*init

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+/*
+* Copyright (c) 2006-2011 Erin Catto http://www.box2d.org
+*
+* This software is provided 'as-is', without any express or implied
+* warranty.  In no event will the authors be held liable for any damages
+* arising from the use of this software.
+* Permission is granted to anyone to use this software for any purpose,
+* including commercial applications, and to alter it and redistribute it
+* freely, subject to the following restrictions:
+* 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.
+* 2. Altered source versions must be plainly marked as such, and must not be
+* misrepresented as being the original software.
+* 3. This notice may not be removed or altered from any source distribution.
+*/
+
+#ifndef B2_BODY_H
+#define B2_BODY_H
+
+#include "Box2D/Common/b2Math.h"
+#include "Box2D/Collision/Shapes/b2Shape.h"
+#include <memory>
+
+class b2Fixture;
+class b2Joint;
+class b2Contact;
+class b2Controller;
+class b2World;
+struct b2FixtureDef;
+struct b2JointEdge;
+struct b2ContactEdge;
+
+/// The body type.
+/// static: zero mass, zero velocity, may be manually moved
+/// kinematic: zero mass, non-zero velocity set by user, moved by solver
+/// dynamic: positive mass, non-zero velocity determined by forces, moved by solver
+enum b2BodyType
+{
+	b2_staticBody = 0,
+	b2_kinematicBody,
+	b2_dynamicBody
+
+	// TODO_ERIN
+	//b2_bulletBody,
+};
+
+/// A body definition holds all the data needed to construct a rigid body.
+/// You can safely re-use body definitions. Shapes are added to a body after construction.
+struct b2BodyDef
+{
+	/// This constructor sets the body definition default values.
+	b2BodyDef()
+	{
+		userData = nullptr;
+		position.Set(0.0f, 0.0f);
+		angle = 0.0f;
+		linearVelocity.Set(0.0f, 0.0f);
+		angularVelocity = 0.0f;
+		linearDamping = 0.0f;
+		angularDamping = 0.0f;
+		allowSleep = true;
+		awake = true;
+		fixedRotation = false;
+		bullet = false;
+		type = b2_staticBody;
+		active = true;
+		gravityScale = 1.0f;
+	}
+
+	/// The body type: static, kinematic, or dynamic.
+	/// Note: if a dynamic body would have zero mass, the mass is set to one.
+	b2BodyType type;
+
+	/// The world position of the body. Avoid creating bodies at the origin
+	/// since this can lead to many overlapping shapes.
+	b2Vec2 position;
+
+	/// The world angle of the body in radians.
+	float32 angle;
+
+	/// The linear velocity of the body's origin in world co-ordinates.
+	b2Vec2 linearVelocity;
+
+	/// The angular velocity of the body.
+	float32 angularVelocity;
+
+	/// Linear damping is use to reduce the linear velocity. The damping parameter
+	/// can be larger than 1.0f but the damping effect becomes sensitive to the
+	/// time step when the damping parameter is large.
+	/// Units are 1/time
+	float32 linearDamping;
+
+	/// Angular damping is use to reduce the angular velocity. The damping parameter
+	/// can be larger than 1.0f but the damping effect becomes sensitive to the
+	/// time step when the damping parameter is large.
+	/// Units are 1/time
+	float32 angularDamping;
+
+	/// Set this flag to false if this body should never fall asleep. Note that
+	/// this increases CPU usage.
+	bool allowSleep;
+
+	/// Is this body initially awake or sleeping?
+	bool awake;
+
+	/// Should this body be prevented from rotating? Useful for characters.
+	bool fixedRotation;
+
+	/// Is this a fast moving body that should be prevented from tunneling through
+	/// other moving bodies? Note that all bodies are prevented from tunneling through
+	/// kinematic and static bodies. This setting is only considered on dynamic bodies.
+	/// @warning You should use this flag sparingly since it increases processing time.
+	bool bullet;
+
+	/// Does this body start out active?
+	bool active;
+
+	/// Use this to store application specific body data.
