PfxFloat pfxContactCapsuleCapsule( PfxVector3 &normal,PfxPoint3 &pointA,PfxPoint3 &pointB, void *shapeA,const PfxTransform3 &transformA, void *shapeB,const PfxTransform3 &transformB, PfxFloat distanceThreshold) { PfxCapsule &capsuleA = *((PfxCapsule*)shapeA); PfxCapsule &capsuleB = *((PfxCapsule*)shapeB); PfxVector3 directionA = transformA.getUpper3x3().getCol0(); PfxVector3 translationA = transformA.getTranslation(); PfxVector3 directionB = transformB.getUpper3x3().getCol0(); PfxVector3 translationB = transformB.getTranslation(); // translation between centers PfxVector3 translation = translationB - translationA; // compute the closest points of the capsule line segments PfxVector3 ptsVector; // the vector between the closest points PfxVector3 offsetA, offsetB; // offsets from segment centers to their closest points PfxFloat tA, tB; // parameters on line segment segmentsClosestPoints( ptsVector, offsetA, offsetB, tA, tB, translation, directionA, capsuleA.m_halfLen, directionB, capsuleB.m_halfLen ); PfxFloat distance = length(ptsVector) - capsuleA.m_radius - capsuleB.m_radius; if ( distance > distanceThreshold ) return distance; // compute the contact normal segmentsNormal( normal, ptsVector ); // compute points on capsules pointA = PfxPoint3( transpose(transformA.getUpper3x3()) * ( offsetA + normal * capsuleA.m_radius ) ); pointB = PfxPoint3( transpose(transformB.getUpper3x3()) * ( offsetB - normal * capsuleB.m_radius ) ); return distance; }
PfxFloat pfxContactCapsuleSphere( PfxVector3 &normal,PfxPoint3 &pointA,PfxPoint3 &pointB, void *shapeA,const PfxTransform3 &transformA, void *shapeB,const PfxTransform3 &transformB, PfxFloat distanceThreshold) { PfxCapsule &capsuleA = *((PfxCapsule*)shapeA); PfxSphere &sphereB = *((PfxSphere*)shapeB); PfxVector3 directionA = transformA.getUpper3x3().getCol0(); PfxVector3 translationA = transformA.getTranslation(); PfxVector3 translationB = transformB.getTranslation(); // translation between centers of capsule and sphere PfxVector3 translation = translationB - translationA; // compute the closest point on the capsule line segment to the sphere center PfxVector3 ptsVector; PfxVector3 offsetA; PfxFloat tA; segmentPointClosestPoints( ptsVector, offsetA, tA, translation, directionA, capsuleA.m_halfLen ); PfxFloat distance = length(ptsVector) - capsuleA.m_radius - sphereB.m_radius; if ( distance > distanceThreshold ) return distance; // compute the contact normal segmentPointNormal( normal, ptsVector ); // compute points on capsule and sphere pointA = PfxPoint3( transpose(transformA.getUpper3x3()) * ( offsetA + normal * capsuleA.m_radius ) ); pointB = PfxPoint3( transpose(transformB.getUpper3x3()) * ( -normal * sphereB.m_radius ) ); return distance; }
PfxBool pfxIntersectRayBox(const PfxRayInput &ray,PfxRayOutput &out,const PfxBox &box,const PfxTransform3 &transform) { // レイをBoxのローカル座標へ変換 PfxTransform3 transformBox = orthoInverse(transform); PfxVector3 rayStartPosition = transformBox.getUpper3x3() * ray.m_startPosition + transformBox.getTranslation(); PfxVector3 rayDirection = transformBox.getUpper3x3() * ray.m_direction; // 交差判定 PfxFloat tmpVariable=0.0f; PfxVector3 tmpNormal(0.0f); if(pfxIntersectRayAABB(rayStartPosition,rayDirection,PfxVector3(0.0f),box.m_half,tmpVariable,tmpNormal)) { if(tmpVariable > 0.0f && tmpVariable < out.m_variable) { out.m_contactFlag = true; out.m_variable = tmpVariable; out.m_contactPoint = ray.m_startPosition + tmpVariable * ray.m_direction; out.m_contactNormal = transform.getUpper3x3() * tmpNormal; out.m_subData.m_type = PfxSubData::NONE; return true; } } return false; }
