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/*
Bullet Continuous Collision Detection and Physics Library
Copyright ( c ) 2003 - 2013 Erwin Coumans http : //bulletphysics.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 .
*/
/**
* @ mainpage Bullet Documentation
*
* @ section intro_sec Introduction
* Bullet is a Collision Detection and Rigid Body Dynamics Library . The Library is Open Source and free for commercial use , under the ZLib license ( http : //opensource.org/licenses/zlib-license.php ).
*
* The main documentation is Bullet_User_Manual . pdf , included in the source code distribution .
* There is the Physics Forum for feedback and general Collision Detection and Physics discussions .
* Please visit http : //www.bulletphysics.org
*
* @ section install_sec Installation
*
* @ subsection step1 Step 1 : Download
* You can download the Bullet Physics Library from the github repository : https : //github.com/bulletphysics/bullet3/releases
*
* @ subsection step2 Step 2 : Building
* Bullet has multiple build systems , including premake , cmake and autotools . Premake and cmake support all platforms .
* Premake is included in the Bullet / build folder for Windows , Mac OSX and Linux .
* Under Windows you can click on Bullet / build / vs2010 . bat to create Microsoft Visual Studio projects .
* On Mac OSX and Linux you can open a terminal and generate Makefile , codeblocks or Xcode4 projects :
* cd Bullet / build
* . / premake4_osx gmake or . / premake4_linux gmake or . / premake4_linux64 gmake or ( for Mac ) . / premake4_osx xcode4
* cd Bullet / build / gmake
* make
*
* An alternative to premake is cmake . You can download cmake from http : //www.cmake.org
* cmake can autogenerate projectfiles for Microsoft Visual Studio , Apple Xcode , KDevelop and Unix Makefiles .
* The easiest is to run the CMake cmake - gui graphical user interface and choose the options and generate projectfiles .
* You can also use cmake in the command - line . Here are some examples for various platforms :
* cmake . - G " Visual Studio 9 2008 "
* cmake . - G Xcode
* cmake . - G " Unix Makefiles "
* Although cmake is recommended , you can also use autotools for UNIX : . / autogen . sh . / configure to create a Makefile and then run make .
*
* @ subsection step3 Step 3 : Testing demos
* Try to run and experiment with BasicDemo executable as a starting point .
* Bullet can be used in several ways , as Full Rigid Body simulation , as Collision Detector Library or Low Level / Snippets like the GJK Closest Point calculation .
* The Dependencies can be seen in this documentation under Directories
*
* @ subsection step4 Step 4 : Integrating in your application , full Rigid Body and Soft Body simulation
* Check out BasicDemo how to create a btDynamicsWorld , btRigidBody and btCollisionShape , Stepping the simulation and synchronizing your graphics object transform .
* Check out SoftDemo how to use soft body dynamics , using btSoftRigidDynamicsWorld .
* @ subsection step5 Step 5 : Integrate the Collision Detection Library ( without Dynamics and other Extras )
* Bullet Collision Detection can also be used without the Dynamics / Extras .
* Check out btCollisionWorld and btCollisionObject , and the CollisionInterfaceDemo .
* @ subsection step6 Step 6 : Use Snippets like the GJK Closest Point calculation .
* Bullet has been designed in a modular way keeping dependencies to a minimum . The ConvexHullDistance demo demonstrates direct use of btGjkPairDetector .
