hinge_end).normalized();
		btVector3 localwheelpos = info.position - strut.end;

		btScalar hingeradius = hinge_end.length();
		btScalar disp_rad = asin(displacement_fraction * info.travel / hingeradius);

		btQuaternion hingerotate(rotaxis, -disp_rad);

		btScalar e_angle = angle_from_sides(end_top.length(), hinge_end.length(), hinge_top.length());

		hinge_end = quatRotate(hingerotate, hinge_end);

		btScalar e_angle_disp = angle_from_sides(end_top.length(), hinge_end.length(), hinge_top.length());

		rotaxis = up.cross(end_top).normalized();

		mountrot.setRotation(rotaxis, e_angle_disp - e_angle);
		localwheelpos = quatRotate(mountrot, localwheelpos);

		return localwheelpos + strut.hinge + hinge_end;
	}
Ejemplo n.º 4
0
	btVector3 GetWheelPosition(btScalar displacement_fraction)
	{
		btVector3 rel_uc_uh = (hinge[UPPER_HUB] - hinge[UPPER_CHASSIS]),
			rel_lc_lh = (hinge[LOWER_HUB] - hinge[LOWER_CHASSIS]),
			rel_uc_lh = (hinge[LOWER_HUB] - hinge[UPPER_CHASSIS]),
			rel_lc_uh = (hinge[UPPER_HUB] - hinge[LOWER_CHASSIS]),
			rel_uc_lc = (hinge[LOWER_CHASSIS] - hinge[UPPER_CHASSIS]),
			rel_lh_uh = (hinge[UPPER_HUB] - hinge[LOWER_HUB]),
			localwheelpos = (info.position - hinge[LOWER_HUB]);

		btScalar radlc = angle_from_sides(rel_lc_lh.length(), rel_uc_lc.length(), rel_uc_lh.length());
		btScalar lrotrad = -displacement_fraction * info.travel / rel_lc_lh.length();
		btScalar radlcd = radlc + lrotrad;
		btScalar d_uc_lh = side_from_angle(radlcd, rel_lc_lh.length(), rel_uc_lc.length());
		btScalar radlh = angle_from_sides(rel_lc_lh.length(), rel_lh_uh.length(), rel_lc_uh.length());
		btScalar dradlh = (angle_from_sides(rel_lc_lh.length(), d_uc_lh, rel_uc_lc.length()) +
								angle_from_sides(d_uc_lh, rel_lh_uh.length(), rel_uc_uh.length()));

		btVector3 axiswd = -rel_lc_lh.cross(rel_lh_uh);

		btQuaternion hingerot(axis[LOWER_CHASSIS], lrotrad);
		mountrot.setRotation(axiswd, radlh - dradlh);
		rel_lc_lh = quatRotate(hingerot, rel_lc_lh);
		localwheelpos = quatRotate(mountrot, localwheelpos);

		return hinge[LOWER_CHASSIS] + rel_lc_lh + localwheelpos;
	}
btVector3 btMultiBody::worldDirToLocal(int i, const btVector3 &world_dir) const
{
    if (i == -1) {
        return quatRotate(getWorldToBaseRot(), world_dir);
    } else {
        return quatRotate(getParentToLocalRot(i) ,worldDirToLocal(getParent(i), world_dir));
    }
}
Ejemplo n.º 6
0
void SpaceObject::rotate(double pitch, double yaw) {
	btVector3 localXAxis  = quatRotate(body->getOrientation(),btVector3(1,0,0));
	localXAxis*=mouseScalePitch*pitch;
	body->applyTorque(localXAxis);

