/* * 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_REVOLUTE_JOINT_H #define B2_REVOLUTE_JOINT_H #include /// Revolute joint definition. This requires defining an /// anchor point where the bodies are joined. The definition /// uses local anchor points so that the initial configuration /// can violate the constraint slightly. You also need to /// specify the initial relative angle for joint limits. This /// helps when saving and loading a game. /// The local anchor points are measured from the body's origin /// rather than the center of mass because: /// 1. you might not know where the center of mass will be. /// 2. if you add/remove shapes from a body and recompute the mass, /// the joints will be broken. struct b2RevoluteJointDef : public b2JointDef { b2RevoluteJointDef() { type = e_revoluteJoint; localAnchorA.Set(0.0f, 0.0f); localAnchorB.Set(0.0f, 0.0f); referenceAngle = 0.0f; lowerAngle = 0.0f; upperAngle = 0.0f; maxMotorTorque = 0.0f; motorSpeed = 0.0f; enableLimit = false; enableMotor = false; } /// Initialize the bodies, anchors, and reference angle using a world /// anchor point. void Initialize(b2Body* bodyA, b2Body* bodyB, const b2Vec2& anchor); /// The local anchor point relative to bodyA's origin. b2Vec2 localAnchorA; /// The local anchor point relative to bodyB's origin. b2Vec2 localAnchorB; /// The bodyB angle minus bodyA angle in the reference state (radians). float32 referenceAngle; /// A flag to enable joint limits. bool enableLimit; /// The lower angle for the joint limit (radians). float32 lowerAngle; /// The upper angle for the joint limit (radians). float32 upperAngle; /// A flag to enable the joint motor. bool enableMotor; /// The desired motor speed. Usually in radians per second. float32 motorSpeed; /// The maximum motor torque used to achieve the desired motor speed. /// Usually in N-m. float32 maxMotorTorque; }; /// A revolute joint constrains two bodies to share a common point while they /// are free to rotate about the point. The relative rotation about the shared /// point is the joint angle. You can limit the relative rotation with /// a joint limit that specifies a lower and upper angle. You can use a motor /// to drive the relative rotation about the shared point. A maximum motor torque /// is provided so that infinite forces are not generated. class b2RevoluteJoint : public b2Joint { public: b2Vec2 GetAnchorA() const; b2Vec2 GetAnchorB() const; /// The local anchor point relative to bodyA's origin. const b2Vec2& GetLocalAnchorA() const { return m_localAnchorA; } /// The local anchor point relative to bodyB's origin. const b2Vec2& GetLocalAnchorB() const { return m_localAnchorB; } /// Get the reference angle. float32 GetReferenceAngle() const { return m_referenceAngle; } /// Get the current joint angle in radians. float32 GetJointAngle() const; /// Get the current joint angle speed in radians per second. float32 GetJointSpeed() const; /// Is the joint limit enabled? bool IsLimitEnabled() const; /// Enable/disable the joint limit. void EnableLimit(bool flag); /// Get the lower joint limit in radians. float32 GetLowerLimit() const; /// Get the upper joint limit in radians. float32 GetUpperLimit() const; /// Set the joint limits in radians. void SetLimits(float32 lower, float32 upper); /// Is the joint motor enabled? bool IsMotorEnabled() const; /// Enable/disable the joint motor. void EnableMotor(bool flag); /// Set the motor speed in radians per second. void SetMotorSpeed(float32 speed); /// Get the motor speed in radians per second. float32 GetMotorSpeed() const; /// Set the maximum motor torque, usually in N-m. void SetMaxMotorTorque(float32 torque); float32 GetMaxMotorTorque() const { return m_maxMotorTorque; } /// Get the reaction force given the inverse time step. /// Unit is N. b2Vec2 GetReactionForce(float32 inv_dt) const; /// Get the reaction torque due to the joint limit given the inverse time step. /// Unit is N*m. float32 GetReactionTorque(float32 inv_dt) const; /// Get the current motor torque given the inverse time step. /// Unit is N*m. float32 GetMotorTorque(float32 inv_dt) const; /// Dump to b2Log. void Dump(); protected: friend class b2Joint; friend class b2GearJoint; b2RevoluteJoint(const b2RevoluteJointDef* def); void InitVelocityConstraints(const b2SolverData& data); void SolveVelocityConstraints(const b2SolverData& data); bool SolvePositionConstraints(const b2SolverData& data); // Solver shared b2Vec2 m_localAnchorA; b2Vec2 m_localAnchorB; b2Vec3 m_impulse; float32 m_motorImpulse; bool m_enableMotor; float32 m_maxMotorTorque; float32 m_motorSpeed; bool m_enableLimit; float32 m_referenceAngle; float32 m_lowerAngle; float32 m_upperAngle; // Solver temp int32 m_indexA; int32 m_indexB; b2Vec2 m_rA; b2Vec2 m_rB; b2Vec2 m_localCenterA; b2Vec2 m_localCenterB; float32 m_invMassA; float32 m_invMassB; float32 m_invIA; float32 m_invIB; b2Mat33 m_mass; // effective mass for point-to-point constraint. float32 m_motorMass; // effective mass for motor/limit angular constraint. b2LimitState m_limitState; }; inline float32 b2RevoluteJoint::GetMotorSpeed() const { return m_motorSpeed; } #endif