307 lines
7.6 KiB
C++
307 lines
7.6 KiB
C++
/*
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Bullet Continuous Collision Detection and Physics Library
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Copyright (c) 2003-2006 Erwin Coumans http://continuousphysics.com/Bullet/
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This software is provided 'as-is', without any express or implied warranty.
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In no event will the authors be held liable for any damages arising from the use of this software.
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Permission is granted to anyone to use this software for any purpose,
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including commercial applications, and to alter it and redistribute it freely,
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subject to the following restrictions:
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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.
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2. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software.
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3. This notice may not be removed or altered from any source distribution.
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*/
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#ifndef BT_SOLVER_BODY_H
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#define BT_SOLVER_BODY_H
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class btRigidBody;
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#include "LinearMath/btVector3.h"
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#include "LinearMath/btMatrix3x3.h"
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#include "LinearMath/btAlignedAllocator.h"
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#include "LinearMath/btTransformUtil.h"
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///Until we get other contributions, only use SIMD on Windows, when using Visual Studio 2008 or later, and not double precision
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#ifdef BT_USE_SSE
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#define USE_SIMD 1
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#endif //
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#ifdef USE_SIMD
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struct btSimdScalar
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{
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SIMD_FORCE_INLINE btSimdScalar()
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{
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}
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SIMD_FORCE_INLINE btSimdScalar(float fl)
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:m_vec128 (_mm_set1_ps(fl))
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{
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}
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SIMD_FORCE_INLINE btSimdScalar(__m128 v128)
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:m_vec128(v128)
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{
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}
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union
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{
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__m128 m_vec128;
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float m_floats[4];
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int m_ints[4];
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btScalar m_unusedPadding;
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};
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SIMD_FORCE_INLINE __m128 get128()
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{
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return m_vec128;
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}
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SIMD_FORCE_INLINE const __m128 get128() const
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{
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return m_vec128;
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}
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SIMD_FORCE_INLINE void set128(__m128 v128)
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{
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m_vec128 = v128;
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}
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SIMD_FORCE_INLINE operator __m128()
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{
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return m_vec128;
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}
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SIMD_FORCE_INLINE operator const __m128() const
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{
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return m_vec128;
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}
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SIMD_FORCE_INLINE operator float() const
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{
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return m_floats[0];
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}
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};
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///@brief Return the elementwise product of two btSimdScalar
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SIMD_FORCE_INLINE btSimdScalar
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operator*(const btSimdScalar& v1, const btSimdScalar& v2)
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{
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return btSimdScalar(_mm_mul_ps(v1.get128(),v2.get128()));
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}
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///@brief Return the elementwise product of two btSimdScalar
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SIMD_FORCE_INLINE btSimdScalar
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operator+(const btSimdScalar& v1, const btSimdScalar& v2)
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{
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return btSimdScalar(_mm_add_ps(v1.get128(),v2.get128()));
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}
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#else
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#define btSimdScalar btScalar
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#endif
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///The btSolverBody is an internal datastructure for the constraint solver. Only necessary data is packed to increase cache coherence/performance.
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ATTRIBUTE_ALIGNED16 (struct) btSolverBody
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{
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BT_DECLARE_ALIGNED_ALLOCATOR();
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btTransform m_worldTransform;
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btVector3 m_deltaLinearVelocity;
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btVector3 m_deltaAngularVelocity;
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btVector3 m_angularFactor;
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btVector3 m_linearFactor;
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btVector3 m_invMass;
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btVector3 m_pushVelocity;
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btVector3 m_turnVelocity;
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btVector3 m_linearVelocity;
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btVector3 m_angularVelocity;
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btVector3 m_externalForceImpulse;
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btVector3 m_externalTorqueImpulse;
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btRigidBody* m_originalBody;
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void setWorldTransform(const btTransform& worldTransform)
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{
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m_worldTransform = worldTransform;
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}
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const btTransform& getWorldTransform() const
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{
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return m_worldTransform;
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}
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SIMD_FORCE_INLINE void getVelocityInLocalPointNoDelta(const btVector3& rel_pos, btVector3& velocity ) const
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{
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if (m_originalBody)
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velocity = m_linearVelocity + m_externalForceImpulse + (m_angularVelocity+m_externalTorqueImpulse).cross(rel_pos);
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else
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velocity.setValue(0,0,0);
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}
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SIMD_FORCE_INLINE void getVelocityInLocalPointObsolete(const btVector3& rel_pos, btVector3& velocity ) const
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{
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if (m_originalBody)
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velocity = m_linearVelocity+m_deltaLinearVelocity + (m_angularVelocity+m_deltaAngularVelocity).cross(rel_pos);
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else