	btVector3 localYAxis  = quatRotate(body->getOrientation(),btVector3(0,1,0));
	localYAxis*=mouseScaleYaw*yaw;
	body->applyTorque(localYAxis);
	return;
}
btVector3 btMultiBody::worldPosToLocal(int i, const btVector3 &world_pos) const
{
    if (i == -1) {
        // world to base
        return quatRotate(getWorldToBaseRot(),(world_pos - getBasePos()));
    } else {
        // find position in parent frame, then transform to current frame
        return quatRotate(getParentToLocalRot(i),worldPosToLocal(getParent(i), world_pos)) - getRVector(i);
    }
}
btVector3 btMultiBody::localDirToWorld(int i, const btVector3 &local_dir) const
{
    btVector3 result = local_dir;
    while (i != -1) {
        result = quatRotate(getParentToLocalRot(i).inverse() , result);
        i = getParent(i);
    }
    result = quatRotate(getWorldToBaseRot().inverse() , result);
    return result;
}
Ejemplo n.º 9
0
	btRaycastBar2 (btScalar ray_length, btScalar z,btScalar max_y)
	{
		frame_counter = 0;
		ms = 0;
		max_ms = 0;
		min_ms = 9999;
		sum_ms_samples = 0;
		sum_ms = 0;
		dx = 10.0;
		min_x = 0;
		max_x = 0;
		this->max_y = max_y;
		sign = 1.0;
		btScalar dalpha = 2*SIMD_2_PI/NUMRAYS;
		for (int i = 0; i < NUMRAYS; i++)
		{
			btScalar alpha = dalpha * i;
			// rotate around by alpha degrees y 
			btQuaternion q(btVector3(0.0, 1.0, 0.0), alpha);
			direction[i] = btVector3(1.0, 0.0, 0.0);
			direction[i] = quatRotate(q , direction[i]);
			direction[i] = direction[i] * ray_length;
			
			
			source[i] = btVector3(min_x, max_y, z);
			dest[i] = source[i] + direction[i];
			dest[i][1]=-1000;
			normal[i] = btVector3(1.0, 0.0, 0.0);
		}
	}
btVector3 btMultiBody::localPosToWorld(int i, const btVector3 &local_pos) const
{
    btVector3 result = local_pos;
    while (i != -1) {
        // 'result' is in frame i. transform it to frame parent(i)
        result += getRVector(i);
        result = quatRotate(getParentToLocalRot(i).inverse(),result);
        i = getParent(i);
    }

    // 'result' is now in the base frame. transform it to world frame
    result = quatRotate(getWorldToBaseRot().inverse() ,result);
    result += getBasePos();

    return result;
}
Ejemplo n.º 11
0
btVector3 btConeTwistConstraint::GetPointForAngle(btScalar fAngleInRadians, btScalar fLength) const
{
	// compute x/y in ellipse using cone angle (0 -> 2*PI along surface of cone)
	btScalar xEllipse = btCos(fAngleInRadians);
	btScalar yEllipse = btSin(fAngleInRadians);

	// Use the slope of the vector (using x/yEllipse) and find the length
	// of the line that intersects the ellipse:
	//  x^2   y^2
	//  --- + --- = 1, where a and b are semi-major axes 2 and 1 respectively (ie. the limits)
	//  a^2   b^2
	// Do the math and it should be clear.

	float swingLimit = m_swingSpan1; // if xEllipse == 0, just use axis b (1)
	if (fabs(xEllipse) > SIMD_EPSILON)
	{
		btScalar surfaceSlope2 = (yEllipse*yEllipse)/(xEllipse*xEllipse);
		btScalar norm = 1 / (m_swingSpan2 * m_swingSpan2);
		norm += surfaceSlope2 / (m_swingSpan1 * m_swingSpan1);
		btScalar swingLimit2 = (1 + surfaceSlope2) / norm;
		swingLimit = sqrt(swingLimit2);
	}

	// convert into point in constraint space:
	// note: twist is x-axis, swing 1 and 2 are along the z and y axes respectively
	btVector3 vSwingAxis(0, xEllipse, -yEllipse);
	btQuaternion qSwing(vSwingAxis, swingLimit);
	btVector3 vPointInConstraintSpace(fLength,0,0);
	return quatRotate(qSwing, vPointInConstraintSpace);
}
Ejemplo n.º 12
0
btHingeConstraint::btHingeConstraint(btRigidBody& rbA,const btVector3& pivotInA,btVector3& axisInA)
:btTypedConstraint(HINGE_CONSTRAINT_TYPE, rbA), m_angularOnly(false), m_enableAngularMotor(false)
{

