axmol/Box2D/Dynamics/Joints/b2Joint.h

227 lines
5.6 KiB
C++

/*
* Copyright (c) 2006-2007 Erin Catto http://www.gphysics.com
*
* 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_JOINT_H
#define B2_JOINT_H
#include <Box2D/Common/b2Math.h>
class b2Body;
class b2Joint;
struct b2TimeStep;
class b2BlockAllocator;
enum b2JointType
{
e_unknownJoint,
e_revoluteJoint,
e_prismaticJoint,
e_distanceJoint,
e_pulleyJoint,
e_mouseJoint,
e_gearJoint,
e_lineJoint,
e_weldJoint,
e_frictionJoint,
};
enum b2LimitState
{
e_inactiveLimit,
e_atLowerLimit,
e_atUpperLimit,
e_equalLimits
};
struct b2Jacobian
{
b2Vec2 linearA;
float32 angularA;
b2Vec2 linearB;
float32 angularB;
void SetZero();
void Set(const b2Vec2& x1, float32 a1, const b2Vec2& x2, float32 a2);
float32 Compute(const b2Vec2& x1, float32 a1, const b2Vec2& x2, float32 a2);
};
/// A joint edge is used to connect bodies and joints together
/// in a joint graph where each body is a node and each joint
/// is an edge. A joint edge belongs to a doubly linked list
/// maintained in each attached body. Each joint has two joint
/// nodes, one for each attached body.
struct b2JointEdge
{
b2Body* other; ///< provides quick access to the other body attached.
b2Joint* joint; ///< the joint
b2JointEdge* prev; ///< the previous joint edge in the body's joint list
b2JointEdge* next; ///< the next joint edge in the body's joint list
};
/// Joint definitions are used to construct joints.
struct b2JointDef
{
b2JointDef()
{
type = e_unknownJoint;
userData = NULL;
bodyA = NULL;
bodyB = NULL;
collideConnected = false;
}
/// The joint type is set automatically for concrete joint types.
b2JointType type;
/// Use this to attach application specific data to your joints.
void* userData;
/// The first attached body.
b2Body* bodyA;
/// The second attached body.
b2Body* bodyB;
/// Set this flag to true if the attached bodies should collide.
bool collideConnected;
};
/// The base joint class. Joints are used to constraint two bodies together in
/// various fashions. Some joints also feature limits and motors.
class b2Joint
{
public:
/// Get the type of the concrete joint.
b2JointType GetType() const;
/// Get the first body attached to this joint.
b2Body* GetBodyA();
/// Get the second body attached to this joint.
b2Body* GetBodyB();
/// Get the anchor point on bodyA in world coordinates.
virtual b2Vec2 GetAnchorA() const = 0;
/// Get the anchor point on bodyB in world coordinates.
virtual b2Vec2 GetAnchorB() const = 0;
/// Get the reaction force on body2 at the joint anchor in Newtons.
virtual b2Vec2 GetReactionForce(float32 inv_dt) const = 0;
/// Get the reaction torque on body2 in N*m.
virtual float32 GetReactionTorque(float32 inv_dt) const = 0;
/// Get the next joint the world joint list.
b2Joint* GetNext();
/// Get the user data pointer.
void* GetUserData() const;
/// Set the user data pointer.
void SetUserData(void* data);
/// Short-cut function to determine if either body is inactive.
bool IsActive() const;
protected:
friend class b2World;
friend class b2Body;
friend class b2Island;
static b2Joint* Create(const b2JointDef* def, b2BlockAllocator* allocator);
static void Destroy(b2Joint* joint, b2BlockAllocator* allocator);
b2Joint(const b2JointDef* def);
virtual ~b2Joint() {}
virtual void InitVelocityConstraints(const b2TimeStep& step) = 0;
virtual void SolveVelocityConstraints(const b2TimeStep& step) = 0;
// This returns true if the position errors are within tolerance.
virtual bool SolvePositionConstraints(float32 baumgarte) = 0;
b2JointType m_type;
b2Joint* m_prev;
b2Joint* m_next;
b2JointEdge m_edgeA;
b2JointEdge m_edgeB;
b2Body* m_bodyA;
b2Body* m_bodyB;
bool m_islandFlag;
bool m_collideConnected;
void* m_userData;
// Cache here per time step to reduce cache misses.
b2Vec2 m_localCenterA, m_localCenterB;
float32 m_invMassA, m_invIA;
float32 m_invMassB, m_invIB;
};
inline void b2Jacobian::SetZero()
{
linearA.SetZero(); angularA = 0.0f;
linearB.SetZero(); angularB = 0.0f;
}
inline void b2Jacobian::Set(const b2Vec2& x1, float32 a1, const b2Vec2& x2, float32 a2)
{
linearA = x1; angularA = a1;
linearB = x2; angularB = a2;
}
inline float32 b2Jacobian::Compute(const b2Vec2& x1, float32 a1, const b2Vec2& x2, float32 a2)
{
return b2Dot(linearA, x1) + angularA * a1 + b2Dot(linearB, x2) + angularB * a2;
}
inline b2JointType b2Joint::GetType() const
{
return m_type;
}
inline b2Body* b2Joint::GetBodyA()
{
return m_bodyA;
}
inline b2Body* b2Joint::GetBodyB()
{
return m_bodyB;
}
inline b2Joint* b2Joint::GetNext()
{
return m_next;
}
inline void* b2Joint::GetUserData() const
{
return m_userData;
}
inline void b2Joint::SetUserData(void* data)
{
m_userData = data;
}
#endif