+	void* userData;
+
+	/// Scale the gravity applied to this body.
+	float32 gravityScale;
+};
+
+/// A rigid body. These are created via b2World::CreateBody.
+class b2Body
+{
+public:
+	/// Creates a fixture and attach it to this body. Use this function if you need
+	/// to set some fixture parameters, like friction. Otherwise you can create the
+	/// fixture directly from a shape.
+	/// If the density is non-zero, this function automatically updates the mass of the body.
+	/// Contacts are not created until the next time step.
+	/// @param def the fixture definition.
+	/// @warning This function is locked during callbacks.
+	b2Fixture* CreateFixture(const b2FixtureDef* def);
+
+	/// Creates a fixture from a shape and attach it to this body.
+	/// This is a convenience function. Use b2FixtureDef if you need to set parameters
+	/// like friction, restitution, user data, or filtering.
+	/// If the density is non-zero, this function automatically updates the mass of the body.
+	/// @param shape the shape to be cloned.
+	/// @param density the shape density (set to zero for static bodies).
+	/// @warning This function is locked during callbacks.
+	b2Fixture* CreateFixture(const b2Shape* shape, float32 density);
+
+	/// Destroy a fixture. This removes the fixture from the broad-phase and
+	/// destroys all contacts associated with this fixture. This will
+	/// automatically adjust the mass of the body if the body is dynamic and the
+	/// fixture has positive density.
+	/// All fixtures attached to a body are implicitly destroyed when the body is destroyed.
+	/// @param fixture the fixture to be removed.
+	/// @warning This function is locked during callbacks.
+	void DestroyFixture(b2Fixture* fixture);
+
+	/// Set the position of the body's origin and rotation.
+	/// Manipulating a body's transform may cause non-physical behavior.
+	/// Note: contacts are updated on the next call to b2World::Step.
+	/// @param position the world position of the body's local origin.
+	/// @param angle the world rotation in radians.
+	void SetTransform(const b2Vec2& position, float32 angle);
+
+	/// Get the body transform for the body's origin.
+	/// @return the world transform of the body's origin.
+	const b2Transform& GetTransform() const;
+
+	/// Get the world body origin position.
+	/// @return the world position of the body's origin.
+	const b2Vec2& GetPosition() const;
+
+	/// Get the angle in radians.
+	/// @return the current world rotation angle in radians.
+	float32 GetAngle() const;
+
+	/// Get the world position of the center of mass.
+	const b2Vec2& GetWorldCenter() const;
+
+	/// Get the local position of the center of mass.
+	const b2Vec2& GetLocalCenter() const;
+
+	/// Set the linear velocity of the center of mass.
+	/// @param v the new linear velocity of the center of mass.
+	void SetLinearVelocity(const b2Vec2& v);
+
+	/// Get the linear velocity of the center of mass.
+	/// @return the linear velocity of the center of mass.
+	const b2Vec2& GetLinearVelocity() const;
+
+	/// Set the angular velocity.
+	/// @param omega the new angular velocity in radians/second.
+	void SetAngularVelocity(float32 omega);
+
+	/// Get the angular velocity.
+	/// @return the angular velocity in radians/second.
+	float32 GetAngularVelocity() const;
+
+	/// Apply a force at a world point. If the force is not
+	/// applied at the center of mass, it will generate a torque and
+	/// affect the angular velocity. This wakes up the body.
+	/// @param force the world force vector, usually in Newtons (N).
+	/// @param point the world position of the point of application.
+	/// @param wake also wake up the body
+	void ApplyForce(const b2Vec2& force, const b2Vec2& point, bool wake);
+
+	/// Apply a force to the center of mass. This wakes up the body.
+	/// @param force the world force vector, usually in Newtons (N).
+	/// @param wake also wake up the body
+	void ApplyForceToCenter(const b2Vec2& force, bool wake);
+
+	/// Apply a torque. This affects the angular velocity
+	/// without affecting the linear velocity of the center of mass.
+	/// @param torque about the z-axis (out of the screen), usually in N-m.