	// since no frame is given, assume this to be zero angle and just pick rb transform axis
	// fixed axis in worldspace
	btVector3 rbAxisA1, rbAxisA2;
	btPlaneSpace1(axisInA, rbAxisA1, rbAxisA2);

	m_rbAFrame.getOrigin() = pivotInA;
	m_rbAFrame.getBasis().setValue( rbAxisA1.getX(),rbAxisA2.getX(),axisInA.getX(),
									rbAxisA1.getY(),rbAxisA2.getY(),axisInA.getY(),
									rbAxisA1.getZ(),rbAxisA2.getZ(),axisInA.getZ() );

	btVector3 axisInB = rbA.getCenterOfMassTransform().getBasis() * -axisInA;

	btQuaternion rotationArc = shortestArcQuat(axisInA,axisInB);
	btVector3 rbAxisB1 =  quatRotate(rotationArc,rbAxisA1);
	btVector3 rbAxisB2 = axisInB.cross(rbAxisB1);


	m_rbBFrame.getOrigin() = rbA.getCenterOfMassTransform()(pivotInA);
	m_rbBFrame.getBasis().setValue( rbAxisB1.getX(),rbAxisB2.getX(),axisInB.getX(),
									rbAxisB1.getY(),rbAxisB2.getY(),axisInB.getY(),
									rbAxisB1.getZ(),rbAxisB2.getZ(),axisInB.getZ() );
	
	//start with free
	m_lowerLimit = btScalar(1e30);
	m_upperLimit = btScalar(-1e30);
	m_biasFactor = 0.3f;
	m_relaxationFactor = 1.0f;
	m_limitSoftness = 0.9f;
	m_solveLimit = false;
}
btHingeConstraint::btHingeConstraint(btRigidBody& rbA,const btVector3& pivotInA,const btVector3& axisInA, bool useReferenceFrameA)
:btTypedConstraint(HINGE_CONSTRAINT_TYPE, rbA), m_angularOnly(false), m_enableAngularMotor(false), 
m_useSolveConstraintObsolete(HINGE_USE_OBSOLETE_SOLVER),
m_useOffsetForConstraintFrame(HINGE_USE_FRAME_OFFSET),
m_useReferenceFrameA(useReferenceFrameA),
m_flags(0),m_limit()
{

	// since no frame is given, assume this to be zero angle and just pick rb transform axis
	// fixed axis in worldspace
	btVector3 rbAxisA1, rbAxisA2;
	btPlaneSpace1(axisInA, rbAxisA1, rbAxisA2);

	m_rbAFrame.getOrigin() = pivotInA;
	m_rbAFrame.getBasis().setValue( rbAxisA1.getX(),rbAxisA2.getX(),axisInA.getX(),
									rbAxisA1.getY(),rbAxisA2.getY(),axisInA.getY(),
									rbAxisA1.getZ(),rbAxisA2.getZ(),axisInA.getZ() );

	btVector3 axisInB = rbA.getCenterOfMassTransform().getBasis() * axisInA;

	btQuaternion rotationArc = shortestArcQuat(axisInA,axisInB);
	btVector3 rbAxisB1 =  quatRotate(rotationArc,rbAxisA1);
	btVector3 rbAxisB2 = axisInB.cross(rbAxisB1);


	m_rbBFrame.getOrigin() = rbA.getCenterOfMassTransform()(pivotInA);
	m_rbBFrame.getBasis().setValue( rbAxisB1.getX(),rbAxisB2.getX(),axisInB.getX(),
									rbAxisB1.getY(),rbAxisB2.getY(),axisInB.getY(),
									rbAxisB1.getZ(),rbAxisB2.getZ(),axisInB.getZ() );
	
	m_referenceSign = m_useReferenceFrameA ? btScalar(-1.f) : btScalar(1.f);
}
Ejemplo n.º 14
0
//-----------------------------------------------------------------------------
void AIBaseController::checkPosition(const Vec3 &point, posData *pos_data,
                                     Vec3 *lc, bool use_front_xyz) const
{
    // Convert to local coordinates from the point of view of current kart
    btQuaternion q(btVector3(0, 1, 0), -m_kart->getHeading());
    Vec3 p = point -
        (use_front_xyz ? m_kart->getFrontXYZ() : m_kart->getXYZ());
    Vec3 local_coordinates = quatRotate(q, p);

    // Save local coordinates for later use if needed
    if (lc) *lc = local_coordinates;

    if (pos_data == NULL) return;
    // lhs: tell whether it's left or right hand side
    if (local_coordinates.getX() < 0)
        pos_data->lhs = true;
    else
        pos_data->lhs = false;

