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source: code/trunk/src/external/bullet/BulletDynamics/Dynamics/btRigidBody.h @ 11110

Last change on this file since 11110 was 8393, checked in by rgrieder, 14 years ago

Updated Bullet from v2.77 to v2.78.
(I'm not going to make a branch for that since the update from 2.74 to 2.77 hasn't been tested that much either).

You will HAVE to do a complete RECOMPILE! I tested with MSVC and MinGW and they both threw linker errors at me.

Property svn:eol-style set to native

File size: 19.4 KB

Rev	Line
[1963]	1	/*
	2	Bullet Continuous Collision Detection and Physics Library
	3	Copyright (c) 2003-2006 Erwin Coumans http://continuousphysics.com/Bullet/
	4
	5	This software is provided 'as-is', without any express or implied warranty.
	6	In no event will the authors be held liable for any damages arising from the use of this software.
	7	Permission is granted to anyone to use this software for any purpose,
	8	including commercial applications, and to alter it and redistribute it freely,
	9	subject to the following restrictions:
	10
	11	1. The origin of this software must not be misrepresented; you must not claim that you wrote the original software. If you use this software in a product, an acknowledgment in the product documentation would be appreciated but is not required.
	12	2. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software.
	13	3. This notice may not be removed or altered from any source distribution.
	14	*/
	15
[8393]	16	#ifndef BT_RIGIDBODY_H
	17	#define BT_RIGIDBODY_H
[1963]	18
	19	#include "LinearMath/btAlignedObjectArray.h"
	20	#include "LinearMath/btTransform.h"
	21	#include "BulletCollision/BroadphaseCollision/btBroadphaseProxy.h"
	22	#include "BulletCollision/CollisionDispatch/btCollisionObject.h"
	23
	24	class btCollisionShape;
	25	class btMotionState;
	26	class btTypedConstraint;
	27
	28
	29	extern btScalar gDeactivationTime;
	30	extern bool gDisableDeactivation;
	31
[8351]	32	#ifdef BT_USE_DOUBLE_PRECISION
	33	#define btRigidBodyData btRigidBodyDoubleData
	34	#define btRigidBodyDataName "btRigidBodyDoubleData"
	35	#else
	36	#define btRigidBodyData btRigidBodyFloatData
	37	#define btRigidBodyDataName "btRigidBodyFloatData"
	38	#endif //BT_USE_DOUBLE_PRECISION
[1963]	39
[8351]	40
	41	enum btRigidBodyFlags
	42	{
	43	BT_DISABLE_WORLD_GRAVITY = 1
	44	};
	45
	46
[2430]	47	///The btRigidBody is the main class for rigid body objects. It is derived from btCollisionObject, so it keeps a pointer to a btCollisionShape.
[1963]	48	///It is recommended for performance and memory use to share btCollisionShape objects whenever possible.
	49	///There are 3 types of rigid bodies:
	50	///- A) Dynamic rigid bodies, with positive mass. Motion is controlled by rigid body dynamics.
	51	///- B) Fixed objects with zero mass. They are not moving (basically collision objects)
	52	///- C) Kinematic objects, which are objects without mass, but the user can move them. There is on-way interaction, and Bullet calculates a velocity based on the timestep and previous and current world transform.
	53	///Bullet automatically deactivates dynamic rigid bodies, when the velocity is below a threshold for a given time.