static void convertToBullet(void) { cleanupBullet(); m_config = new btDefaultCollisionConfiguration(); btHashedOverlappingPairCache* pairCache = new btHashedOverlappingPairCache(); //m_broadphase = new btDbvtBroadphase(); btLowLevelData* lowLevelData = new btLowLevelData; lowLevelData->m_maxContacts = NUM_CONTACTS;//8024; lowLevelData->m_contactIdPool = (int*) btAlignedAlloc(sizeof(int)*lowLevelData->m_maxContacts ,16); lowLevelData->m_contacts = (PfxContactManifold*) btAlignedAlloc(sizeof(PfxContactManifold)*lowLevelData->m_maxContacts,16); lowLevelData->m_maxPairs = lowLevelData->m_maxContacts;//?? lowLevelData->m_pairsBuff[0] = (PfxBroadphasePair*) btAlignedAlloc(sizeof(PfxBroadphasePair)*lowLevelData->m_maxPairs,16); lowLevelData->m_pairsBuff[1] = (PfxBroadphasePair*) btAlignedAlloc(sizeof(PfxBroadphasePair)*lowLevelData->m_maxPairs,16); #define USE_LL_BP #ifdef USE_LL_BP btLowLevelBroadphase* llbp = new btLowLevelBroadphase(lowLevelData,pairCache); m_broadphase = llbp; #else //USE_LL_BP m_broadphase = new btDbvtBroadphase(); #endif //USE_LL_BP //m_dispatcher = new btCollisionDispatcher(m_config); m_dispatcher = new btLowLevelCollisionDispatcher(lowLevelData,m_config,NUM_CONTACTS); //#ifdef USE_PARALLEL_SOLVER // m_solver = new btSequentialImpulseConstraintSolver(); //#else //sThreadSupport = createSolverThreadSupport(4); //m_solver = new btLowLevelConstraintSolver(sThreadSupport); m_solver = new btLowLevelConstraintSolver2(lowLevelData); //#endif //USE_PARALLEL_SOLVER //m_dynamicsWorld = new btDiscreteDynamicsWorld(m_dispatcher,m_broadphase,m_solver,m_config); m_dynamicsWorld = new btBulletPhysicsEffectsWorld(lowLevelData, m_dispatcher,llbp,m_solver,m_config,0); PEDebugDrawer* drawer = new PEDebugDrawer(); drawer->setDebugMode(btIDebugDraw::DBG_DrawWireframe+btIDebugDraw::DBG_DrawAabb); m_dynamicsWorld->setDebugDrawer(drawer); m_dynamicsWorld ->getSolverInfo().m_splitImpulse = true; for(int i=0;i<physics_get_num_rigidbodies();i++) { btRigidBody* body = 0; btAlignedObjectArray<btCollisionShape*> shapes; btAlignedObjectArray<btTransform> childTtransforms; PfxRigidState &state = states[i];//physics_get_state(i); state.setUserData(0); const PfxCollidable &coll = physics_get_collidable(i); PfxTransform3 rbT(state.getOrientation(), state.getPosition()); PfxShapeIterator itrShape(coll); for(int j=0;j<coll.getNumShapes();j++,++itrShape) { const PfxShape &shape = *itrShape; PfxTransform3 offsetT = shape.getOffsetTransform(); PfxTransform3 worldT = rbT * offsetT; btTransform childTransform; childTransform.setIdentity(); childTransform.setOrigin(getBtVector3(offsetT.getTranslation())); PfxQuat quat(offsetT.getUpper3x3()); childTransform.setBasis(btMatrix3x3(getBtQuat(quat))); childTtransforms.push_back(childTransform); switch(shape.getType()) { case kPfxShapeSphere: { btSphereShape* sphere = new btSphereShape(shape.getSphere().m_radius); shapes.push_back(sphere); //render_sphere( worldT, Vectormath::Aos::Vector3(1,1,1),Vectormath::floatInVec(shape.getSphere().m_radius)); } break; case kPfxShapeBox: { btBoxShape* box = new btBoxShape(getBtVector3(shape.getBox().m_half)); shapes.push_back(box); } //render_box( worldT, Vectormath::Aos::Vector3(1,1,1), shape.getBox().m_half); break; case kPfxShapeCapsule: shapes.push_back(new btCapsuleShapeX(shape.getCapsule().m_radius,2.f*shape.getCapsule().m_halfLen)); //render_capsule( worldT, Vectormath::Aos::Vector3(1,1,1), Vectormath::floatInVec(shape.getCapsule().m_radius), Vectormath::floatInVec(shape.getCapsule().m_halfLen)); break; case kPfxShapeCylinder: shapes.push_back(new btCylinderShapeX(btVector3(shape.getCylinder().m_halfLen,shape.getCylinder().m_radius,shape.getCylinder().m_radius))); //render_cylinder( worldT, Vectormath::Aos::Vector3(1,1,1), Vectormath::floatInVec(shape.getCylinder().m_radius),Vectormath::floatInVec(shape.getCylinder().m_halfLen)); break; case kPfxShapeConvexMesh: { const PfxConvexMesh* convex = shape.getConvexMesh(); const btScalar* vertices = (const btScalar*)&convex->m_verts[0]; btConvexHullShape* convexHull = new btConvexHullShape(vertices,convex->m_numVerts, sizeof(PfxVector3)); shapes.push_back(convexHull); } break; case kPfxShapeLargeTriMesh: { const PfxLargeTriMesh* mesh = shape.getLargeTriMesh(); btTriangleIndexVertexArray* meshInterface = new btTriangleIndexVertexArray(); int i; for (i= 0; i < mesh->m_numIslands;i++) { PfxTriMesh* island = &mesh->m_islands[i]; //mesh->m_islands //mesh->m_numIslands btIndexedMesh indexedMesh; indexedMesh.m_indexType = PHY_UCHAR; indexedMesh.m_numTriangles = island->m_numFacets; indexedMesh.m_triangleIndexBase = &island->m_facets[0].m_vertIds[0]; indexedMesh.m_triangleIndexStride = sizeof(PfxFacet); indexedMesh.m_vertexBase = (const unsigned char*) &island->m_verts[0]; indexedMesh.m_numVertices = island->m_numVerts;//unused indexedMesh.m_vertexStride = sizeof(PfxVector3); meshInterface->addIndexedMesh(indexedMesh,PHY_UCHAR); } btBvhTriangleMeshShape* trimesh = new btBvhTriangleMeshShape(meshInterface,true); shapes.push_back(trimesh); } break; default: { printf("unknown\n"); } break; } } if(shapes.size()>0) { printf("shapes!\n"); btCollisionShape* colShape = 0; if (shapes.size()==1 && childTtransforms[0].getOrigin().fuzzyZero()) //todo: also check orientation { colShape = shapes[0]; } else { btCompoundShape* compound = new btCompoundShape(); for (int i=0;i<shapes.size();i++) { compound->addChildShape(childTtransforms[i],shapes[i]); } colShape = compound; } btTransform worldTransform; worldTransform.setIdentity(); worldTransform.setOrigin(getBtVector3(rbT.getTranslation())); PfxQuat quat(rbT.getUpper3x3()); worldTransform.setBasis(btMatrix3x3(getBtQuat(quat))); btScalar mass = physics_get_body(i).getMass(); btRigidBody* body = addRigidBody(colShape,mass,worldTransform); void* ptr = (void*)&state; body->setUserPointer(ptr); state.setUserData(body); } } //very basic joint conversion (only limits of PFX_JOINT_SWINGTWIST joint) for (int i=0;i<numJoints;i++) { PfxJoint& joint = joints[i]; switch (joint.m_type) { case kPfxJointSwingtwist: { //btConeTwistConstraint* coneTwist = new btConeTwistConstraint(rbA,rbB,frameA,frameB); bool referenceA = true; btRigidBody* bodyA = (btRigidBody*)states[joint.m_rigidBodyIdA].getUserData(); btRigidBody* bodyB = (btRigidBody*)states[joint.m_rigidBodyIdB].getUserData(); if (bodyA&&bodyB) { btTransform frameA,frameB; frameA.setIdentity(); frameB.setIdentity(); frameA.setOrigin(getBtVector3(joint.m_anchorA)); frameB.setOrigin(getBtVector3(joint.m_anchorB)); bool referenceA = false; btGeneric6DofConstraint* dof6 = new btGeneric6DofConstraint(*bodyA,*bodyB,frameA,frameB,referenceA); for (int i=0;i<joint.m_numConstraints;i++) { switch (joint.m_constraints[i].m_lock) { case SCE_PFX_JOINT_LOCK_FIX: { dof6->setLimit(i,0,0); break; } case SCE_PFX_JOINT_LOCK_FREE: { dof6->setLimit(i,1,0); break; } case SCE_PFX_JOINT_LOCK_LIMIT: { //deal with the case where angular limits of Y-axis are free and/or beyond -PI/2 and PI/2 if ((i==4) && ((joint.m_constraints[i].m_movableLowerLimit<-SIMD_PI/2)||(joint.m_constraints[i].m_movableUpperLimit>SIMD_PI/2))) { printf("error with joint limits, forcing DOF to fixed\n"); dof6->setLimit(i,0,0); } else { dof6->setLimit(i,joint.m_constraints[i].m_movableLowerLimit,joint.m_constraints[i].m_movableUpperLimit); } break; } default: { printf("unknown joint lock state\n"); } } } m_dynamicsWorld->addConstraint(dof6,true); } else { printf("error: missing bodies during joint conversion\n"); } break; }; case kPfxJointBall: case kPfxJointHinge: case kPfxJointSlider: case kPfxJointFix: case kPfxJointUniversal: case kPfxJointAnimation: default: { printf("unknown joint\n"); } } } //create a large enough buffer. There is no method to pre-calculate the buffer size yet. int maxSerializeBufferSize = 1024*1024*5; btDefaultSerializer* serializer = new btDefaultSerializer(maxSerializeBufferSize); m_dynamicsWorld->serialize(serializer); FILE* file = fopen("testFile.bullet","wb"); fwrite(serializer->getBufferPointer(),serializer->getCurrentBufferSize(),1, file); fclose(file); }