    // behind: tell whether it's behind or not
    if (local_coordinates.getZ() < 0)
        pos_data->behind = true;
    else
        pos_data->behind = false;

    pos_data->angle = atan2(fabsf(local_coordinates.getX()),
        fabsf(local_coordinates.getZ()));
    pos_data->distance = p.length();

}   //  checkPosition
Ejemplo n.º 15
0
void btHingeConstraint::setMotorTarget(const btQuaternion& qAinB, btScalar dt)
{
    // convert target from body to constraint space
    btQuaternion qConstraint = m_rbBFrame.getRotation().inverse() * qAinB * m_rbAFrame.getRotation();
    qConstraint.normalize();

    // extract "pure" hinge component
    btVector3 vNoHinge = quatRotate(qConstraint, vHinge);
    vNoHinge.normalize();
    btQuaternion qNoHinge = shortestArcQuat(vHinge, vNoHinge);
    btQuaternion qHinge = qNoHinge.inverse() * qConstraint;
    qHinge.normalize();

    // compute angular target, clamped to limits
    btScalar targetAngle = qHinge.getAngle();
    if (targetAngle > SIMD_PI) // long way around. flip quat and recalculate.
    {
        qHinge = -(qHinge);
        targetAngle = qHinge.getAngle();
    }
    if (qHinge.getZ() < 0)
        targetAngle = -targetAngle;

    setMotorTarget(targetAngle, dt);
}
Ejemplo n.º 16
0
btHingeConstraint::btHingeConstraint(btRigidBody& rbA,btRigidBody& rbB, const btVector3& pivotInA,const btVector3& pivotInB,
									 const btVector3& axisInA,const btVector3& axisInB, bool useReferenceFrameA)
									 :btTypedConstraint(HINGE_CONSTRAINT_TYPE, rbA,rbB),
#ifdef _BT_USE_CENTER_LIMIT_
									 m_limit(),
#endif
									 m_angularOnly(false),
									 m_enableAngularMotor(false),
									 m_useSolveConstraintObsolete(HINGE_USE_OBSOLETE_SOLVER),
									 m_useOffsetForConstraintFrame(HINGE_USE_FRAME_OFFSET),
									 m_useReferenceFrameA(useReferenceFrameA),
									 m_flags(0),
									 m_normalCFM(0),
									 m_normalERP(0),
									 m_stopCFM(0),
									 m_stopERP(0)
{
	m_rbAFrame.getOrigin() = pivotInA;
	
	// since no frame is given, assume this to be zero angle and just pick rb transform axis
	btVector3 rbAxisA1 = rbA.getCenterOfMassTransform().getBasis().getColumn(0);

	btVector3 rbAxisA2;
	btScalar projection = axisInA.dot(rbAxisA1);
	if (projection >= 1.0f - SIMD_EPSILON) {
		rbAxisA1 = -rbA.getCenterOfMassTransform().getBasis().getColumn(2);
		rbAxisA2 = rbA.getCenterOfMassTransform().getBasis().getColumn(1);
	} else if (projection <= -1.0f + SIMD_EPSILON) {
		rbAxisA1 = rbA.getCenterOfMassTransform().getBasis().getColumn(2);
		rbAxisA2 = rbA.getCenterOfMassTransform().getBasis().getColumn(1);      
	} else {
		rbAxisA2 = axisInA.cross(rbAxisA1);
		rbAxisA1 = rbAxisA2.cross(axisInA);
	}

	m_rbAFrame.getBasis().setValue( rbAxisA1.getX(),rbAxisA2.getX(),axisInA.getX(),
									rbAxisA1.getY(),rbAxisA2.getY(),axisInA.getY(),
									rbAxisA1.getZ(),rbAxisA2.getZ(),axisInA.getZ() );

	btQuaternion rotationArc = shortestArcQuat(axisInA,axisInB);
	btVector3 rbAxisB1 =  quatRotate(rotationArc,rbAxisA1);
	btVector3 rbAxisB2 =  axisInB.cross(rbAxisB1);	
	
	m_rbBFrame.getOrigin() = pivotInB;
	m_rbBFrame.getBasis().setValue( rbAxisB1.getX(),rbAxisB2.getX(),axisInB.getX(),
									rbAxisB1.getY(),rbAxisB2.getY(),axisInB.getY(),
									rbAxisB1.getZ(),rbAxisB2.getZ(),axisInB.getZ() );
	