+	/// @param wake also wake up the body
+	void ApplyTorque(float32 torque, bool wake);
+
+	/// Apply an impulse at a point. This immediately modifies the velocity.
+	/// It also modifies the angular velocity if the point of application
+	/// is not at the center of mass. This wakes up the body.
+	/// @param impulse the world impulse vector, usually in N-seconds or kg-m/s.
+	/// @param point the world position of the point of application.
+	/// @param wake also wake up the body
+	void ApplyLinearImpulse(const b2Vec2& impulse, const b2Vec2& point, bool wake);
+
+	/// Apply an impulse to the center of mass. This immediately modifies the velocity.
+	/// @param impulse the world impulse vector, usually in N-seconds or kg-m/s.
+	/// @param wake also wake up the body
+	void ApplyLinearImpulseToCenter(const b2Vec2& impulse, bool wake);
+
+	/// Apply an angular impulse.
+	/// @param impulse the angular impulse in units of kg*m*m/s
+	/// @param wake also wake up the body
+	void ApplyAngularImpulse(float32 impulse, bool wake);
+
+	/// Get the total mass of the body.
+	/// @return the mass, usually in kilograms (kg).
+	float32 GetMass() const;
+
+	/// Get the rotational inertia of the body about the local origin.
+	/// @return the rotational inertia, usually in kg-m^2.
+	float32 GetInertia() const;
+
+	/// Get the mass data of the body.
+	/// @return a struct containing the mass, inertia and center of the body.
+	void GetMassData(b2MassData* data) const;
+
+	/// Set the mass properties to override the mass properties of the fixtures.
+	/// Note that this changes the center of mass position.
+	/// Note that creating or destroying fixtures can also alter the mass.
+	/// This function has no effect if the body isn't dynamic.
+	/// @param massData the mass properties.
+	void SetMassData(const b2MassData* data);
+
+	/// This resets the mass properties to the sum of the mass properties of the fixtures.
+	/// This normally does not need to be called unless you called SetMassData to override
+	/// the mass and you later want to reset the mass.
+	void ResetMassData();
+
+	/// Get the world coordinates of a point given the local coordinates.
+	/// @param localPoint a point on the body measured relative the the body's origin.
+	/// @return the same point expressed in world coordinates.
+	b2Vec2 GetWorldPoint(const b2Vec2& localPoint) const;
+
+	/// Get the world coordinates of a vector given the local coordinates.
+	/// @param localVector a vector fixed in the body.
+	/// @return the same vector expressed in world coordinates.
+	b2Vec2 GetWorldVector(const b2Vec2& localVector) const;
+
+	/// Gets a local point relative to the body's origin given a world point.
+	/// @param a point in world coordinates.
+	/// @return the corresponding local point relative to the body's origin.
+	b2Vec2 GetLocalPoint(const b2Vec2& worldPoint) const;
+
+	/// Gets a local vector given a world vector.
+	/// @param a vector in world coordinates.
+	/// @return the corresponding local vector.
+	b2Vec2 GetLocalVector(const b2Vec2& worldVector) const;
+
+	/// Get the world linear velocity of a world point attached to this body.
+	/// @param a point in world coordinates.
+	/// @return the world velocity of a point.
+	b2Vec2 GetLinearVelocityFromWorldPoint(const b2Vec2& worldPoint) const;
+
+	/// Get the world velocity of a local point.
+	/// @param a point in local coordinates.
+	/// @return the world velocity of a point.
+	b2Vec2 GetLinearVelocityFromLocalPoint(const b2Vec2& localPoint) const;
+
+	/// Get the linear damping of the body.
+	float32 GetLinearDamping() const;
+
+	/// Set the linear damping of the body.
+	void SetLinearDamping(float32 linearDamping);
+
+	/// Get the angular damping of the body.
+	float32 GetAngularDamping() const;
+
+	/// Set the angular damping of the body.
+	void SetAngularDamping(float32 angularDamping);
+
+	/// Get the gravity scale of the body.
+	float32 GetGravityScale() const;
+
+	/// Set the gravity scale of the body.