void graphics_from_physics(GLInstancingRenderer& renderer, bool syncTransformsOnly) { int cubeShapeIndex = -1; int strideInBytes = sizeof(float)*9; if (!syncTransformsOnly) { int numVertices = sizeof(cube_vertices)/strideInBytes; int numIndices = sizeof(cube_indices)/sizeof(int); cubeShapeIndex = renderer.registerShape(&cube_vertices[0],numVertices,cube_indices,numIndices); } int curGraphicsIndex=0; for(int i=0;i<physics_get_num_rigidbodies();i++) { const PfxRigidState &state = physics_get_state(i); const PfxCollidable &coll = physics_get_collidable(i); const PfxRigidBody& body = physics_get_body(i); float color[4]={0,0,0,1}; if (body.getMass()==0.f) { color[0]=1.f; } else { color[1]=1.f; } PfxTransform3 rbT(state.getOrientation(), state.getPosition()); PfxShapeIterator itrShape(coll); for(int j=0;j<coll.getNumShapes();j++,++itrShape) { const PfxShape &shape = *itrShape; PfxTransform3 offsetT = shape.getOffsetTransform(); PfxTransform3 worldT = rbT * offsetT; PfxQuat ornWorld( worldT.getUpper3x3()); switch(shape.getType()) { case kPfxShapeSphere: printf("render sphere\n"); /*render_sphere( worldT, PfxVector3(1,1,1), PfxFloatInVec(shape.getSphere().m_radius)); */ break; case kPfxShapeBox: { // printf("render box\n"); float cubeScaling[4] = {shape.getBox().m_half.getX(),shape.getBox().m_half.getY(),shape.getBox().m_half.getZ(),1}; float rotOrn[4] = {ornWorld.getX(),ornWorld.getY(),ornWorld.getZ(),ornWorld.getW()}; float position[4]={worldT.getTranslation().getX(),worldT.getTranslation().getY(),worldT.getTranslation().getZ(),0}; if (!syncTransformsOnly) { renderer.registerGraphicsInstance(cubeShapeIndex,position,rotOrn,color,cubeScaling); } else { renderer.writeSingleInstanceTransformToCPU(position,rotOrn,curGraphicsIndex); } curGraphicsIndex++; /* render_box( worldT, PfxVector3(1,1,1), shape.getBox().m_half); */ break; } case kPfxShapeCapsule: printf("render_capsule\n"); /*render_capsule( worldT, PfxVector3(1,1,1), PfxFloatInVec(shape.getCapsule().m_radius), PfxFloatInVec(shape.getCapsule().m_halfLen)); */ break; case kPfxShapeCylinder: printf("render_cylinder\n"); /* render_cylinder( worldT, PfxVector3(1,1,1), PfxFloatInVec(shape.getCylinder().m_radius), PfxFloatInVec(shape.getCylinder().m_halfLen)); */ break; case kPfxShapeConvexMesh: printf("render_mesh\n"); /* render_mesh( worldT, PfxVector3(1,1,1), convexMeshId); */ break; case kPfxShapeLargeTriMesh: printf("render_mesh\n"); /* render_mesh( worldT, PfxVector3(1,1,1), landscapeMeshId); */ break; default: break; } } } }
PfxInt32 pfxContactTriMeshSphere( PfxContactCache &contacts, const PfxTriMesh *meshA, const PfxTransform3 &transformA, const PfxSphere &sphereB, const PfxTransform3 &transformB, PfxFloat distanceThreshold) { (void) distanceThreshold; PfxTransform3 transformAB,transformBA; PfxMatrix3 matrixBA; PfxVector3 offsetBA; // Bローカル→Aローカルへの変換 transformAB = orthoInverse(transformA) * transformB; // Aローカル→Bローカルへの変換 transformBA = orthoInverse(transformAB); matrixBA = transformBA.getUpper3x3(); offsetBA = transformBA.getTranslation(); //------------------------------------------- // 判定する面を絞り込む PfxUInt8 SCE_PFX_ALIGNED(16) selFacets[SCE_PFX_NUMMESHFACETS] = {0}; PfxUInt32 numSelFacets = 0; PfxVector3 aabbB(sphereB.m_radius); numSelFacets = pfxGatherFacets(meshA,(PfxFloat*)&aabbB,offsetBA,matrixBA,selFacets); if(numSelFacets == 0) { return 0; } //----------------------------------------------- // 判定 PfxContactCache localContacts; // TriangleMeshの面->sphereの判定 // ※TriangleMesh座標系 { for(PfxUInt32 f = 0; f < numSelFacets; f++ ) { const PfxFacet &facet = meshA->m_facets[selFacets[f]]; const PfxVector3 facetNormal = pfxReadVector3(facet.m_normal); const PfxVector3 facetPnts[3] = { meshA->m_verts[facet.m_vertIds[0]], meshA->m_verts[facet.m_vertIds[1]], meshA->m_verts[facet.m_vertIds[2]], }; const PfxEdge *edge[3] = { &meshA->m_edges[facet.m_edgeIds[0]], &meshA->m_edges[facet.m_edgeIds[1]], &meshA->m_edges[facet.m_edgeIds[2]], }; PfxVector3 sepAxis,pntA,pntB; PfxUInt32 edgeChk = ((edge[0]->m_angleType==SCE_PFX_EDGE_CONVEX)?0x00:0x01) | ((edge[1]->m_angleType==SCE_PFX_EDGE_CONVEX)?0x00:0x02) | ((edge[2]->m_angleType==SCE_PFX_EDGE_CONVEX)?0x00:0x04); pfxContactTriangleSphere(localContacts,selFacets[f], facetNormal,facetPnts[0],facetPnts[1],facetPnts[2], facet.m_thickness, 0.5f*SCE_PFX_PI*(edge[0]->m_tilt/255.0f), 0.5f*SCE_PFX_PI*(edge[1]->m_tilt/255.0f), 0.5f*SCE_PFX_PI*(edge[2]->m_tilt/255.0f), edgeChk, sphereB.m_radius,transformAB.getTranslation()); } } for(int i=0;i<localContacts.getNumContacts();i++) { PfxSubData subData = localContacts.getSubData(i); const PfxFacet &facet = meshA->m_facets[subData.getFacetId()]; PfxTriangle triangleA( meshA->m_verts[facet.m_vertIds[0]], meshA->m_verts[facet.m_vertIds[1]], meshA->m_verts[facet.m_vertIds[2]]); PfxFloat s=0.0f,t=0.0f; pfxGetLocalCoords(PfxVector3(localContacts.getLocalPointA(i)),triangleA,s,t); subData.m_type = PfxSubData::MESH_INFO; subData.setFacetLocalS(s); subData.setFacetLocalT(t); contacts.addContactPoint( localContacts.getDistance(i), transformA.getUpper3x3() * localContacts.getNormal(i), localContacts.getLocalPointA(i), transformBA * localContacts.getLocalPointB(i), subData); } return contacts.getNumContacts(); }
PfxInt32 pfxContactLargeTriMesh( PfxContactCache &contacts, const PfxLargeTriMesh *lmeshA, const PfxTransform3 &transformA, const PfxShape &shapeB, const PfxTransform3 &transformB, PfxFloat distanceThreshold) { PfxTransform3 transformAB; PfxMatrix3 matrixAB; PfxVector3 offsetAB; // Bローカル→Aローカルへの変換 transformAB = orthoInverse(transformA) * transformB; matrixAB = transformAB.getUpper3x3(); offsetAB = transformAB.getTranslation(); // ----------------------------------------------------- // LargeTriMeshに含まれるTriMeshのAABBと凸体のAABBを判定し、 // 交差するものを個別に衝突判定する。※LargeMesh座標系 PfxVector3 shapeHalf(0.0f); PfxVector3 shapeCenter = offsetAB; switch(shapeB.getType()) { case kPfxShapeSphere: shapeHalf = PfxVector3(shapeB.getSphere().m_radius); break; case kPfxShapeCapsule: { PfxCapsule capsule = shapeB.getCapsule(); shapeHalf = absPerElem(matrixAB) * PfxVector3(capsule.m_halfLen+capsule.m_radius,capsule.m_radius,capsule.m_radius); } break; case kPfxShapeCylinder: { PfxCylinder cylinder = shapeB.getCylinder(); shapeHalf = absPerElem(matrixAB) * PfxVector3(cylinder.m_halfLen,cylinder.m_radius,cylinder.m_radius); } break; case kPfxShapeBox: shapeHalf = absPerElem(matrixAB) * shapeB.getBox().m_half; break; case kPfxShapeConvexMesh: shapeHalf = absPerElem(matrixAB) * shapeB.getConvexMesh()->m_half; break; default: break; } // ----------------------------------------------------- // アイランドとの衝突判定 PfxVecInt3 aabbMinL,aabbMaxL; lmeshA->getLocalPosition((shapeCenter-shapeHalf),(shapeCenter+shapeHalf),aabbMinL,aabbMaxL); PfxUInt32 numIslands = lmeshA->m_numIslands; { for(PfxUInt32 i=0;i<numIslands;i++) { // AABBチェック PfxAabb16 aabbB = lmeshA->m_aabbList[i]; if(aabbMaxL.getX() < pfxGetXMin(aabbB) || aabbMinL.getX() > pfxGetXMax(aabbB)) continue; if(aabbMaxL.getY() < pfxGetYMin(aabbB) || aabbMinL.getY() > pfxGetYMax(aabbB)) continue; if(aabbMaxL.getZ() < pfxGetZMin(aabbB) || aabbMinL.getZ() > pfxGetZMax(aabbB)) continue; PfxTriMesh *island = &lmeshA->m_islands[i]; // 衝突判定 PfxContactCache localContacts; switch(shapeB.getType()) { case kPfxShapeSphere: pfxContactTriMeshSphere(localContacts,island,transformA,shapeB.getSphere(),transformB,distanceThreshold); break; case kPfxShapeCapsule: pfxContactTriMeshCapsule(localContacts,island,transformA,shapeB.getCapsule(),transformB,distanceThreshold); break; case kPfxShapeBox: pfxContactTriMeshBox(localContacts,island,transformA,shapeB.getBox(),transformB,distanceThreshold); break; case kPfxShapeCylinder: pfxContactTriMeshCylinder(localContacts,island,transformA,shapeB.getCylinder(),transformB,distanceThreshold); break; case kPfxShapeConvexMesh: pfxContactTriMeshConvex(localContacts,island,transformA,*shapeB.getConvexMesh(),transformB,distanceThreshold); break; default: break; } // 衝突点を追加 for(int j=0;j<localContacts.getNumContacts();j++) { PfxSubData subData = localContacts.getSubData(j); subData.setIslandId(i); contacts.addContactPoint( localContacts.getDistance(j), localContacts.getNormal(j), localContacts.getLocalPointA(j), localContacts.getLocalPointB(j), subData); } } } return contacts.getNumContacts(); }