#ifndef	_BT_USE_CENTER_LIMIT_
	//start with free
	m_lowerLimit = btScalar(1.0f);
	m_upperLimit = btScalar(-1.0f);
	m_biasFactor = 0.3f;
	m_relaxationFactor = 1.0f;
	m_limitSoftness = 0.9f;
	m_solveLimit = false;
#endif
	m_referenceSign = m_useReferenceFrameA ? btScalar(-1.f) : btScalar(1.f);
}
Ejemplo n.º 17
0
void SpaceObject::yaw_right() {
	if(body->getAngularVelocity().length2()>maxOmega){
		return;
	}
	btVector3 localYAxis  = quatRotate(body->getOrientation(),btVector3(0,-1,0));
	localYAxis*=scalingOmega;
	body->applyTorque(localYAxis);
}
Ejemplo n.º 18
0
void SpaceObject::roll_right() {
	if((body->getAngularVelocity().length2())>(maxOmega*100.0)){
		return;
	}
	btVector3 localZAxis  = quatRotate(body->getOrientation(),btVector3(0,0,-1));
	localZAxis*=30.0*scalingOmega;
	body->applyTorque(localZAxis);
}
Ejemplo n.º 19
0
void SpaceObject::ascend() {
	if(body->getLinearVelocity().length2()>maxVelocity){
		return;
	}
	btVector3 localYAxis  = quatRotate(body->getOrientation(),btVector3(0,1,0));
	localYAxis*=scalingAcceleration;
	body->applyCentralImpulse(localYAxis);
}
Ejemplo n.º 20
0
void MyCharacterController::updateUpAxis(const glm::quat& rotation) {
    btVector3 oldUp = _currentUp;
    _currentUp = quatRotate(glmToBullet(rotation), LOCAL_UP_AXIS);
    if (!_isHovering) {
        const btScalar MIN_UP_ERROR = 0.01f;
        if (oldUp.distance(_currentUp) > MIN_UP_ERROR) {
            _rigidBody->setGravity(DEFAULT_GRAVITY * _currentUp);
        }
    }
}
Ejemplo n.º 21
0
void LinkState::propagateFK(LinkState *p, JointState *j)
{
    if (p == NULL && j == NULL)
    {
        rel_frame_.setIdentity();
        abs_position_.setValue(0, 0, 0);
        abs_orientation_.setValue(0, 0, 0, 1);
        abs_velocity_.setValue(0, 0, 0);
        abs_rot_velocity_.setValue(0, 0, 0);
    }
    else
    {
        assert(p);
        assert(j);

        abs_position_ =
            p->abs_position_
            + quatRotate(p->abs_orientation_, link_->origin_xyz_)
            + j->getTranslation();

        tf::Quaternion rel_or(link_->origin_rpy_[2], link_->origin_rpy_[1], link_->origin_rpy_[0]);
        abs_orientation_ = p->abs_orientation_ * j->getRotation() * rel_or;
        abs_orientation_.normalize();

        abs_velocity_ =
            p->abs_velocity_
            + cross(p->abs_rot_velocity_, link_->origin_xyz_)
            + j->getTransVelocity();

        abs_rot_velocity_ = p->abs_rot_velocity_ + quatRotate(abs_orientation_, j->getRotVelocity());


        // Computes the relative frame transform
        rel_frame_.setIdentity();
        rel_frame_ *= tf::Transform(tf::Quaternion(0,0,0), link_->origin_xyz_);
        rel_frame_ *= j->getTransform();
        rel_frame_ *= tf::Transform(tf::Quaternion(link_->origin_rpy_[2],
                                    link_->origin_rpy_[1],
                                    link_->origin_rpy_[0]));

        tf::Vector3 jo = j->getTransform().getOrigin();
    }
}
btVector3 btMultiBody::getAngularMomentum() const
{
	int num_links = getNumLinks();
    // TODO: would be better not to allocate memory here
    btAlignedObjectArray<btVector3> omega;omega.resize(num_links+1);
	btAlignedObjectArray<btVector3> vel;vel.resize(num_links+1);
    btAlignedObjectArray<btQuaternion> rot_from_world;rot_from_world.resize(num_links+1);
    compTreeLinkVelocities(&omega[0], &vel[0]);