	54	///Deactivated (sleeping) rigid bodies don't take any processing time, except a minor broadphase collision detection impact (to allow active objects to activate/wake up sleeping objects)
	55	class btRigidBody : public btCollisionObject
	56	{
	57
	58	btMatrix3x3 m_invInertiaTensorWorld;
	59	btVector3 m_linearVelocity;
	60	btVector3 m_angularVelocity;
	61	btScalar m_inverseMass;
[8351]	62	btVector3 m_linearFactor;
[1963]	63
	64	btVector3 m_gravity;
[2882]	65	btVector3 m_gravity_acceleration;
[1963]	66	btVector3 m_invInertiaLocal;
	67	btVector3 m_totalForce;
	68	btVector3 m_totalTorque;
	69
	70	btScalar m_linearDamping;
	71	btScalar m_angularDamping;
	72
	73	bool m_additionalDamping;
	74	btScalar m_additionalDampingFactor;
	75	btScalar m_additionalLinearDampingThresholdSqr;
	76	btScalar m_additionalAngularDampingThresholdSqr;
	77	btScalar m_additionalAngularDampingFactor;
	78
	79
	80	btScalar m_linearSleepingThreshold;
	81	btScalar m_angularSleepingThreshold;
	82
	83	//m_optionalMotionState allows to automatic synchronize the world transform for active objects
	84	btMotionState* m_optionalMotionState;
	85
	86	//keep track of typed constraints referencing this rigid body
	87	btAlignedObjectArray<btTypedConstraint*> m_constraintRefs;
	88
[8351]	89	int m_rigidbodyFlags;
	90
	91	int m_debugBodyId;
[8393]	92
[8351]	93
	94	protected:
	95
	96	ATTRIBUTE_ALIGNED64(btVector3 m_deltaLinearVelocity);
	97	btVector3 m_deltaAngularVelocity;
	98	btVector3 m_angularFactor;
	99	btVector3 m_invMass;
	100	btVector3 m_pushVelocity;
	101	btVector3 m_turnVelocity;
	102
	103
[1963]	104	public:
	105
	106
[2430]	107	///The btRigidBodyConstructionInfo structure provides information to create a rigid body. Setting mass to zero creates a fixed (non-dynamic) rigid body.
[1963]	108	///For dynamic objects, you can use the collision shape to approximate the local inertia tensor, otherwise use the zero vector (default argument)
	109	///You can use the motion state to synchronize the world transform between physics and graphics objects.
	110	///And if the motion state is provided, the rigid body will initialize its initial world transform from the motion state,
	111	///m_startWorldTransform is only used when you don't provide a motion state.
	112	struct btRigidBodyConstructionInfo
	113	{
	114	btScalar m_mass;
	115
	116	///When a motionState is provided, the rigid body will initialize its world transform from the motion state
	117	///In this case, m_startWorldTransform is ignored.
	118	btMotionState* m_motionState;
	119	btTransform m_startWorldTransform;
	120
	121	btCollisionShape* m_collisionShape;
	122	btVector3 m_localInertia;
	123	btScalar m_linearDamping;
	124	btScalar m_angularDamping;
	125
	126	///best simulation results when friction is non-zero
	127	btScalar m_friction;
	128	///best simulation results using zero restitution.
	129	btScalar m_restitution;
	130
	131	btScalar m_linearSleepingThreshold;
	132	btScalar m_angularSleepingThreshold;
	133
	134	//Additional damping can help avoiding lowpass jitter motion, help stability for ragdolls etc.
	135	//Such damping is undesirable, so once the overall simulation quality of the rigid body dynamics system has improved, this should become obsolete
	136	bool m_additionalDamping;
	137	btScalar m_additionalDampingFactor;
	138	btScalar m_additionalLinearDampingThresholdSqr;
	139	btScalar m_additionalAngularDampingThresholdSqr;
	140	btScalar m_additionalAngularDampingFactor;
	141
	142	btRigidBodyConstructionInfo( btScalar mass, btMotionState* motionState, btCollisionShape* collisionShape, const btVector3& localInertia=btVector3(0,0,0)):
	143	m_mass(mass),
	144	m_motionState(motionState),
	145	m_collisionShape(collisionShape),
	146	m_localInertia(localInertia),
	147	m_linearDamping(btScalar(0.)),
	148	m_angularDamping(btScalar(0.)),
	149	m_friction(btScalar(0.5)),
	150	m_restitution(btScalar(0.)),
	151	m_linearSleepingThreshold(btScalar(0.8)),
	152	m_angularSleepingThreshold(btScalar(1.f)),
	153	m_additionalDamping(false),
	154	m_additionalDampingFactor(btScalar(0.005)),
	155	m_additionalLinearDampingThresholdSqr(btScalar(0.01)),
	156	m_additionalAngularDampingThresholdSqr(btScalar(0.01)),
	157	m_additionalAngularDampingFactor(btScalar(0.01))
	158	{
	159	m_startWorldTransform.setIdentity();
	160	}
	161	};
	162
	163	///btRigidBody constructor using construction info
	164	btRigidBody( const btRigidBodyConstructionInfo& constructionInfo);
	165
	166	///btRigidBody constructor for backwards compatibility.