+	void SetGravityScale(float32 scale);
+
+	/// Set the type of this body. This may alter the mass and velocity.
+	void SetType(b2BodyType type);
+
+	/// Get the type of this body.
+	b2BodyType GetType() const;
+
+	/// Should this body be treated like a bullet for continuous collision detection?
+	void SetBullet(bool flag);
+
+	/// Is this body treated like a bullet for continuous collision detection?
+	bool IsBullet() const;
+
+	/// You can disable sleeping on this body. If you disable sleeping, the
+	/// body will be woken.
+	void SetSleepingAllowed(bool flag);
+
+	/// Is this body allowed to sleep
+	bool IsSleepingAllowed() const;
+
+	/// Set the sleep state of the body. A sleeping body has very
+	/// low CPU cost.
+	/// @param flag set to true to wake the body, false to put it to sleep.
+	void SetAwake(bool flag);
+
+	/// Get the sleeping state of this body.
+	/// @return true if the body is awake.
+	bool IsAwake() const;
+
+	/// Set the active state of the body. An inactive body is not
+	/// simulated and cannot be collided with or woken up.
+	/// If you pass a flag of true, all fixtures will be added to the
+	/// broad-phase.
+	/// If you pass a flag of false, all fixtures will be removed from
+	/// the broad-phase and all contacts will be destroyed.
+	/// Fixtures and joints are otherwise unaffected. You may continue
+	/// to create/destroy fixtures and joints on inactive bodies.
+	/// Fixtures on an inactive body are implicitly inactive and will
+	/// not participate in collisions, ray-casts, or queries.
+	/// Joints connected to an inactive body are implicitly inactive.
+	/// An inactive body is still owned by a b2World object and remains
+	/// in the body list.
+	void SetActive(bool flag);
+
+	/// Get the active state of the body.
+	bool IsActive() const;
+
+	/// Set this body to have fixed rotation. This causes the mass
+	/// to be reset.
+	void SetFixedRotation(bool flag);
+
+	/// Does this body have fixed rotation?
+	bool IsFixedRotation() const;
+
+	/// Get the list of all fixtures attached to this body.
+	b2Fixture* GetFixtureList();
+	const b2Fixture* GetFixtureList() const;
+
+	/// Get the list of all joints attached to this body.
+	b2JointEdge* GetJointList();
+	const b2JointEdge* GetJointList() const;
+
+	/// Get the list of all contacts attached to this body.
+	/// @warning this list changes during the time step and you may
+	/// miss some collisions if you don't use b2ContactListener.
+	b2ContactEdge* GetContactList();
+	const b2ContactEdge* GetContactList() const;
+
+	/// Get the next body in the world's body list.
+	b2Body* GetNext();
+	const b2Body* GetNext() const;
+
+	/// Get the user data pointer that was provided in the body definition.
+	void* GetUserData() const;
+
+	/// Set the user data. Use this to store your application specific data.
+	void SetUserData(void* data);
+
+	/// Get the parent world of this body.
+	b2World* GetWorld();
+	const b2World* GetWorld() const;
+
+	/// Dump this body to a log file
+	void Dump();
+
+private:
+
+	friend class b2World;
+	friend class b2Island;
+	friend class b2ContactManager;
+	friend class b2ContactSolver;
+	friend class b2Contact;
+	
+	friend class b2DistanceJoint;
+	friend class b2FrictionJoint;
+	friend class b2GearJoint;
+	friend class b2MotorJoint;
+	friend class b2MouseJoint;
+	friend class b2PrismaticJoint;
+	friend class b2PulleyJoint;
+	friend class b2RevoluteJoint;
+	friend class b2RopeJoint;
+	friend class b2WeldJoint;
+	friend class b2WheelJoint;
+
+	// m_flags
+	enum
+	{
+		e_islandFlag		= 0x0001,
+		e_awakeFlag			= 0x0002,
+		e_autoSleepFlag		= 0x0004,
+		e_bulletFlag		= 0x0008,
+		e_fixedRotationFlag	= 0x0010,
+		e_activeFlag		= 0x0020,
+		e_toiFlag			= 0x0040
+	};
+
+	b2Body(const b2BodyDef* bd, b2World* world);
+	~b2Body();
+
+	void SynchronizeFixtures();
+	void SynchronizeTransform();
+
+	// This is used to prevent connected bodies from colliding.