    rot_from_world[0] = base_quat;
    btVector3 result = quatRotate(rot_from_world[0].inverse() , (base_inertia * omega[0]));

    for (int i = 0; i < num_links; ++i) {
        rot_from_world[i+1] = links[i].cached_rot_parent_to_this * rot_from_world[links[i].parent+1];
        result += (quatRotate(rot_from_world[i+1].inverse() , (links[i].inertia * omega[i+1])));
    }

    return result;
}
Ejemplo n.º 23
0
void System::drawAll(){
	if(updateDraw){
		glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT);
		glEnable(GL_DEPTH_TEST);
		glFrontFace(GL_CCW);
		glCullFace(GL_BACK);
		glEnable(GL_CULL_FACE);
		glDepthFunc(GL_LEQUAL);
		glClearDepth(1.0);

		glPointSize(2);
		glLoadIdentity();


		float4 pitch_quat=CreateFromAxisAngle(cross(dir,camera_up), camera_pitch);
		float4 heading_quat=CreateFromAxisAngle(camera_up, camera_heading);

		dir=quatRotate(dir,normalize(mult(pitch_quat,heading_quat)));
		camera_pos+=camera_pos_delta;
		look_at=camera_pos+dir*1;

		camera_heading*=.5;
		camera_pitch*=.5;
		camera_pos_delta*=.5;

		gluLookAt(	
			camera_pos.x, camera_pos.y, camera_pos.z,
			look_at.x, look_at.y,  look_at.z,
			camera_up.x, camera_up.y,  camera_up.z);

		for(int i=0; i<mSystem->Get_bodylist()->size(); i++){
			ChBody* abody=mSystem->Get_bodylist()->at(i);
			if(abody->GetCollisionModel()->GetShapeType()==SPHERE){
				drawSphere((abody)->GetPos(),(abody)->GetPos_dt().Length(), mSphereRadius);
			}
			if(abody->GetCollisionModel()->GetShapeType()==BOX){
				drawBox(abody,mSphereRadius,mGPUSys);
			}
			if(abody->GetCollisionModel()->GetShapeType()==ELLIPSOID){
				drawSphere(abody,mGPUSys);
			}
			if(abody->GetCollisionModel()->GetShapeType()==TRIANGLEMESH){
				glColor3f (0,0,0);
				drawTriMesh(TriMesh,(abody));
			}
		}

#if defined( _WINDOWS )
		Sleep( 30 );
#else
		usleep( 30 * 1000 );
#endif
		glutSwapBuffers();
	}
}
void btMultiBody::compTreeLinkVelocities(btVector3 *omega, btVector3 *vel) const
{
	int num_links = getNumLinks();
    // Calculates the velocities of each link (and the base) in its local frame
    omega[0] = quatRotate(base_quat ,getBaseOmega());
    vel[0] = quatRotate(base_quat ,getBaseVel());
    
    for (int i = 0; i < num_links; ++i) {
        const int parent = links[i].parent;

        // transform parent vel into this frame, store in omega[i+1], vel[i+1]
        SpatialTransform(btMatrix3x3(links[i].cached_rot_parent_to_this), links[i].cached_r_vector,
                         omega[parent+1], vel[parent+1],
                         omega[i+1], vel[i+1]);

        // now add qidot * shat_i
        omega[i+1] += getJointVel(i) * links[i].axis_top;
        vel[i+1] += getJointVel(i) * links[i].axis_bottom;
    }
}
Ejemplo n.º 25
0
static PyObject *
Quaternion_quatRotate(bulletphysics_QuaternionObject *self, PyObject *args, PyObject *kwds) {
        bulletphysics_QuaternionObject *py_quaternion = NULL;
        bulletphysics_Vector3Object *py_vector3 = NULL;
        if (!PyArg_ParseTuple(args, "OO", &py_quaternion, &py_vector3)) {
                return NULL;
        }
        pybulletphysics_checktype(py_quaternion, Quaternion);
        pybulletphysics_checktype(py_vector3, Vector3);
	return new_pyvector3_from_vector(quatRotate(*(py_quaternion->quaternion), *(py_vector3->vector)));
}
Ejemplo n.º 26
0
btVector3 btRigidBody::computeGyroscopicImpulseImplicit_Body(btScalar step) const
{	
	btVector3 idl = getLocalInertia();
	btVector3 omega1 = getAngularVelocity();
	btQuaternion q = getWorldTransform().getRotation();
	
