mirror of https://github.com/axmolengine/axmol.git
414 lines
16 KiB
C++
414 lines
16 KiB
C++
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/*
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Bullet Continuous Collision Detection and Physics Library
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Copyright (c) 2003-2013 Erwin Coumans http://bulletphysics.org
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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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#include "btCompoundCompoundCollisionAlgorithm.h"
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#include "LinearMath/btQuickprof.h"
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#include "BulletCollision/CollisionDispatch/btCollisionObject.h"
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#include "BulletCollision/CollisionShapes/btCompoundShape.h"
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#include "BulletCollision/BroadphaseCollision/btDbvt.h"
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#include "LinearMath/btIDebugDraw.h"
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#include "LinearMath/btAabbUtil2.h"
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#include "BulletCollision/CollisionDispatch/btManifoldResult.h"
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#include "BulletCollision/CollisionDispatch/btCollisionObjectWrapper.h"
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//USE_LOCAL_STACK will avoid most (often all) dynamic memory allocations due to resizing in processCollision and MycollideTT
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#define USE_LOCAL_STACK 1
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btShapePairCallback gCompoundCompoundChildShapePairCallback = 0;
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btCompoundCompoundCollisionAlgorithm::btCompoundCompoundCollisionAlgorithm(const btCollisionAlgorithmConstructionInfo& ci, const btCollisionObjectWrapper* body0Wrap, const btCollisionObjectWrapper* body1Wrap, bool isSwapped)
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: btCompoundCollisionAlgorithm(ci, body0Wrap, body1Wrap, isSwapped)
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{
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void* ptr = btAlignedAlloc(sizeof(btHashedSimplePairCache), 16);
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m_childCollisionAlgorithmCache = new (ptr) btHashedSimplePairCache();
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const btCollisionObjectWrapper* col0ObjWrap = body0Wrap;
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btAssert(col0ObjWrap->getCollisionShape()->isCompound());
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const btCollisionObjectWrapper* col1ObjWrap = body1Wrap;
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btAssert(col1ObjWrap->getCollisionShape()->isCompound());
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const btCompoundShape* compoundShape0 = static_cast<const btCompoundShape*>(col0ObjWrap->getCollisionShape());
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m_compoundShapeRevision0 = compoundShape0->getUpdateRevision();
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const btCompoundShape* compoundShape1 = static_cast<const btCompoundShape*>(col1ObjWrap->getCollisionShape());
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m_compoundShapeRevision1 = compoundShape1->getUpdateRevision();
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}
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btCompoundCompoundCollisionAlgorithm::~btCompoundCompoundCollisionAlgorithm()
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{
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removeChildAlgorithms();
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m_childCollisionAlgorithmCache->~btHashedSimplePairCache();
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btAlignedFree(m_childCollisionAlgorithmCache);
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}
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void btCompoundCompoundCollisionAlgorithm::getAllContactManifolds(btManifoldArray& manifoldArray)
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{
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int i;
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btSimplePairArray& pairs = m_childCollisionAlgorithmCache->getOverlappingPairArray();
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for (i = 0; i < pairs.size(); i++)
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{
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if (pairs[i].m_userPointer)
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{
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((btCollisionAlgorithm*)pairs[i].m_userPointer)->getAllContactManifolds(manifoldArray);
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}
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}
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}
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void btCompoundCompoundCollisionAlgorithm::removeChildAlgorithms()
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{
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btSimplePairArray& pairs = m_childCollisionAlgorithmCache->getOverlappingPairArray();
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int numChildren = pairs.size();
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int i;
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for (i = 0; i < numChildren; i++)
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{
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if (pairs[i].m_userPointer)
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{
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btCollisionAlgorithm* algo = (btCollisionAlgorithm*)pairs[i].m_userPointer;
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algo->~btCollisionAlgorithm();
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m_dispatcher->freeCollisionAlgorithm(algo);
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}