PfxBool pfxIntersectRayCapsule(const PfxRayInput &ray,PfxRayOutput &out,const PfxCapsule &capsule,const PfxTransform3 &transform) { // レイをCapsuleのローカル座標へ変換 PfxTransform3 transformCapsule = orthoInverse(transform); PfxVector3 startPosL = transformCapsule.getUpper3x3() * ray.m_startPosition + transformCapsule.getTranslation(); PfxVector3 rayDirL = transformCapsule.getUpper3x3() * ray.m_direction; PfxFloat radSqr = capsule.m_radius * capsule.m_radius; // 始点がカプセルの内側にあるか判定 { PfxFloat h = fabsf(startPosL[0]); if(h > capsule.m_halfLen) h = capsule.m_halfLen; PfxVector3 Px(out.m_variable,0,0); PfxFloat sqrLen = lengthSqr(startPosL-Px); if(sqrLen <= radSqr) return false; } // カプセルの胴体との交差判定 do { PfxVector3 P(startPosL); PfxVector3 D(rayDirL); P[0] = 0.0f; D[0] = 0.0f; PfxFloat a = dot(D,D); PfxFloat b = dot(P,D); PfxFloat c = dot(P,P) - radSqr; PfxFloat d = b * b - a * c; if(d < 0.0f || fabs(a) < 0.00001f) return false; PfxFloat tt = ( -b - sqrtf(d) ) / a; if(tt < 0.0f) break; else if(tt > 1.0f) return false; if(tt < out.m_variable) { PfxVector3 cp = startPosL + tt * rayDirL; if(fabsf(cp[0]) <= capsule.m_halfLen) { out.m_contactFlag = true; out.m_variable = tt; out.m_contactPoint = PfxVector3(transform * PfxPoint3(cp)); out.m_contactNormal = transform.getUpper3x3() * normalize(cp); out.m_subData.m_type = PfxSubData::NONE; return true; } } } while(0); // カプセルの両端にある球体との交差判定 PfxFloat a = dot(rayDirL,rayDirL); if(fabs(a) < 0.00001f) return false; do { PfxVector3 center(capsule.m_halfLen,0.0f,0.0f); PfxVector3 v = startPosL - center; PfxFloat b = dot(v,rayDirL); PfxFloat c = dot(v,v) - radSqr; PfxFloat d = b * b - a * c; if(d < 0.0f) break; PfxFloat tt = ( -b - sqrtf(d) ) / a; if(tt < 0.0f || tt > 1.0f) break; if(tt < out.m_variable) { PfxVector3 cp = startPosL + tt * rayDirL; out.m_contactFlag = true; out.m_variable = tt; out.m_contactPoint = ray.m_startPosition + tt * ray.m_direction; out.m_contactNormal = transform.getUpper3x3() * normalize(cp-center); out.m_subData.m_type = PfxSubData::NONE; return true; } } while(0); { PfxVector3 center(-capsule.m_halfLen,0.0f,0.0f); PfxVector3 v = startPosL - center; PfxFloat b = dot(v,rayDirL); PfxFloat c = dot(v,v) - radSqr; PfxFloat d = b * b - a * c; if(d < 0.0f) return false; PfxFloat tt = ( -b - sqrtf(d) ) / a; if(tt < 0.0f || tt > 1.0f) return false; if(tt < out.m_variable) { PfxVector3 cp = startPosL + out.m_variable * rayDirL; out.m_contactFlag = true; out.m_variable = tt; out.m_contactPoint = ray.m_startPosition + tt * ray.m_direction; out.m_contactNormal = transform.getUpper3x3() * normalize(cp-center); out.m_subData.m_type = PfxSubData::NONE; return true; } } return false; }
PfxBool pfxIntersectRayCylinder(const PfxRayInput &ray,PfxRayOutput &out,const PfxCylinder &cylinder,const PfxTransform3 &transform) { // レイを円柱のローカル座標へ変換 PfxTransform3 transformCapsule = orthoInverse(transform); PfxVector3 startPosL = transformCapsule.getUpper3x3() * ray.m_startPosition + transformCapsule.getTranslation(); PfxVector3 rayDirL = transformCapsule.getUpper3x3() * ray.m_direction; PfxFloat radSqr = cylinder.m_radius * cylinder.m_radius; // 始点が円柱の内側にあるか判定 { PfxFloat h = startPosL[0]; if(-cylinder.m_halfLen <= h && h <= cylinder.m_halfLen) { PfxVector3 Px(h,0,0); PfxFloat sqrLen = lengthSqr(startPosL-Px); if(sqrLen <= radSqr) return false; } } // 円柱の胴体との交差判定 do { PfxVector3 P(startPosL); PfxVector3 D(rayDirL); P[0] = 0.0f; D[0] = 0.0f; PfxFloat a = dot(D,D); PfxFloat b = dot(P,D); PfxFloat c = dot(P,P) - radSqr; PfxFloat d = b * b - a * c; if(d < 0.0f) return false; // レイは逸れている if(pfxAbsf(a) < 