	// Convert to body coordinates
	btVector3 omegab = quatRotate(q.inverse(), omega1);
	btMatrix3x3 Ib;
	Ib.setValue(idl.x(),0,0,
				0,idl.y(),0,
				0,0,idl.z());
	
	btVector3 ibo = Ib*omegab;

	// Residual vector
	btVector3 f = step * omegab.cross(ibo);
	
	btMatrix3x3 skew0;
	omegab.getSkewSymmetricMatrix(&skew0[0], &skew0[1], &skew0[2]);
	btVector3 om = Ib*omegab;
	btMatrix3x3 skew1;
	om.getSkewSymmetricMatrix(&skew1[0],&skew1[1],&skew1[2]);
	
	// Jacobian
	btMatrix3x3 J = Ib +  (skew0*Ib - skew1)*step;
	
//	btMatrix3x3 Jinv = J.inverse();
//	btVector3 omega_div = Jinv*f;
	btVector3 omega_div = J.solve33(f);
	
	// Single Newton-Raphson update
	omegab = omegab - omega_div;//Solve33(J, f);
	// Back to world coordinates
	btVector3 omega2 = quatRotate(q,omegab);
	btVector3 gf = omega2-omega1;
	return gf;
}
Ejemplo n.º 27
0
void btConeTwistConstraint::setMotorTargetInConstraintSpace(const btQuaternion &q)
{
	m_qTarget = q;

	// clamp motor target to within limits
	{
		btScalar softness = 1.f;//m_limitSoftness;

		// split into twist and cone
		btVector3 vTwisted = quatRotate(m_qTarget, vTwist);
		btQuaternion qTargetCone  = shortestArcQuat(vTwist, vTwisted); qTargetCone.normalize();
		btQuaternion qTargetTwist = qTargetCone.inverse() * m_qTarget; qTargetTwist.normalize();

		// clamp cone
		if (m_swingSpan1 >= btScalar(0.05f) && m_swingSpan2 >= btScalar(0.05f))
		{
			btScalar swingAngle, swingLimit; btVector3 swingAxis;
			computeConeLimitInfo(qTargetCone, swingAngle, swingAxis, swingLimit);

			if (fabs(swingAngle) > SIMD_EPSILON)
			{
				if (swingAngle > swingLimit*softness)
					swingAngle = swingLimit*softness;
				else if (swingAngle < -swingLimit*softness)
					swingAngle = -swingLimit*softness;
				qTargetCone = btQuaternion(swingAxis, swingAngle);
			}
		}

		// clamp twist
		if (m_twistSpan >= btScalar(0.05f))
		{
			btScalar twistAngle; btVector3 twistAxis;
			computeTwistLimitInfo(qTargetTwist, twistAngle, twistAxis);

			if (fabs(twistAngle) > SIMD_EPSILON)
			{
				// eddy todo: limitSoftness used here???
				if (twistAngle > m_twistSpan*softness)
					twistAngle = m_twistSpan*softness;
				else if (twistAngle < -m_twistSpan*softness)
					twistAngle = -m_twistSpan*softness;
				qTargetTwist = btQuaternion(twistAxis, twistAngle);
			}
		}

		m_qTarget = qTargetCone * qTargetTwist;
	}
}
Ejemplo n.º 28
0
// Movement for free moving cameras
void _Camera::HandleMove(const btVector3 &Direction, float Speed) {
	switch(Type) {
		case FREEMOVE: {
			if(!Direction.isZero()) {

				btVector3 Move(Direction);
				Move.normalize();
				Move *= Speed;
				btQuaternion Orientation(Game.Camera->getOrientation().x, Game.Camera->getOrientation().y, Game.Camera->getOrientation().z, Game.Camera->getOrientation().w);
				Velocity = quatRotate(Orientation, Move);
			}
			else
				Velocity.setZero();
		} break;
	}
}
Ejemplo n.º 29
0
btHingeConstraint::btHingeConstraint(btRigidBody& rbA,btRigidBody& rbB, const btVector3& pivotInA,const btVector3& pivotInB,
									 btVector3& axisInA,btVector3& axisInB)
									 :btTypedConstraint(HINGE_CONSTRAINT_TYPE, rbA,rbB),
									 m_angularOnly(false),
									 m_enableAngularMotor(false)
{
	m_rbAFrame.getOrigin() = pivotInA;
	