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velocity.setValue(0,0,0);
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}
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SIMD_FORCE_INLINE void getAngularVelocity(btVector3& angVel) const
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{
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if (m_originalBody)
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angVel =m_angularVelocity+m_deltaAngularVelocity;
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else
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angVel.setValue(0,0,0);
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}
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//Optimization for the iterative solver: avoid calculating constant terms involving inertia, normal, relative position
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SIMD_FORCE_INLINE void applyImpulse(const btVector3& linearComponent, const btVector3& angularComponent,const btScalar impulseMagnitude)
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{
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if (m_originalBody)
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{
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m_deltaLinearVelocity += linearComponent*impulseMagnitude*m_linearFactor;
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m_deltaAngularVelocity += angularComponent*(impulseMagnitude*m_angularFactor);
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}
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}
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SIMD_FORCE_INLINE void internalApplyPushImpulse(const btVector3& linearComponent, const btVector3& angularComponent,btScalar impulseMagnitude)
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{
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if (m_originalBody)
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{
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m_pushVelocity += linearComponent*impulseMagnitude*m_linearFactor;
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m_turnVelocity += angularComponent*(impulseMagnitude*m_angularFactor);
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}
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}
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const btVector3& getDeltaLinearVelocity() const
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{
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return m_deltaLinearVelocity;
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}
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const btVector3& getDeltaAngularVelocity() const
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{
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return m_deltaAngularVelocity;
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}
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const btVector3& getPushVelocity() const
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{
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return m_pushVelocity;
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}
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const btVector3& getTurnVelocity() const
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{
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return m_turnVelocity;
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}
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////////////////////////////////////////////////
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///some internal methods, don't use them
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btVector3& internalGetDeltaLinearVelocity()
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{
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return m_deltaLinearVelocity;
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}
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btVector3& internalGetDeltaAngularVelocity()
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{
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return m_deltaAngularVelocity;
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}
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const btVector3& internalGetAngularFactor() const
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{
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return m_angularFactor;
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}
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const btVector3& internalGetInvMass() const
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{
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return m_invMass;
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}
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void internalSetInvMass(const btVector3& invMass)
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{
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m_invMass = invMass;
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}
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btVector3& internalGetPushVelocity()
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{
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return m_pushVelocity;
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}
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btVector3& internalGetTurnVelocity()
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{
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return m_turnVelocity;
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}
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SIMD_FORCE_INLINE void internalGetVelocityInLocalPointObsolete(const btVector3& rel_pos, btVector3& velocity ) const
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{
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velocity = m_linearVelocity+m_deltaLinearVelocity + (m_angularVelocity+m_deltaAngularVelocity).cross(rel_pos);
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}
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SIMD_FORCE_INLINE void internalGetAngularVelocity(btVector3& angVel) const
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{
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angVel = m_angularVelocity+m_deltaAngularVelocity;
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}
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//Optimization for the iterative solver: avoid calculating constant terms involving inertia, normal, relative position
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SIMD_FORCE_INLINE void internalApplyImpulse(const btVector3& linearComponent, const btVector3& angularComponent,const btScalar impulseMagnitude)
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{
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if (m_originalBody)
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{
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m_deltaLinearVelocity += linearComponent*impulseMagnitude*m_linearFactor;
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m_deltaAngularVelocity += angularComponent*(impulseMagnitude*m_angularFactor);
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}
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}
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void writebackVelocity()
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{
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if (m_originalBody)
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{
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m_linearVelocity +=m_deltaLinearVelocity;
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m_angularVelocity += m_deltaAngularVelocity;
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//m_originalBody->setCompanionId(-1);
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}
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}
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void writebackVelocityAndTransform(btScalar timeStep, btScalar splitImpulseTurnErp)
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{
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(void) timeStep;
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if (m_originalBody)
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{
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m_linearVelocity += m_deltaLinearVelocity;
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m_angularVelocity += m_deltaAngularVelocity;
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//correct the position/orientation based on push/turn recovery
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btTransform newTransform;
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if (m_pushVelocity[0]!=0.f || m_pushVelocity[1]!=0 || m_pushVelocity[2]!=0 || m_turnVelocity[0]!=0.f || m_turnVelocity[1]!=0 || m_turnVelocity[2]!=0)
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{
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// btQuaternion orn = m_worldTransform.getRotation();
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btTransformUtil::integrateTransform(m_worldTransform,m_pushVelocity,m_turnVelocity*splitImpulseTurnErp,timeStep,newTransform);
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m_worldTransform = newTransform;
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}
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//m_worldTransform.setRotation(orn);
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//m_originalBody->setCompanionId(-1);
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}
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}
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};
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#endif //BT_SOLVER_BODY_H
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