+	// It may lie, depending on the collideConnected flag.
+	bool ShouldCollide(const b2Body* other) const;
+
+	void Advance(float32 t);
+
+	b2BodyType m_type;
+
+	uint16 m_flags;
+
+	int32 m_islandIndex;
+
+	b2Transform m_xf;		// the body origin transform
+	b2Sweep m_sweep;		// the swept motion for CCD
+
+	b2Vec2 m_linearVelocity;
+	float32 m_angularVelocity;
+
+	b2Vec2 m_force;
+	float32 m_torque;
+
+	b2World* m_world;
+	b2Body* m_prev;
+	b2Body* m_next;
+
+	b2Fixture* m_fixtureList;
+	int32 m_fixtureCount;
+
+	b2JointEdge* m_jointList;
+	b2ContactEdge* m_contactList;
+
+	float32 m_mass, m_invMass;
+
+	// Rotational inertia about the center of mass.
+	float32 m_I, m_invI;
+
+	float32 m_linearDamping;
+	float32 m_angularDamping;
+	float32 m_gravityScale;
+
+	float32 m_sleepTime;
+
+	void* m_userData;
+};
+
+inline b2BodyType b2Body::GetType() const
+{
+	return m_type;
+}
+
+inline const b2Transform& b2Body::GetTransform() const
+{
+	return m_xf;
+}
+
+inline const b2Vec2& b2Body::GetPosition() const
+{
+	return m_xf.p;
+}
+
+inline float32 b2Body::GetAngle() const
+{
+	return m_sweep.a;
+}
+
+inline const b2Vec2& b2Body::GetWorldCenter() const
+{
+	return m_sweep.c;
+}
+
+inline const b2Vec2& b2Body::GetLocalCenter() const
+{
+	return m_sweep.localCenter;
+}
+
+inline void b2Body::SetLinearVelocity(const b2Vec2& v)
+{
+	if (m_type == b2_staticBody)
+	{
+		return;
+	}
+
+	if (b2Dot(v,v) > 0.0f)
+	{
+		SetAwake(true);
+	}
+
+	m_linearVelocity = v;
+}
+
+inline const b2Vec2& b2Body::GetLinearVelocity() const
+{
+	return m_linearVelocity;
+}
+
+inline void b2Body::SetAngularVelocity(float32 w)
+{
+	if (m_type == b2_staticBody)
+	{
+		return;
+	}
+
+	if (w * w > 0.0f)
+	{
+		SetAwake(true);
+	}
+
+	m_angularVelocity = w;
+}
+
+inline float32 b2Body::GetAngularVelocity() const
+{
+	return m_angularVelocity;
+}
+
+inline float32 b2Body::GetMass() const
+{
+	return m_mass;
+}
+
+inline float32 b2Body::GetInertia() const
+{
+	return m_I + m_mass * b2Dot(m_sweep.localCenter, m_sweep.localCenter);
+}
+
+inline void b2Body::GetMassData(b2MassData* data) const
+{
+	data->mass = m_mass;
+	data->I = m_I + m_mass * b2Dot(m_sweep.localCenter, m_sweep.localCenter);
+	data->center = m_sweep.localCenter;
+}
+
+inline b2Vec2 b2Body::GetWorldPoint(const b2Vec2& localPoint) const
+{
+	return b2Mul(m_xf, localPoint);
+}
+
+inline b2Vec2 b2Body::GetWorldVector(const b2Vec2& localVector) const
+{
+	return b2Mul(m_xf.q, localVector);
+}
+
+inline b2Vec2 b2Body::GetLocalPoint(const b2Vec2& worldPoint) const
+{
+	return b2MulT(m_xf, worldPoint);
+}
+
+inline b2Vec2 b2Body::GetLocalVector(const b2Vec2& worldVector) const
+{
+	return b2MulT(m_xf.q, worldVector);
+}
+
+inline b2Vec2 b2Body::GetLinearVelocityFromWorldPoint(const b2Vec2& worldPoint) const
+{
+	return m_linearVelocity + b2Cross(m_angularVelocity, worldPoint - m_sweep.c);
+}
+