	167	///To specify friction (etc) during rigid body construction, please use the other constructor (using btRigidBodyConstructionInfo)
	168	btRigidBody( btScalar mass, btMotionState* motionState, btCollisionShape* collisionShape, const btVector3& localInertia=btVector3(0,0,0));
	169
	170
	171	virtual ~btRigidBody()
	172	{
	173	//No constraints should point to this rigidbody
	174	//Remove constraints from the dynamics world before you delete the related rigidbodies.
	175	btAssert(m_constraintRefs.size()==0);
	176	}
	177
	178	protected:
	179
	180	///setupRigidBody is only used internally by the constructor
	181	void setupRigidBody(const btRigidBodyConstructionInfo& constructionInfo);
	182
	183	public:
	184
	185	void proceedToTransform(const btTransform& newTrans);
	186
	187	///to keep collision detection and dynamics separate we don't store a rigidbody pointer
	188	///but a rigidbody is derived from btCollisionObject, so we can safely perform an upcast
	189	static const btRigidBody* upcast(const btCollisionObject* colObj)
	190	{
[8351]	191	if (colObj->getInternalType()&btCollisionObject::CO_RIGID_BODY)
[1963]	192	return (const btRigidBody*)colObj;
	193	return 0;
	194	}
	195	static btRigidBody* upcast(btCollisionObject* colObj)
	196	{
[8351]	197	if (colObj->getInternalType()&btCollisionObject::CO_RIGID_BODY)
[1963]	198	return (btRigidBody*)colObj;
	199	return 0;
	200	}
	201
	202	/// continuous collision detection needs prediction
	203	void predictIntegratedTransform(btScalar step, btTransform& predictedTransform) ;
	204
	205	void saveKinematicState(btScalar step);
	206
	207	void applyGravity();
	208
	209	void setGravity(const btVector3& acceleration);
	210
	211	const btVector3& getGravity() const
	212	{
[2882]	213	return m_gravity_acceleration;
[1963]	214	}
	215
	216	void setDamping(btScalar lin_damping, btScalar ang_damping);
	217
	218	btScalar getLinearDamping() const
	219	{
	220	return m_linearDamping;
	221	}
	222
	223	btScalar getAngularDamping() const
	224	{
	225	return m_angularDamping;
	226	}
	227
	228	btScalar getLinearSleepingThreshold() const
	229	{
	230	return m_linearSleepingThreshold;
	231	}
	232
	233	btScalar getAngularSleepingThreshold() const
	234	{
	235	return m_angularSleepingThreshold;
	236	}
	237
	238	void applyDamping(btScalar timeStep);
	239
	240	SIMD_FORCE_INLINE const btCollisionShape* getCollisionShape() const {
	241	return m_collisionShape;
	242	}
	243
	244	SIMD_FORCE_INLINE btCollisionShape* getCollisionShape() {
	245	return m_collisionShape;
	246	}
	247
	248	void setMassProps(btScalar mass, const btVector3& inertia);
	249
[8351]	250	const btVector3& getLinearFactor() const
	251	{
	252	return m_linearFactor;
	253	}
	254	void setLinearFactor(const btVector3& linearFactor)
	255	{
	256	m_linearFactor = linearFactor;
	257	m_invMass = m_linearFactor*m_inverseMass;
	258	}
[1963]	259	btScalar getInvMass() const { return m_inverseMass; }
	260	const btMatrix3x3& getInvInertiaTensorWorld() const {
	261	return m_invInertiaTensorWorld;
	262	}
	263
	264	void integrateVelocities(btScalar step);
	265