*
* @ section copyright Copyright
* For up - to - data information and copyright and contributors list check out the Bullet_User_Manual . pdf
*
*/
# ifndef BT_COLLISION_WORLD_H
# define BT_COLLISION_WORLD_H
class btCollisionShape ;
class btConvexShape ;
class btBroadphaseInterface ;
class btSerializer ;
# include "LinearMath/btVector3.h"
# include "LinearMath/btTransform.h"
# include "btCollisionObject.h"
# include "btCollisionDispatcher.h"
# include "BulletCollision/BroadphaseCollision/btOverlappingPairCache.h"
# include "LinearMath/btAlignedObjectArray.h"
///CollisionWorld is interface and container for the collision detection
class btCollisionWorld
{
protected :
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btAlignedObjectArray < btCollisionObject * > m_collisionObjects ;
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btDispatcher * m_dispatcher1 ;
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btDispatcherInfo m_dispatchInfo ;
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btBroadphaseInterface * m_broadphasePairCache ;
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btIDebugDraw * m_debugDrawer ;
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///m_forceUpdateAllAabbs can be set to false as an optimization to only update active object AABBs
///it is true by default, because it is error-prone (setting the position of static objects wouldn't update their AABB)
bool m_forceUpdateAllAabbs ;
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void serializeCollisionObjects ( btSerializer * serializer ) ;
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void serializeContactManifolds ( btSerializer * serializer ) ;
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public :
//this constructor doesn't own the dispatcher and paircache/broadphase
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btCollisionWorld ( btDispatcher * dispatcher , btBroadphaseInterface * broadphasePairCache , btCollisionConfiguration * collisionConfiguration ) ;
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virtual ~ btCollisionWorld ( ) ;
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void setBroadphase ( btBroadphaseInterface * pairCache )
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{
m_broadphasePairCache = pairCache ;
}
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const btBroadphaseInterface * getBroadphase ( ) const
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{
return m_broadphasePairCache ;
}
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btBroadphaseInterface * getBroadphase ( )
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{
return m_broadphasePairCache ;
}
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btOverlappingPairCache * getPairCache ( )
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{
return m_broadphasePairCache - > getOverlappingPairCache ( ) ;
}
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btDispatcher * getDispatcher ( )
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{
return m_dispatcher1 ;
}
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const btDispatcher * getDispatcher ( ) const
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{
return m_dispatcher1 ;
}
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void updateSingleAabb ( btCollisionObject * colObj ) ;
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virtual void updateAabbs ( ) ;
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///the computeOverlappingPairs is usually already called by performDiscreteCollisionDetection (or stepSimulation)
///it can be useful to use if you perform ray tests without collision detection/simulation
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virtual void computeOverlappingPairs ( ) ;
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virtual void setDebugDrawer ( btIDebugDraw * debugDrawer )
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{
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m_debugDrawer = debugDrawer ;
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}
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virtual btIDebugDraw * getDebugDrawer ( )
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{
return m_debugDrawer ;
}
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virtual void debugDrawWorld ( ) ;
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virtual void debugDrawObject ( const btTransform & worldTransform , const btCollisionShape * shape , const btVector3 & color ) ;
///LocalShapeInfo gives extra information for complex shapes
///Currently, only btTriangleMeshShape is available, so it just contains triangleIndex and subpart
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struct LocalShapeInfo
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{
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int m_shapePart ;
int m_triangleIndex ;
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//const btCollisionShape* m_shapeTemp;
//const btTransform* m_shapeLocalTransform;
} ;
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struct LocalRayResult
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{
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LocalRayResult ( const btCollisionObject * collisionObject ,
LocalShapeInfo * localShapeInfo ,
const btVector3 & hitNormalLocal ,
btScalar hitFraction )
: m_collisionObject ( collisionObject ) ,
m_localShapeInfo ( localShapeInfo ) ,
m_hitNormalLocal ( hitNormalLocal ) ,
m_hitFraction ( hitFraction )
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{
}
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const btCollisionObject * m_collisionObject ;
LocalShapeInfo * m_localShapeInfo ;
btVector3 m_hitNormalLocal ;
btScalar m_hitFraction ;
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} ;
///RayResultCallback is used to report new raycast results
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struct RayResultCallback
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{
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btScalar m_closestHitFraction ;
const btCollisionObject * m_collisionObject ;
int m_collisionFilterGroup ;
int m_collisionFilterMask ;
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//@BP Mod - Custom flags, currently used to enable backface culling on tri-meshes, see btRaycastCallback.h. Apply any of the EFlags defined there on m_flags here to invoke.