+inline b2Vec2 b2Body::GetLinearVelocityFromLocalPoint(const b2Vec2& localPoint) const
+{
+	return GetLinearVelocityFromWorldPoint(GetWorldPoint(localPoint));
+}
+
+inline float32 b2Body::GetLinearDamping() const
+{
+	return m_linearDamping;
+}
+
+inline void b2Body::SetLinearDamping(float32 linearDamping)
+{
+	m_linearDamping = linearDamping;
+}
+
+inline float32 b2Body::GetAngularDamping() const
+{
+	return m_angularDamping;
+}
+
+inline void b2Body::SetAngularDamping(float32 angularDamping)
+{
+	m_angularDamping = angularDamping;
+}
+
+inline float32 b2Body::GetGravityScale() const
+{
+	return m_gravityScale;
+}
+
+inline void b2Body::SetGravityScale(float32 scale)
+{
+	m_gravityScale = scale;
+}
+
+inline void b2Body::SetBullet(bool flag)
+{
+	if (flag)
+	{
+		m_flags |= e_bulletFlag;
+	}
+	else
+	{
+		m_flags &= ~e_bulletFlag;
+	}
+}
+
+inline bool b2Body::IsBullet() const
+{
+	return (m_flags & e_bulletFlag) == e_bulletFlag;
+}
+
+inline void b2Body::SetAwake(bool flag)
+{
+	if (flag)
+	{
+		m_flags |= e_awakeFlag;
+		m_sleepTime = 0.0f;
+	}
+	else
+	{
+		m_flags &= ~e_awakeFlag;
+		m_sleepTime = 0.0f;
+		m_linearVelocity.SetZero();
+		m_angularVelocity = 0.0f;
+		m_force.SetZero();
+		m_torque = 0.0f;
+	}
+}
+
+inline bool b2Body::IsAwake() const
+{
+	return (m_flags & e_awakeFlag) == e_awakeFlag;
+}
+
+inline bool b2Body::IsActive() const
+{
+	return (m_flags & e_activeFlag) == e_activeFlag;
+}
+
+inline bool b2Body::IsFixedRotation() const
+{
+	return (m_flags & e_fixedRotationFlag) == e_fixedRotationFlag;
+}
+
+inline void b2Body::SetSleepingAllowed(bool flag)
+{
+	if (flag)
+	{
+		m_flags |= e_autoSleepFlag;
+	}
+	else
+	{
+		m_flags &= ~e_autoSleepFlag;
+		SetAwake(true);
+	}
+}
+
+inline bool b2Body::IsSleepingAllowed() const
+{
+	return (m_flags & e_autoSleepFlag) == e_autoSleepFlag;
+}
+
+inline b2Fixture* b2Body::GetFixtureList()
+{
+	return m_fixtureList;
+}
+
+inline const b2Fixture* b2Body::GetFixtureList() const
+{
+	return m_fixtureList;
+}
+
+inline b2JointEdge* b2Body::GetJointList()
+{
+	return m_jointList;
+}
+
+inline const b2JointEdge* b2Body::GetJointList() const
+{
+	return m_jointList;
+}
+
+inline b2ContactEdge* b2Body::GetContactList()
+{
+	return m_contactList;
+}
+
+inline const b2ContactEdge* b2Body::GetContactList() const
+{
+	return m_contactList;
+}
+
+inline b2Body* b2Body::GetNext()
+{
+	return m_next;
+}
+
+inline const b2Body* b2Body::GetNext() const
+{
+	return m_next;
+}
+
+inline void b2Body::SetUserData(void* data)
+{
+	m_userData = data;
+}
+
+inline void* b2Body::GetUserData() const
+{
+	return m_userData;
+}
+
+inline void b2Body::ApplyForce(const b2Vec2& force, const b2Vec2& point, bool wake)
+{
+	if (m_type != b2_dynamicBody)
+	{
+		return;
+	}
+
+	if (wake && (m_flags & e_awakeFlag) == 0)
+	{
+		SetAwake(true);
+	}
+
+	// Don't accumulate a force if the body is sleeping.