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}
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m_childCollisionAlgorithmCache->removeAllPairs();
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}
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struct btCompoundCompoundLeafCallback : btDbvt::ICollide
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{
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int m_numOverlapPairs;
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const btCollisionObjectWrapper* m_compound0ColObjWrap;
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const btCollisionObjectWrapper* m_compound1ColObjWrap;
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btDispatcher* m_dispatcher;
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const btDispatcherInfo& m_dispatchInfo;
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btManifoldResult* m_resultOut;
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class btHashedSimplePairCache* m_childCollisionAlgorithmCache;
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btPersistentManifold* m_sharedManifold;
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btCompoundCompoundLeafCallback(const btCollisionObjectWrapper* compound1ObjWrap,
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const btCollisionObjectWrapper* compound0ObjWrap,
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btDispatcher* dispatcher,
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const btDispatcherInfo& dispatchInfo,
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btManifoldResult* resultOut,
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btHashedSimplePairCache* childAlgorithmsCache,
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btPersistentManifold* sharedManifold)
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: m_numOverlapPairs(0), m_compound0ColObjWrap(compound1ObjWrap), m_compound1ColObjWrap(compound0ObjWrap), m_dispatcher(dispatcher), m_dispatchInfo(dispatchInfo), m_resultOut(resultOut), m_childCollisionAlgorithmCache(childAlgorithmsCache), m_sharedManifold(sharedManifold)
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{
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}
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void Process(const btDbvtNode* leaf0, const btDbvtNode* leaf1)
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{
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BT_PROFILE("btCompoundCompoundLeafCallback::Process");
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m_numOverlapPairs++;
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int childIndex0 = leaf0->dataAsInt;
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int childIndex1 = leaf1->dataAsInt;
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btAssert(childIndex0 >= 0);
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btAssert(childIndex1 >= 0);
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const btCompoundShape* compoundShape0 = static_cast<const btCompoundShape*>(m_compound0ColObjWrap->getCollisionShape());
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btAssert(childIndex0 < compoundShape0->getNumChildShapes());
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const btCompoundShape* compoundShape1 = static_cast<const btCompoundShape*>(m_compound1ColObjWrap->getCollisionShape());
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btAssert(childIndex1 < compoundShape1->getNumChildShapes());
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const btCollisionShape* childShape0 = compoundShape0->getChildShape(childIndex0);
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const btCollisionShape* childShape1 = compoundShape1->getChildShape(childIndex1);
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//backup
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btTransform orgTrans0 = m_compound0ColObjWrap->getWorldTransform();
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const btTransform& childTrans0 = compoundShape0->getChildTransform(childIndex0);
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btTransform newChildWorldTrans0 = orgTrans0 * childTrans0;
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btTransform orgTrans1 = m_compound1ColObjWrap->getWorldTransform();
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const btTransform& childTrans1 = compoundShape1->getChildTransform(childIndex1);
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btTransform newChildWorldTrans1 = orgTrans1 * childTrans1;
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//perform an AABB check first
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btVector3 aabbMin0, aabbMax0, aabbMin1, aabbMax1;
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childShape0->getAabb(newChildWorldTrans0, aabbMin0, aabbMax0);
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childShape1->getAabb(newChildWorldTrans1, aabbMin1, aabbMax1);
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btVector3 thresholdVec(m_resultOut->m_closestPointDistanceThreshold, m_resultOut->m_closestPointDistanceThreshold, m_resultOut->m_closestPointDistanceThreshold);
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aabbMin0 -= thresholdVec;
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aabbMax0 += thresholdVec;
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if (gCompoundCompoundChildShapePairCallback)
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{
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if (!gCompoundCompoundChildShapePairCallback(childShape0, childShape1))
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return;
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}
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if (TestAabbAgainstAabb2(aabbMin0, aabbMax0, aabbMin1, aabbMax1))
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{
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btCollisionObjectWrapper compoundWrap0(this->m_compound0ColObjWrap, childShape0, m_compound0ColObjWrap->getCollisionObject(), newChildWorldTrans0, -1, childIndex0);