	266	void setCenterOfMassTransform(const btTransform& xform);
	267
	268	void applyCentralForce(const btVector3& force)
	269	{
[8351]	270	m_totalForce += force*m_linearFactor;
[1963]	271	}
[2882]	272
[8393]	273	const btVector3& getTotalForce() const
[2882]	274	{
	275	return m_totalForce;
	276	};
	277
[8393]	278	const btVector3& getTotalTorque() const
[2882]	279	{
	280	return m_totalTorque;
	281	};
[1963]	282
[2882]	283	const btVector3& getInvInertiaDiagLocal() const
[1963]	284	{
	285	return m_invInertiaLocal;
	286	};
	287
	288	void setInvInertiaDiagLocal(const btVector3& diagInvInertia)
	289	{
	290	m_invInertiaLocal = diagInvInertia;
	291	}
	292
	293	void setSleepingThresholds(btScalar linear,btScalar angular)
	294	{
	295	m_linearSleepingThreshold = linear;
	296	m_angularSleepingThreshold = angular;
	297	}
	298
	299	void applyTorque(const btVector3& torque)
	300	{
[8351]	301	m_totalTorque += torque*m_angularFactor;
[1963]	302	}
	303
	304	void applyForce(const btVector3& force, const btVector3& rel_pos)
	305	{
	306	applyCentralForce(force);
[8351]	307	applyTorque(rel_pos.cross(force*m_linearFactor));
[1963]	308	}
	309
	310	void applyCentralImpulse(const btVector3& impulse)
	311	{
[8351]	312	m_linearVelocity += impulse m_linearFactor m_inverseMass;
[1963]	313	}
	314
	315	void applyTorqueImpulse(const btVector3& torque)
	316	{
[8351]	317	m_angularVelocity += m_invInertiaTensorWorld * torque * m_angularFactor;
[1963]	318	}
	319
	320	void applyImpulse(const btVector3& impulse, const btVector3& rel_pos)
	321	{
	322	if (m_inverseMass != btScalar(0.))
	323	{
	324	applyCentralImpulse(impulse);
	325	if (m_angularFactor)
	326	{
[8351]	327	applyTorqueImpulse(rel_pos.cross(impulse*m_linearFactor));
[1963]	328	}
	329	}
	330	}
	331
	332	void clearForces()
	333	{
	334	m_totalForce.setValue(btScalar(0.0), btScalar(0.0), btScalar(0.0));
	335	m_totalTorque.setValue(btScalar(0.0), btScalar(0.0), btScalar(0.0));
	336	}
	337
	338	void updateInertiaTensor();
	339
[2430]	340	const btVector3& getCenterOfMassPosition() const {
[1963]	341	return m_worldTransform.getOrigin();
	342	}
	343	btQuaternion getOrientation() const;
	344
	345	const btTransform& getCenterOfMassTransform() const {
	346	return m_worldTransform;
	347	}
	348	const btVector3& getLinearVelocity() const {
	349	return m_linearVelocity;
	350	}
	351	const btVector3& getAngularVelocity() const {
	352	return m_angularVelocity;
	353	}
	354
	355
	356	inline void setLinearVelocity(const btVector3& lin_vel)
	357	{
	358	m_linearVelocity = lin_vel;
	359	}
	360
[2430]	361	inline void setAngularVelocity(const btVector3& ang_vel)
	362	{
	363	m_angularVelocity = ang_vel;
[1963]	364	}
	365
	366	btVector3 getVelocityInLocalPoint(const btVector3& rel_pos) const
	367	{
	368	//we also calculate lin/ang velocity for kinematic objects
	369	return m_linearVelocity + m_angularVelocity.cross(rel_pos);
	370
	371	//for kinematic objects, we could also use use:
	372	// return (m_worldTransform(rel_pos) - m_interpolationWorldTransform(rel_pos)) / m_kinematicTimeStep;
	373	}
	374
	375	void translate(const btVector3& v)
	376	{
	377	m_worldTransform.getOrigin() += v;