0.00001f) break; // レイがX軸に平行 PfxFloat tt = ( -b - sqrtf(d) ) / a; if(tt < 0.0f || tt > 1.0f) break; if(tt < out.m_variable) { PfxVector3 cp = startPosL + tt * rayDirL; if(pfxAbsf(cp[0]) <= cylinder.m_halfLen) { out.m_contactFlag = true; out.m_variable = tt; out.m_contactPoint = PfxVector3(transform * PfxPoint3(cp)); out.m_contactNormal = transform.getUpper3x3() * normalize(cp); out.m_subData.m_type = PfxSubData::NONE; return true; } } } while(0); // 円柱の両端にある平面との交差判定 { if(pfxAbsf(rayDirL[0]) < 0.00001f) return false; PfxFloat t1 = ( cylinder.m_halfLen - startPosL[0] ) / rayDirL[0]; PfxFloat t2 = ( - cylinder.m_halfLen - startPosL[0] ) / rayDirL[0]; PfxFloat tt = SCE_PFX_MIN(t1,t2); if(tt < 0.0f || tt > 1.0f) return false; PfxVector3 p = startPosL + tt * rayDirL; p[0] = 0.0f; if(lengthSqr(p) < radSqr && tt < out.m_variable) { PfxVector3 cp = startPosL + tt * rayDirL; out.m_contactFlag = true; out.m_variable = tt; out.m_contactPoint = ray.m_startPosition + tt * ray.m_direction; out.m_contactNormal = transform.getUpper3x3() * ((cp[0]>0.0f)?PfxVector3(1.0,0.0,0.0):PfxVector3(-1.0,0.0,0.0)); out.m_subData.m_type = PfxSubData::NONE; return true; } } return false; }
PfxFloat pfxContactBoxCapsule( PfxVector3 &normal,PfxPoint3 &pointA,PfxPoint3 &pointB, void *shapeA,const PfxTransform3 &transformA, void *shapeB,const PfxTransform3 &transformB, PfxFloat distanceThreshold) { PfxBox boxA = *((PfxBox*)shapeA); PfxCapsule capsuleB = *((PfxCapsule*)shapeB); PfxVector3 ident[3] = { PfxVector3(1.0,0.0,0.0), PfxVector3(0.0,1.0,0.0), PfxVector3(0.0,0.0,1.0), }; // get capsule position and direction in box's coordinate system PfxMatrix3 matrixA = transformA.getUpper3x3(); PfxMatrix3 matrixAinv = transpose(matrixA); PfxVector3 directionB = transformB.getUpper3x3().getCol0(); PfxVector3 translationB = transformB.getTranslation(); PfxVector3 capsDirection = matrixAinv * directionB; PfxVector3 absCapsDirection = absPerElem(capsDirection); PfxVector3 offsetAB = matrixAinv * (translationB - transformA.getTranslation()); // find separating axis with largest gap between projections BoxCapsSepAxisType axisType; PfxVector3 axisA; PfxFloat maxGap; int faceDimA = 0, edgeDimA = 0; // face axes // can compute all the gaps at once with VU0 PfxVector3 gapsA = absPerElem(offsetAB) - boxA.m_half - absCapsDirection * capsuleB.m_halfLen; AaxisTest( 0, X, true ); AaxisTest( 1, Y, false ); AaxisTest( 2, Z, false ); // cross product axes // compute gaps on all cross product axes using some VU0 math. suppose there's a tradeoff // between doing this with SIMD all at once or without SIMD in each cross product test, since // some test might exit early. PfxVector3 lsqrs, projOffset, projAhalf; PfxMatrix3 crossProdMat = crossMatrix(capsDirection) * PfxMatrix3::identity(); PfxMatrix3 crossProdMatT = crossMatrix(-capsDirection) * PfxMatrix3::identity(); lsqrs = mulPerElem( crossProdMatT.getCol0(), crossProdMatT.getCol0() ) + mulPerElem( crossProdMatT.getCol1(), crossProdMatT.getCol1() ) + mulPerElem( crossProdMatT.getCol2(), crossProdMatT.getCol2() ); projOffset = crossProdMatT * offsetAB; projAhalf = absPerElem(crossProdMatT) * boxA.m_half; PfxVector3 gapsAxB = absPerElem(projOffset) - projAhalf; CrossAxisTest( 0, X ); CrossAxisTest( 1, Y ); CrossAxisTest( 2, Z ); // make axis point from box center towards capsule center. if ( dot(axisA,offsetAB) < 0.0f ) axisA = -axisA; // find the face on box whose normal best matches the separating axis. will use the entire // face only in degenerate cases. // // to make things simpler later, change the coordinate system so that the face normal is the z // direction. if an edge cross product axis was chosen above, also align the box edge to the y // axis. this saves the later tests from having to know which face was chosen. changing the // coordinate system involves permuting vector elements, so construct a permutation matrix. // I believe this is a faster