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btCollisionObjectWrapper compoundWrap1(this->m_compound1ColObjWrap, childShape1, m_compound1ColObjWrap->getCollisionObject(), newChildWorldTrans1, -1, childIndex1);
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btSimplePair* pair = m_childCollisionAlgorithmCache->findPair(childIndex0, childIndex1);
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bool removePair = false;
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btCollisionAlgorithm* colAlgo = 0;
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if (m_resultOut->m_closestPointDistanceThreshold > 0)
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{
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colAlgo = m_dispatcher->findAlgorithm(&compoundWrap0, &compoundWrap1, 0, BT_CLOSEST_POINT_ALGORITHMS);
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removePair = true;
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}
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else
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{
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if (pair)
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{
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colAlgo = (btCollisionAlgorithm*)pair->m_userPointer;
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}
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else
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{
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colAlgo = m_dispatcher->findAlgorithm(&compoundWrap0, &compoundWrap1, m_sharedManifold, BT_CONTACT_POINT_ALGORITHMS);
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pair = m_childCollisionAlgorithmCache->addOverlappingPair(childIndex0, childIndex1);
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btAssert(pair);
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pair->m_userPointer = colAlgo;
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}
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}
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btAssert(colAlgo);
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const btCollisionObjectWrapper* tmpWrap0 = 0;
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const btCollisionObjectWrapper* tmpWrap1 = 0;
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tmpWrap0 = m_resultOut->getBody0Wrap();
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tmpWrap1 = m_resultOut->getBody1Wrap();
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m_resultOut->setBody0Wrap(&compoundWrap0);
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m_resultOut->setBody1Wrap(&compoundWrap1);
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m_resultOut->setShapeIdentifiersA(-1, childIndex0);
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m_resultOut->setShapeIdentifiersB(-1, childIndex1);
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colAlgo->processCollision(&compoundWrap0, &compoundWrap1, m_dispatchInfo, m_resultOut);
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m_resultOut->setBody0Wrap(tmpWrap0);
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m_resultOut->setBody1Wrap(tmpWrap1);
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if (removePair)
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{
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colAlgo->~btCollisionAlgorithm();
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m_dispatcher->freeCollisionAlgorithm(colAlgo);
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}
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}
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}
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};
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static DBVT_INLINE bool MyIntersect(const btDbvtAabbMm& a,
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const btDbvtAabbMm& b, const btTransform& xform, btScalar distanceThreshold)
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{
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btVector3 newmin, newmax;
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btTransformAabb(b.Mins(), b.Maxs(), 0.f, xform, newmin, newmax);
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newmin -= btVector3(distanceThreshold, distanceThreshold, distanceThreshold);
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newmax += btVector3(distanceThreshold, distanceThreshold, distanceThreshold);
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btDbvtAabbMm newb = btDbvtAabbMm::FromMM(newmin, newmax);
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return Intersect(a, newb);
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}
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static inline void MycollideTT(const btDbvtNode* root0,
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const btDbvtNode* root1,
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const btTransform& xform,
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btCompoundCompoundLeafCallback* callback, btScalar distanceThreshold)
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{
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if (root0 && root1)
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{
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int depth = 1;
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int treshold = btDbvt::DOUBLE_STACKSIZE - 4;
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btAlignedObjectArray<btDbvt::sStkNN> stkStack;
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#ifdef USE_LOCAL_STACK
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ATTRIBUTE_ALIGNED16(btDbvt::sStkNN localStack[btDbvt::DOUBLE_STACKSIZE]);
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stkStack.initializeFromBuffer(&localStack, btDbvt::DOUBLE_STACKSIZE, btDbvt::DOUBLE_STACKSIZE);
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#else
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stkStack.resize(btDbvt::DOUBLE_STACKSIZE);
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#endif