unsigned int m_flags ;
virtual ~ RayResultCallback ( )
{
}
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bool hasHit ( ) const
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{
return ( m_collisionObject ! = 0 ) ;
}
RayResultCallback ( )
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: m_closestHitFraction ( btScalar ( 1. ) ) ,
m_collisionObject ( 0 ) ,
m_collisionFilterGroup ( btBroadphaseProxy : : DefaultFilter ) ,
m_collisionFilterMask ( btBroadphaseProxy : : AllFilter ) ,
//@BP Mod
m_flags ( 0 )
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{
}
virtual bool needsCollision ( btBroadphaseProxy * proxy0 ) const
{
bool collides = ( proxy0 - > m_collisionFilterGroup & m_collisionFilterMask ) ! = 0 ;
collides = collides & & ( m_collisionFilterGroup & proxy0 - > m_collisionFilterMask ) ;
return collides ;
}
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virtual btScalar addSingleResult ( LocalRayResult & rayResult , bool normalInWorldSpace ) = 0 ;
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} ;
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struct ClosestRayResultCallback : public RayResultCallback
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{
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ClosestRayResultCallback ( const btVector3 & rayFromWorld , const btVector3 & rayToWorld )
: m_rayFromWorld ( rayFromWorld ) ,
m_rayToWorld ( rayToWorld )
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{
}
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btVector3 m_rayFromWorld ; //used to calculate hitPointWorld from hitFraction
btVector3 m_rayToWorld ;
btVector3 m_hitNormalWorld ;
btVector3 m_hitPointWorld ;
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virtual btScalar addSingleResult ( LocalRayResult & rayResult , bool normalInWorldSpace )
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{
//caller already does the filter on the m_closestHitFraction
btAssert ( rayResult . m_hitFraction < = m_closestHitFraction ) ;
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m_closestHitFraction = rayResult . m_hitFraction ;
m_collisionObject = rayResult . m_collisionObject ;
if ( normalInWorldSpace )
{
m_hitNormalWorld = rayResult . m_hitNormalLocal ;
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}
else
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{
///need to transform normal into worldspace
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m_hitNormalWorld = m_collisionObject - > getWorldTransform ( ) . getBasis ( ) * rayResult . m_hitNormalLocal ;
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}
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m_hitPointWorld . setInterpolate3 ( m_rayFromWorld , m_rayToWorld , rayResult . m_hitFraction ) ;
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return rayResult . m_hitFraction ;
}
} ;
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struct AllHitsRayResultCallback : public RayResultCallback
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{
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AllHitsRayResultCallback ( const btVector3 & rayFromWorld , const btVector3 & rayToWorld )
: m_rayFromWorld ( rayFromWorld ) ,
m_rayToWorld ( rayToWorld )
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{
}
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btAlignedObjectArray < const btCollisionObject * > m_collisionObjects ;
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btVector3 m_rayFromWorld ; //used to calculate hitPointWorld from hitFraction
btVector3 m_rayToWorld ;
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btAlignedObjectArray < btVector3 > m_hitNormalWorld ;
btAlignedObjectArray < btVector3 > m_hitPointWorld ;
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btAlignedObjectArray < btScalar > m_hitFractions ;
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virtual btScalar addSingleResult ( LocalRayResult & rayResult , bool normalInWorldSpace )
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{
m_collisionObject = rayResult . m_collisionObject ;
m_collisionObjects . push_back ( rayResult . m_collisionObject ) ;
btVector3 hitNormalWorld ;
if ( normalInWorldSpace )
{
hitNormalWorld = rayResult . m_hitNormalLocal ;
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}
else
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{
///need to transform normal into worldspace
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hitNormalWorld = m_collisionObject - > getWorldTransform ( ) . getBasis ( ) * rayResult . m_hitNormalLocal ;
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}
m_hitNormalWorld . push_back ( hitNormalWorld ) ;
btVector3 hitPointWorld ;
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hitPointWorld . setInterpolate3 ( m_rayFromWorld , m_rayToWorld , rayResult . m_hitFraction ) ;
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m_hitPointWorld . push_back ( hitPointWorld ) ;
m_hitFractions . push_back ( rayResult . m_hitFraction ) ;
return m_closestHitFraction ;
}
} ;
struct LocalConvexResult
{
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LocalConvexResult ( const btCollisionObject * hitCollisionObject ,
LocalShapeInfo * localShapeInfo ,
const btVector3 & hitNormalLocal ,
const btVector3 & hitPointLocal ,
btScalar hitFraction )
: m_hitCollisionObject ( hitCollisionObject ) ,
m_localShapeInfo ( localShapeInfo ) ,
m_hitNormalLocal ( hitNormalLocal ) ,