	// since no frame is given, assume this to be zero angle and just pick rb transform axis
	btVector3 rbAxisA1 = rbA.getCenterOfMassTransform().getBasis().getColumn(0);

	btVector3 rbAxisA2;
	btScalar projection = axisInA.dot(rbAxisA1);
	if (projection >= 1.0f - SIMD_EPSILON) {
		rbAxisA1 = -rbA.getCenterOfMassTransform().getBasis().getColumn(2);
		rbAxisA2 = rbA.getCenterOfMassTransform().getBasis().getColumn(1);
	} else if (projection <= -1.0f + SIMD_EPSILON) {
		rbAxisA1 = rbA.getCenterOfMassTransform().getBasis().getColumn(2);
		rbAxisA2 = rbA.getCenterOfMassTransform().getBasis().getColumn(1);      
	} else {
		rbAxisA2 = axisInA.cross(rbAxisA1);
		rbAxisA1 = rbAxisA2.cross(axisInA);
	}

	m_rbAFrame.getBasis().setValue( rbAxisA1.getX(),rbAxisA2.getX(),axisInA.getX(),
									rbAxisA1.getY(),rbAxisA2.getY(),axisInA.getY(),
									rbAxisA1.getZ(),rbAxisA2.getZ(),axisInA.getZ() );

	btQuaternion rotationArc = shortestArcQuat(axisInA,axisInB);
	btVector3 rbAxisB1 =  quatRotate(rotationArc,rbAxisA1);
	btVector3 rbAxisB2 =  axisInB.cross(rbAxisB1);	
	
	m_rbBFrame.getOrigin() = pivotInB;
	m_rbBFrame.getBasis().setValue( rbAxisB1.getX(),rbAxisB2.getX(),-axisInB.getX(),
									rbAxisB1.getY(),rbAxisB2.getY(),-axisInB.getY(),
									rbAxisB1.getZ(),rbAxisB2.getZ(),-axisInB.getZ() );
	
	//start with free
	m_lowerLimit = btScalar(1e30);
	m_upperLimit = btScalar(-1e30);
	m_biasFactor = 0.3f;
	m_relaxationFactor = 1.0f;
	m_limitSoftness = 0.9f;
	m_solveLimit = false;

}
Ejemplo n.º 30
0
void BulletDS::updateCollisionObjects() const
{

  for(CollisionObjects::iterator ico = _collisionObjects->begin();
      ico != _collisionObjects->end(); ++ ico)

  {

    SP::btCollisionObject collisionObject = boost::get<0>((*ico).second);
    OffSet offset = boost::get<1>((*ico).second);

    SiconosVector& q = *_q;

    DEBUG_EXPR(q.display());

    /* with 32bits input ... 1e-7 */
    assert(fabs(sqrt(pow(q(3), 2) + pow(q(4), 2) +
                   pow(q(5), 2) +  pow(q(6), 2)) - 1.) < 1e-7);

    btQuaternion rbase = btQuaternion(q(4), q(5), q(6), q(3));

    btVector3 boffset = btVector3(offset[0], offset[1], offset[2]);

    btVector3 rboffset = quatRotate(rbase, boffset);

    collisionObject->getWorldTransform().setOrigin(btVector3(q(0)+rboffset[0],
                                                             q(1)+rboffset[1],
                                                             q(2)+rboffset[2]));
    collisionObject->getWorldTransform().getBasis().
      setRotation(rbase * btQuaternion(offset[4], offset[5],
                                       offset[6], offset[3]));

    /* is this needed ? */
    collisionObject->setActivationState(ACTIVE_TAG);
    collisionObject->activate();

  //_collisionObject->setContactProcessingThreshold(BT_LARGE_FLOAT);

  }
}