+	if (m_flags & e_awakeFlag)
+	{
+		m_force += force;
+		m_torque += b2Cross(point - m_sweep.c, force);
+	}
+}
+
+inline void b2Body::ApplyForceToCenter(const b2Vec2& force, bool wake)
+{
+	if (m_type != b2_dynamicBody)
+	{
+		return;
+	}
+
+	if (wake && (m_flags & e_awakeFlag) == 0)
+	{
+		SetAwake(true);
+	}
+
+	// Don't accumulate a force if the body is sleeping
+	if (m_flags & e_awakeFlag)
+	{
+		m_force += force;
+	}
+}
+
+inline void b2Body::ApplyTorque(float32 torque, bool wake)
+{
+	if (m_type != b2_dynamicBody)
+	{
+		return;
+	}
+
+	if (wake && (m_flags & e_awakeFlag) == 0)
+	{
+		SetAwake(true);
+	}
+
+	// Don't accumulate a force if the body is sleeping
+	if (m_flags & e_awakeFlag)
+	{
+		m_torque += torque;
+	}
+}
+
+inline void b2Body::ApplyLinearImpulse(const b2Vec2& impulse, const b2Vec2& point, bool wake)
+{
+	if (m_type != b2_dynamicBody)
+	{
+		return;
+	}
+
+	if (wake && (m_flags & e_awakeFlag) == 0)
+	{
+		SetAwake(true);
+	}
+
+	// Don't accumulate velocity if the body is sleeping
+	if (m_flags & e_awakeFlag)
+	{
+		m_linearVelocity += m_invMass * impulse;
+		m_angularVelocity += m_invI * b2Cross(point - m_sweep.c, impulse);
+	}
+}
+
+inline void b2Body::ApplyLinearImpulseToCenter(const b2Vec2& impulse, bool wake)
+{
+	if (m_type != b2_dynamicBody)
+	{
+		return;
+	}
+
+	if (wake && (m_flags & e_awakeFlag) == 0)
+	{
+		SetAwake(true);
+	}
+
+	// Don't accumulate velocity if the body is sleeping
+	if (m_flags & e_awakeFlag)
+	{
+		m_linearVelocity += m_invMass * impulse;
+	}
+}
+
+inline void b2Body::ApplyAngularImpulse(float32 impulse, bool wake)
+{
+	if (m_type != b2_dynamicBody)
+	{
+		return;
+	}
+
+	if (wake && (m_flags & e_awakeFlag) == 0)
+	{
+		SetAwake(true);
+	}
+
+	// Don't accumulate velocity if the body is sleeping
+	if (m_flags & e_awakeFlag)
+	{
+		m_angularVelocity += m_invI * impulse;
+	}
+}
+
+inline void b2Body::SynchronizeTransform()
+{
+	m_xf.q.Set(m_sweep.a);
+	m_xf.p = m_sweep.c - b2Mul(m_xf.q, m_sweep.localCenter);
+}
+
+inline void b2Body::Advance(float32 alpha)
+{
+	// Advance to the new safe time. This doesn't sync the broad-phase.
+	m_sweep.Advance(alpha);
+	m_sweep.c = m_sweep.c0;
+	m_sweep.a = m_sweep.a0;
+	m_xf.q.Set(m_sweep.a);
+	m_xf.p = m_sweep.c - b2Mul(m_xf.q, m_sweep.localCenter);
+}
+
+inline b2World* b2Body::GetWorld()
+{
+	return m_world;
+}
+
+inline const b2World* b2Body::GetWorld() const
+{
+	return m_world;
+}
+
+#endif