m_hitPointLocal ( hitPointLocal ) ,
m_hitFraction ( hitFraction )
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{
}
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const btCollisionObject * m_hitCollisionObject ;
LocalShapeInfo * m_localShapeInfo ;
btVector3 m_hitNormalLocal ;
btVector3 m_hitPointLocal ;
btScalar m_hitFraction ;
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} ;
///RayResultCallback is used to report new raycast results
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struct ConvexResultCallback
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{
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btScalar m_closestHitFraction ;
int m_collisionFilterGroup ;
int m_collisionFilterMask ;
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ConvexResultCallback ( )
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: m_closestHitFraction ( btScalar ( 1. ) ) ,
m_collisionFilterGroup ( btBroadphaseProxy : : DefaultFilter ) ,
m_collisionFilterMask ( btBroadphaseProxy : : AllFilter )
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{
}
virtual ~ ConvexResultCallback ( )
{
}
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bool hasHit ( ) const
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{
return ( m_closestHitFraction < btScalar ( 1. ) ) ;
}
virtual bool needsCollision ( btBroadphaseProxy * proxy0 ) const
{
bool collides = ( proxy0 - > m_collisionFilterGroup & m_collisionFilterMask ) ! = 0 ;
collides = collides & & ( m_collisionFilterGroup & proxy0 - > m_collisionFilterMask ) ;
return collides ;
}
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virtual btScalar addSingleResult ( LocalConvexResult & convexResult , bool normalInWorldSpace ) = 0 ;
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} ;
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struct ClosestConvexResultCallback : public ConvexResultCallback
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{
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ClosestConvexResultCallback ( const btVector3 & convexFromWorld , const btVector3 & convexToWorld )
: m_convexFromWorld ( convexFromWorld ) ,
m_convexToWorld ( convexToWorld ) ,
m_hitCollisionObject ( 0 )
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{
}
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btVector3 m_convexFromWorld ; //used to calculate hitPointWorld from hitFraction
btVector3 m_convexToWorld ;
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btVector3 m_hitNormalWorld ;
btVector3 m_hitPointWorld ;
const btCollisionObject * m_hitCollisionObject ;
virtual btScalar addSingleResult ( LocalConvexResult & convexResult , bool normalInWorldSpace )
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{
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//caller already does the filter on the m_closestHitFraction
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btAssert ( convexResult . m_hitFraction < = m_closestHitFraction ) ;
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m_closestHitFraction = convexResult . m_hitFraction ;
m_hitCollisionObject = convexResult . m_hitCollisionObject ;
if ( normalInWorldSpace )
{
m_hitNormalWorld = convexResult . m_hitNormalLocal ;
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}
else
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{
///need to transform normal into worldspace
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m_hitNormalWorld = m_hitCollisionObject - > getWorldTransform ( ) . getBasis ( ) * convexResult . m_hitNormalLocal ;
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}
m_hitPointWorld = convexResult . m_hitPointLocal ;
return convexResult . m_hitFraction ;
}
} ;
///ContactResultCallback is used to report contact points
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struct ContactResultCallback
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{
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int m_collisionFilterGroup ;
int m_collisionFilterMask ;
btScalar m_closestDistanceThreshold ;
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ContactResultCallback ( )
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: m_collisionFilterGroup ( btBroadphaseProxy : : DefaultFilter ) ,
m_collisionFilterMask ( btBroadphaseProxy : : AllFilter ) ,
m_closestDistanceThreshold ( 0 )
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{
}
virtual ~ ContactResultCallback ( )
{
}
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virtual bool needsCollision ( btBroadphaseProxy * proxy0 ) const
{
bool collides = ( proxy0 - > m_collisionFilterGroup & m_collisionFilterMask ) ! = 0 ;
collides = collides & & ( m_collisionFilterGroup & proxy0 - > m_collisionFilterMask ) ;
return collides ;
}
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virtual btScalar addSingleResult ( btManifoldPoint & cp , const btCollisionObjectWrapper * colObj0Wrap , int partId0 , int index0 , const btCollisionObjectWrapper * colObj1Wrap , int partId1 , int index1 ) = 0 ;
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} ;
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int getNumCollisionObjects ( ) const
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{
return int ( m_collisionObjects . size ( ) ) ;
}
/// rayTest performs a raycast on all objects in the btCollisionWorld, and calls the resultCallback
/// This allows for several queries: first hit, all hits, any hit, dependent on the value returned by the callback.