	378	}
	379
	380
	381	void getAabb(btVector3& aabbMin,btVector3& aabbMax) const;
	382
	383
	384
	385
	386
[2430]	387	SIMD_FORCE_INLINE btScalar computeImpulseDenominator(const btVector3& pos, const btVector3& normal) const
[1963]	388	{
	389	btVector3 r0 = pos - getCenterOfMassPosition();
	390
	391	btVector3 c0 = (r0).cross(normal);
	392
	393	btVector3 vec = (c0 * getInvInertiaTensorWorld()).cross(r0);
	394
	395	return m_inverseMass + normal.dot(vec);
	396
	397	}
	398
	399	SIMD_FORCE_INLINE btScalar computeAngularImpulseDenominator(const btVector3& axis) const
	400	{
	401	btVector3 vec = axis * getInvInertiaTensorWorld();
	402	return axis.dot(vec);
	403	}
	404
	405	SIMD_FORCE_INLINE void updateDeactivation(btScalar timeStep)
	406	{
	407	if ( (getActivationState() == ISLAND_SLEEPING) \|\| (getActivationState() == DISABLE_DEACTIVATION))
	408	return;
	409
	410	if ((getLinearVelocity().length2() < m_linearSleepingThreshold*m_linearSleepingThreshold) &&
	411	(getAngularVelocity().length2() < m_angularSleepingThreshold*m_angularSleepingThreshold))
	412	{
	413	m_deactivationTime += timeStep;
	414	} else
	415	{
	416	m_deactivationTime=btScalar(0.);
	417	setActivationState(0);
	418	}
	419
	420	}
	421
	422	SIMD_FORCE_INLINE bool wantsSleeping()
	423	{
	424
	425	if (getActivationState() == DISABLE_DEACTIVATION)
	426	return false;
	427
	428	//disable deactivation
	429	if (gDisableDeactivation \|\| (gDeactivationTime == btScalar(0.)))
	430	return false;
	431
	432	if ( (getActivationState() == ISLAND_SLEEPING) \|\| (getActivationState() == WANTS_DEACTIVATION))
	433	return true;
	434
	435	if (m_deactivationTime> gDeactivationTime)
	436	{
	437	return true;
	438	}
	439	return false;
	440	}
	441
	442
	443
	444	const btBroadphaseProxy* getBroadphaseProxy() const
	445	{
	446	return m_broadphaseHandle;
	447	}
	448	btBroadphaseProxy* getBroadphaseProxy()
	449	{
	450	return m_broadphaseHandle;
	451	}
	452	void setNewBroadphaseProxy(btBroadphaseProxy* broadphaseProxy)
	453	{
	454	m_broadphaseHandle = broadphaseProxy;
	455	}
	456
	457	//btMotionState allows to automatic synchronize the world transform for active objects
	458	btMotionState* getMotionState()
	459	{
	460	return m_optionalMotionState;
	461	}
	462	const btMotionState* getMotionState() const
	463	{
	464	return m_optionalMotionState;
	465	}
	466	void setMotionState(btMotionState* motionState)
	467	{
	468	m_optionalMotionState = motionState;
	469	if (m_optionalMotionState)
	470	motionState->getWorldTransform(m_worldTransform);
	471	}
	472
	473	//for experimental overriding of friction/contact solver func
	474	int m_contactSolverType;
	475	int m_frictionSolverType;
	476
[8351]	477	void setAngularFactor(const btVector3& angFac)
[1963]	478	{
	479	m_angularFactor = angFac;
	480	}
[8351]	481
	482	void setAngularFactor(btScalar angFac)
[1963]	483	{
[8351]	484	m_angularFactor.setValue(angFac,angFac,angFac);
	485	}
	486	const btVector3& getAngularFactor() const
	487	{
[1963]	488	return m_angularFactor;
	489	}
	490
	491	//is this rigidbody added to a btCollisionWorld/btDynamicsWorld/btBroadphase?