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stkStack[0] = btDbvt::sStkNN(root0, root1);
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do
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{
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btDbvt::sStkNN p = stkStack[--depth];
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if (MyIntersect(p.a->volume, p.b->volume, xform, distanceThreshold))
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{
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if (depth > treshold)
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{
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stkStack.resize(stkStack.size() * 2);
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treshold = stkStack.size() - 4;
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}
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if (p.a->isinternal())
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{
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if (p.b->isinternal())
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{
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stkStack[depth++] = btDbvt::sStkNN(p.a->childs[0], p.b->childs[0]);
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stkStack[depth++] = btDbvt::sStkNN(p.a->childs[1], p.b->childs[0]);
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stkStack[depth++] = btDbvt::sStkNN(p.a->childs[0], p.b->childs[1]);
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stkStack[depth++] = btDbvt::sStkNN(p.a->childs[1], p.b->childs[1]);
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}
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else
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{
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stkStack[depth++] = btDbvt::sStkNN(p.a->childs[0], p.b);
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stkStack[depth++] = btDbvt::sStkNN(p.a->childs[1], p.b);
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}
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}
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else
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{
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if (p.b->isinternal())
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{
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stkStack[depth++] = btDbvt::sStkNN(p.a, p.b->childs[0]);
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stkStack[depth++] = btDbvt::sStkNN(p.a, p.b->childs[1]);
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}
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else
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{
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callback->Process(p.a, p.b);
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}
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}
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}
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} while (depth);
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}
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}
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void btCompoundCompoundCollisionAlgorithm::processCollision(const btCollisionObjectWrapper* body0Wrap, const btCollisionObjectWrapper* body1Wrap, const btDispatcherInfo& dispatchInfo, btManifoldResult* resultOut)
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{
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const btCollisionObjectWrapper* col0ObjWrap = body0Wrap;
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const btCollisionObjectWrapper* col1ObjWrap = body1Wrap;
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btAssert(col0ObjWrap->getCollisionShape()->isCompound());
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btAssert(col1ObjWrap->getCollisionShape()->isCompound());
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const btCompoundShape* compoundShape0 = static_cast<const btCompoundShape*>(col0ObjWrap->getCollisionShape());
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const btCompoundShape* compoundShape1 = static_cast<const btCompoundShape*>(col1ObjWrap->getCollisionShape());
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const btDbvt* tree0 = compoundShape0->getDynamicAabbTree();
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const btDbvt* tree1 = compoundShape1->getDynamicAabbTree();
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if (!tree0 || !tree1)
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{
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return btCompoundCollisionAlgorithm::processCollision(body0Wrap, body1Wrap, dispatchInfo, resultOut);
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}
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///btCompoundShape might have changed:
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////make sure the internal child collision algorithm caches are still valid
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if ((compoundShape0->getUpdateRevision() != m_compoundShapeRevision0) || (compoundShape1->getUpdateRevision() != m_compoundShapeRevision1))
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{
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///clear all
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removeChildAlgorithms();
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m_compoundShapeRevision0 = compoundShape0->getUpdateRevision();
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m_compoundShapeRevision1 = compoundShape1->getUpdateRevision();
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}
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///we need to refresh all contact manifolds
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///note that we should actually recursively traverse all children, btCompoundShape can nested more then 1 level deep
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///so we should add a 'refreshManifolds' in the btCollisionAlgorithm
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{
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int i;