way to permute a bunch of vectors than using arrays. int dimA[3]; if ( axisType == CROSS_AXIS ) { PfxVector3 absAxisA = PfxVector3(absPerElem(axisA)); dimA[1] = edgeDimA; if ( edgeDimA == 0 ) { if ( absAxisA[1] > absAxisA[2] ) { dimA[0] = 2; dimA[2] = 1; } else { dimA[0] = 1; dimA[2] = 2; } } else if ( edgeDimA == 1 ) { if ( absAxisA[2] > absAxisA[0] ) { dimA[0] = 0; dimA[2] = 2; } else { dimA[0] = 2; dimA[2] = 0; } } else { if ( absAxisA[0] > absAxisA[1] ) { dimA[0] = 1; dimA[2] = 0; } else { dimA[0] = 0; dimA[2] = 1; } } } else { dimA[2] = faceDimA; dimA[0] = (faceDimA+1)%3; dimA[1] = (faceDimA+2)%3; } PfxMatrix3 aperm_col; aperm_col.setCol0(ident[dimA[0]]); aperm_col.setCol1(ident[dimA[1]]); aperm_col.setCol2(ident[dimA[2]]); PfxMatrix3 aperm_row = transpose(aperm_col); // permute vectors to be in face coordinate system. PfxVector3 offsetAB_perm = aperm_row * offsetAB; PfxVector3 halfA_perm = aperm_row * boxA.m_half; PfxVector3 signsA_perm = copySignPerElem(PfxVector3(1.0f), aperm_row * axisA); PfxVector3 scalesA_perm = mulPerElem( signsA_perm, halfA_perm ); PfxVector3 capsDirection_perm = aperm_row * capsDirection; PfxFloat signB = (-dot(capsDirection,axisA) > 0.0f)? 1.0f : -1.0f; PfxFloat scaleB = signB * capsuleB.m_halfLen; // compute the vector between the center of the box face and the capsule center offsetAB_perm.setZ( offsetAB_perm.getZ() - scalesA_perm.getZ() ); // if box and capsule overlap, this will separate them for finding points of penetration. if ( maxGap < 0.0f ) { offsetAB_perm -= aperm_row * axisA * maxGap * 1.01f; } // for each vertex/face or edge/edge pair of box face and line segment, find the closest // points. // // these points each have an associated feature (vertex, edge, or face). if each // point is in the external Voronoi region of the other's feature, they are the // closest points of the objects, and the algorithm can exit. // // the feature pairs are arranged so that in the general case, the first test will // succeed. degenerate cases (line segment parallel to face) may require up to all tests // in the worst case. // // if for some reason no case passes the Voronoi test, the features with the minimum // distance are returned. PfxVector3 closestPtsVec_perm; PfxPoint3 localPointA_perm; PfxFloat minDistSqr; PfxFloat segmentParamB; PfxBool done; localPointA_perm.setZ( scalesA_perm.getZ() ); scalesA_perm.setZ(0.0f); PfxVector3 hA_perm( halfA_perm ); int otherFaceDimA; if ( axisType == CROSS_AXIS ) { EdgeEdgeTests( done, minDistSqr, closestPtsVec_perm, localPointA_perm, segmentParamB, otherFaceDimA, hA_perm, capsuleB.m_halfLen, offsetAB_perm, capsDirection_perm, signsA_perm, scalesA_perm, true ); if ( !done ) { VertexBFaceATests( done, minDistSqr, closestPtsVec_perm, localPointA_perm, segmentParamB, hA_perm, offsetAB_perm, capsDirection_perm, signB, scaleB, false ); } } else { VertexBFaceATests( done, minDistSqr, closestPtsVec_perm, localPointA_perm, segmentParamB, hA_perm, offsetAB_perm, capsDirection_perm, signB, scaleB, true ); if ( !done ) { EdgeEdgeTests( done, minDistSqr, closestPtsVec_perm, localPointA_perm, segmentParamB, otherFaceDimA, hA_perm, capsuleB.m_halfLen, offsetAB_perm, capsDirection_perm, signsA_perm, scalesA_perm, false ); } } // compute normal PfxBool centerInside = ( signsA_perm.getZ() * closestPtsVec_perm.getZ() < 0.0f ); if ( centerInside || ( minDistSqr < lenSqrTol ) ) { normal = matrixA * axisA; } else { PfxVector3 closestPtsVec = aperm_col * closestPtsVec_perm; normal = matrixA * ( closestPtsVec * (1.0f/sqrtf( minDistSqr )) ); } // compute box point pointA = PfxPoint3( aperm_col * PfxVector3( localPointA_perm ) ); // compute capsule point pointB = PfxPoint3( transpose(transformB.getUpper3x3()) * ( directionB * segmentParamB - normal * capsuleB.m_radius ) ); if ( centerInside ) { return (-sqrtf( minDistSqr ) - capsuleB.m_radius); } else { return (sqrtf( minDistSqr ) - capsuleB.m_radius); } }