	492	bool isInWorld() const
	493	{
	494	return (getBroadphaseProxy() != 0);
	495	}
	496
	497	virtual bool checkCollideWithOverride(btCollisionObject* co);
	498
	499	void addConstraintRef(btTypedConstraint* c);
	500	void removeConstraintRef(btTypedConstraint* c);
	501
	502	btTypedConstraint* getConstraintRef(int index)
	503	{
	504	return m_constraintRefs[index];
	505	}
	506
[8393]	507	int getNumConstraintRefs() const
[1963]	508	{
	509	return m_constraintRefs.size();
	510	}
	511
[8351]	512	void setFlags(int flags)
	513	{
	514	m_rigidbodyFlags = flags;
	515	}
	516
	517	int getFlags() const
	518	{
	519	return m_rigidbodyFlags;
	520	}
	521
	522	const btVector3& getDeltaLinearVelocity() const
	523	{
	524	return m_deltaLinearVelocity;
	525	}
	526
	527	const btVector3& getDeltaAngularVelocity() const
	528	{
	529	return m_deltaAngularVelocity;
	530	}
	531
	532	const btVector3& getPushVelocity() const
	533	{
	534	return m_pushVelocity;
	535	}
	536
	537	const btVector3& getTurnVelocity() const
	538	{
	539	return m_turnVelocity;
	540	}
	541
	542
	543	////////////////////////////////////////////////
	544	///some internal methods, don't use them
	545
	546	btVector3& internalGetDeltaLinearVelocity()
	547	{
	548	return m_deltaLinearVelocity;
	549	}
	550
	551	btVector3& internalGetDeltaAngularVelocity()
	552	{
	553	return m_deltaAngularVelocity;
	554	}
	555
	556	const btVector3& internalGetAngularFactor() const
	557	{
	558	return m_angularFactor;
	559	}
	560
	561	const btVector3& internalGetInvMass() const
	562	{
	563	return m_invMass;
	564	}
	565
	566	btVector3& internalGetPushVelocity()
	567	{
	568	return m_pushVelocity;
	569	}
	570
	571	btVector3& internalGetTurnVelocity()
	572	{
	573	return m_turnVelocity;
	574	}
	575
	576	SIMD_FORCE_INLINE void internalGetVelocityInLocalPointObsolete(const btVector3& rel_pos, btVector3& velocity ) const
	577	{
	578	velocity = getLinearVelocity()+m_deltaLinearVelocity + (getAngularVelocity()+m_deltaAngularVelocity).cross(rel_pos);
	579	}
	580
	581	SIMD_FORCE_INLINE void internalGetAngularVelocity(btVector3& angVel) const
	582	{
	583	angVel = getAngularVelocity()+m_deltaAngularVelocity;
	584	}
	585
	586
	587	//Optimization for the iterative solver: avoid calculating constant terms involving inertia, normal, relative position
	588	SIMD_FORCE_INLINE void internalApplyImpulse(const btVector3& linearComponent, const btVector3& angularComponent,const btScalar impulseMagnitude)
	589	{
	590	if (m_inverseMass)
	591	{
	592	m_deltaLinearVelocity += linearComponent*impulseMagnitude;
	593	m_deltaAngularVelocity += angularComponent(impulseMagnitudem_angularFactor);
	594	}
	595	}
	596
	597	SIMD_FORCE_INLINE void internalApplyPushImpulse(const btVector3& linearComponent, const btVector3& angularComponent,btScalar impulseMagnitude)
	598	{
	599	if (m_inverseMass)
	600	{
	601	m_pushVelocity += linearComponent*impulseMagnitude;
	602	m_turnVelocity += angularComponent(impulseMagnitudem_angularFactor);
	603	}
	604	}
	605
	606	void internalWritebackVelocity()
	607	{
	608	if (m_inverseMass)
	609	{