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btManifoldArray manifoldArray;
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#ifdef USE_LOCAL_STACK
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btPersistentManifold localManifolds[4];
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manifoldArray.initializeFromBuffer(&localManifolds, 0, 4);
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#endif
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btSimplePairArray& pairs = m_childCollisionAlgorithmCache->getOverlappingPairArray();
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for (i = 0; i < pairs.size(); i++)
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{
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if (pairs[i].m_userPointer)
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{
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btCollisionAlgorithm* algo = (btCollisionAlgorithm*)pairs[i].m_userPointer;
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algo->getAllContactManifolds(manifoldArray);
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for (int m = 0; m < manifoldArray.size(); m++)
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{
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if (manifoldArray[m]->getNumContacts())
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{
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resultOut->setPersistentManifold(manifoldArray[m]);
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resultOut->refreshContactPoints();
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resultOut->setPersistentManifold(0);
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}
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}
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manifoldArray.resize(0);
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}
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}
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}
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btCompoundCompoundLeafCallback callback(col0ObjWrap, col1ObjWrap, this->m_dispatcher, dispatchInfo, resultOut, this->m_childCollisionAlgorithmCache, m_sharedManifold);
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const btTransform xform = col0ObjWrap->getWorldTransform().inverse() * col1ObjWrap->getWorldTransform();
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MycollideTT(tree0->m_root, tree1->m_root, xform, &callback, resultOut->m_closestPointDistanceThreshold);
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//printf("#compound-compound child/leaf overlap =%d \r",callback.m_numOverlapPairs);
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//remove non-overlapping child pairs
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{
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btAssert(m_removePairs.size() == 0);
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//iterate over all children, perform an AABB check inside ProcessChildShape
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btSimplePairArray& pairs = m_childCollisionAlgorithmCache->getOverlappingPairArray();
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int i;
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btManifoldArray manifoldArray;
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btVector3 aabbMin0, aabbMax0, aabbMin1, aabbMax1;
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for (i = 0; i < pairs.size(); i++)
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{
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if (pairs[i].m_userPointer)
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{
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btCollisionAlgorithm* algo = (btCollisionAlgorithm*)pairs[i].m_userPointer;
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{
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const btCollisionShape* childShape0 = 0;
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btTransform newChildWorldTrans0;
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childShape0 = compoundShape0->getChildShape(pairs[i].m_indexA);
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const btTransform& childTrans0 = compoundShape0->getChildTransform(pairs[i].m_indexA);
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newChildWorldTrans0 = col0ObjWrap->getWorldTransform() * childTrans0;
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childShape0->getAabb(newChildWorldTrans0, aabbMin0, aabbMax0);
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}
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btVector3 thresholdVec(resultOut->m_closestPointDistanceThreshold, resultOut->m_closestPointDistanceThreshold, resultOut->m_closestPointDistanceThreshold);
|
||
|
aabbMin0 -= thresholdVec;
|
||
|
aabbMax0 += thresholdVec;
|
||
|
{
|
||
|
const btCollisionShape* childShape1 = 0;
|
||
|
btTransform newChildWorldTrans1;
|
||
|
|
||
|
childShape1 = compoundShape1->getChildShape(pairs[i].m_indexB);
|
||
|
const btTransform& childTrans1 = compoundShape1->getChildTransform(pairs[i].m_indexB);
|
||
|
newChildWorldTrans1 = col1ObjWrap->getWorldTransform() * childTrans1;
|
||
|
childShape1->getAabb(newChildWorldTrans1, aabbMin1, aabbMax1);
|
||
|
}
|
||
|
|
||
|
aabbMin1 -= thresholdVec;
|
||
|
aabbMax1 += thresholdVec;
|
||
|
|
||
|
if (!TestAabbAgainstAabb2(aabbMin0, aabbMax0, aabbMin1, aabbMax1))
|
||
|
{
|
||
|
algo->~btCollisionAlgorithm();
|
||
|
m_dispatcher->freeCollisionAlgorithm(algo);
|
||
|
m_removePairs.push_back(btSimplePair(pairs[i].m_indexA, pairs[i].m_indexB));
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
for (int i = 0; i < m_removePairs.size(); i++)
|
||
|
{
|
||
|
m_childCollisionAlgorithmCache->removeOverlappingPair(m_removePairs[i].m_indexA, m_removePairs[i].m_indexB);
|
||
|
}
|
||
|
m_removePairs.clear();
|
||
|
}
|
||
|
}
|
||
|
|
||
|
btScalar btCompoundCompoundCollisionAlgorithm::calculateTimeOfImpact(btCollisionObject* body0, btCollisionObject* body1, const btDispatcherInfo& dispatchInfo, btManifoldResult* resultOut)
|
||
|
{
|
||
|
btAssert(0);
|
||
|
return 0.f;
|
||
|
}
|