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virtual void rayTest ( const btVector3 & rayFromWorld , const btVector3 & rayToWorld , RayResultCallback & resultCallback ) const ;
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/// convexTest performs a swept convex cast on all objects in the btCollisionWorld, and calls the resultCallback
/// This allows for several queries: first hit, all hits, any hit, dependent on the value return by the callback.
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void convexSweepTest ( const btConvexShape * castShape , const btTransform & from , const btTransform & to , ConvexResultCallback & resultCallback , btScalar allowedCcdPenetration = btScalar ( 0. ) ) const ;
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///contactTest performs a discrete collision test between colObj against all objects in the btCollisionWorld, and calls the resultCallback.
///it reports one or more contact points for every overlapping object (including the one with deepest penetration)
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void contactTest ( btCollisionObject * colObj , ContactResultCallback & resultCallback ) ;
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///contactTest performs a discrete collision test between two collision objects and calls the resultCallback if overlap if detected.
///it reports one or more contact points (including the one with deepest penetration)
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void contactPairTest ( btCollisionObject * colObjA , btCollisionObject * colObjB , ContactResultCallback & resultCallback ) ;
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/// rayTestSingle performs a raycast call and calls the resultCallback. It is used internally by rayTest.
/// In a future implementation, we consider moving the ray test as a virtual method in btCollisionShape.
/// This allows more customization.
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static void rayTestSingle ( const btTransform & rayFromTrans , const btTransform & rayToTrans ,
btCollisionObject * collisionObject ,
const btCollisionShape * collisionShape ,
const btTransform & colObjWorldTransform ,
RayResultCallback & resultCallback ) ;
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static void rayTestSingleInternal ( const btTransform & rayFromTrans , const btTransform & rayToTrans ,
const btCollisionObjectWrapper * collisionObjectWrap ,
RayResultCallback & resultCallback ) ;
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/// objectQuerySingle performs a collision detection query and calls the resultCallback. It is used internally by rayTest.
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static void objectQuerySingle ( const btConvexShape * castShape , const btTransform & rayFromTrans , const btTransform & rayToTrans ,
btCollisionObject * collisionObject ,
const btCollisionShape * collisionShape ,
const btTransform & colObjWorldTransform ,
ConvexResultCallback & resultCallback , btScalar allowedPenetration ) ;
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static void objectQuerySingleInternal ( const btConvexShape * castShape , const btTransform & convexFromTrans , const btTransform & convexToTrans ,
const btCollisionObjectWrapper * colObjWrap ,
ConvexResultCallback & resultCallback , btScalar allowedPenetration ) ;
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virtual void addCollisionObject ( btCollisionObject * collisionObject , int collisionFilterGroup = btBroadphaseProxy : : DefaultFilter , int collisionFilterMask = btBroadphaseProxy : : AllFilter ) ;
virtual void refreshBroadphaseProxy ( btCollisionObject * collisionObject ) ;
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btCollisionObjectArray & getCollisionObjectArray ( )
{
return m_collisionObjects ;
}
const btCollisionObjectArray & getCollisionObjectArray ( ) const
{
return m_collisionObjects ;
}
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virtual void removeCollisionObject ( btCollisionObject * collisionObject ) ;
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virtual void performDiscreteCollisionDetection ( ) ;
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btDispatcherInfo & getDispatchInfo ( )
{
return m_dispatchInfo ;
}
const btDispatcherInfo & getDispatchInfo ( ) const
{
return m_dispatchInfo ;
}
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bool getForceUpdateAllAabbs ( ) const
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{
return m_forceUpdateAllAabbs ;
}
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void setForceUpdateAllAabbs ( bool forceUpdateAllAabbs )
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{
m_forceUpdateAllAabbs = forceUpdateAllAabbs ;
}
///Preliminary serialization test for Bullet 2.76. Loading those files requires a separate parser (Bullet/Demos/SerializeDemo)
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virtual void serialize ( btSerializer * serializer ) ;
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} ;
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# endif //BT_COLLISION_WORLD_H