	610	setLinearVelocity(getLinearVelocity()+ m_deltaLinearVelocity);
	611	setAngularVelocity(getAngularVelocity()+m_deltaAngularVelocity);
	612	//m_deltaLinearVelocity.setZero();
	613	//m_deltaAngularVelocity .setZero();
	614	//m_originalBody->setCompanionId(-1);
	615	}
	616	}
	617
	618
	619	void internalWritebackVelocity(btScalar timeStep);
[8393]	620
[8351]	621
	622
	623	///////////////////////////////////////////////
	624
	625	virtual int calculateSerializeBufferSize() const;
	626
	627	///fills the dataBuffer and returns the struct name (and 0 on failure)
	628	virtual const char* serialize(void* dataBuffer, class btSerializer* serializer) const;
	629
	630	virtual void serializeSingleObject(class btSerializer* serializer) const;
	631
[1963]	632	};
	633
[8351]	634	//@todo add m_optionalMotionState and m_constraintRefs to btRigidBodyData
	635	///do not change those serialization structures, it requires an updated sBulletDNAstr/sBulletDNAstr64
	636	struct btRigidBodyFloatData
	637	{
	638	btCollisionObjectFloatData m_collisionObjectData;
	639	btMatrix3x3FloatData m_invInertiaTensorWorld;
	640	btVector3FloatData m_linearVelocity;
	641	btVector3FloatData m_angularVelocity;
	642	btVector3FloatData m_angularFactor;
	643	btVector3FloatData m_linearFactor;
	644	btVector3FloatData m_gravity;
	645	btVector3FloatData m_gravity_acceleration;
	646	btVector3FloatData m_invInertiaLocal;
	647	btVector3FloatData m_totalForce;
	648	btVector3FloatData m_totalTorque;
	649	float m_inverseMass;
	650	float m_linearDamping;
	651	float m_angularDamping;
	652	float m_additionalDampingFactor;
	653	float m_additionalLinearDampingThresholdSqr;
	654	float m_additionalAngularDampingThresholdSqr;
	655	float m_additionalAngularDampingFactor;
	656	float m_linearSleepingThreshold;
	657	float m_angularSleepingThreshold;
	658	int m_additionalDamping;
	659	};
[1963]	660
[8351]	661	///do not change those serialization structures, it requires an updated sBulletDNAstr/sBulletDNAstr64
	662	struct btRigidBodyDoubleData
	663	{
	664	btCollisionObjectDoubleData m_collisionObjectData;
	665	btMatrix3x3DoubleData m_invInertiaTensorWorld;
	666	btVector3DoubleData m_linearVelocity;
	667	btVector3DoubleData m_angularVelocity;
	668	btVector3DoubleData m_angularFactor;
	669	btVector3DoubleData m_linearFactor;
	670	btVector3DoubleData m_gravity;
	671	btVector3DoubleData m_gravity_acceleration;
	672	btVector3DoubleData m_invInertiaLocal;
	673	btVector3DoubleData m_totalForce;
	674	btVector3DoubleData m_totalTorque;
	675	double m_inverseMass;
	676	double m_linearDamping;
	677	double m_angularDamping;
	678	double m_additionalDampingFactor;
	679	double m_additionalLinearDampingThresholdSqr;
	680	double m_additionalAngularDampingThresholdSqr;
	681	double m_additionalAngularDampingFactor;
	682	double m_linearSleepingThreshold;
	683	double m_angularSleepingThreshold;
	684	int m_additionalDamping;
	685	char m_padding[4];
	686	};
[1963]	687
[8351]	688
	689
[8393]	690	#endif //BT_RIGIDBODY_H
[1963]	691

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