virtual int registerGraphicsShape(const float* vertices, int numvertices, const int* indices, int numIndices,int primitiveType, int textureId)
{
int shapeIndex = m_swRenderObjects.size();
TinyRenderObjectData* swObj = new TinyRenderObjectData(m_rgbColorBuffer,m_depthBuffer);
float rgbaColor[4] = {1,1,1,1};
//if (textureId>=0)
//{
// swObj->registerMeshShape(vertices,numvertices,indices,numIndices,rgbaColor);
//} else
{
swObj->registerMeshShape(vertices,numvertices,indices,numIndices,rgbaColor);
}
//swObj->createCube(1,1,1);//MeshShape(vertices,numvertices,indices,numIndices);
m_swRenderObjects.insert(shapeIndex,swObj);
return shapeIndex;
}
BasicTexture* findTexture(const char* fileName)
{
BasicTexture** result = m_textures.find(fileName);
if (result)
return *result;
return 0;
}
virtual ~TinyRendererGUIHelper()
{
for (int i=0;i<m_swRenderObjects.size();i++)
{
TinyRenderObjectData** d = m_swRenderObjects[i];
if (d && *d)
{
delete *d;
}
}
}
virtual int registerTexture(const unsigned char* texels, int width, int height)
{
//do we need to make a copy?
int textureId = m_textures.size();
TinyRendererTexture t;
t.m_texels = texels;
t.m_width = width;
t.m_height = height;
this->m_textures.insert(textureId,t);
return textureId;
}
virtual void createCollisionObjectGraphicsObject(btCollisionObject* obj, const btVector3& color)
{
OpenGLGuiHelper::createCollisionObjectGraphicsObject(obj, color);
int colIndex = obj->getUserIndex();
int shapeIndex = obj->getCollisionShape()->getUserIndex();
if (colIndex >= 0 && shapeIndex >= 0)
{
m_swInstances.insert(colIndex, shapeIndex);
}
}
virtual ~SW_And_OpenGLGuiHelper()
{
for (int i = 0; i < m_swRenderObjects.size(); i++)
{
TinyRenderObjectData** d = m_swRenderObjects[i];
if (d && *d)
{
delete *d;
}
}
}
virtual int registerGraphicsShape(const float* vertices, int numvertices, const int* indices, int numIndices, int primitiveType, int textureId)
{
int shapeIndex = OpenGLGuiHelper::registerGraphicsShape(vertices, numvertices, indices, numIndices, primitiveType, textureId);
if (shapeIndex >= 0)
{
TinyRenderObjectData* swObj = new TinyRenderObjectData(m_rgbColorBuffer, m_depthBuffer);
float rgbaColor[4] = {1, 1, 1, 1};
swObj->registerMeshShape(vertices, numvertices, indices, numIndices, rgbaColor);
//swObj->createCube(1,1,1);//MeshShape(vertices,numvertices,indices,numIndices);
m_swRenderObjects.insert(shapeIndex, swObj);
}
return shapeIndex;
}
virtual void createCollisionObjectGraphicsObject(btCollisionObject* obj,const btVector3& color)
{
if (obj->getUserIndex()<0)
{
int colIndex = m_colObjUniqueIndex++;
obj->setUserIndex(colIndex);
int shapeIndex = obj->getCollisionShape()->getUserIndex();
if (colIndex>=0 && shapeIndex>=0)
{
m_swInstances.insert(colIndex,shapeIndex);
}
}
}
virtual int registerGraphicsInstance(int shapeIndex, const float* position, const float* quaternion, const float* color, const float* scaling)
{
int colIndex = m_colObjUniqueIndex++;
if (colIndex>=0 && shapeIndex>=0)
{
TinyRenderObjectData** dPtr = m_swRenderObjects[shapeIndex];
if (dPtr && *dPtr)
{
TinyRenderObjectData* d= *dPtr;
d->m_localScaling.setValue(scaling[0],scaling[1],scaling[2]);
m_swInstances.insert(colIndex,shapeIndex);
}
}
return colIndex;
}
void readLibraryGeometries(TiXmlDocument& doc, btAlignedObjectArray<GLInstanceGraphicsShape>& visualShapes, btHashMap<btHashString,int>& name2Shape, float extraScaling)
{
btHashMap<btHashString,TiXmlElement* > allSources;
btHashMap<btHashString,VertexSource> vertexSources;
for(TiXmlElement* geometry = doc.RootElement()->FirstChildElement("library_geometries")->FirstChildElement("geometry");
geometry != NULL; geometry = geometry->NextSiblingElement("geometry"))
{
btAlignedObjectArray<btVector3> vertexPositions;
btAlignedObjectArray<btVector3> vertexNormals;
btAlignedObjectArray<int> indices;
const char* geometryName = geometry->Attribute("id");
for (TiXmlElement* mesh = geometry->FirstChildElement("mesh");(mesh != NULL); mesh = mesh->NextSiblingElement("mesh"))
{
TiXmlElement* vertices2 = mesh->FirstChildElement("vertices");
for (TiXmlElement* source = mesh->FirstChildElement("source");source != NULL;source = source->NextSiblingElement("source"))
{
const char* srcId= source->Attribute("id");
// printf("source id=%s\n",srcId);
allSources.insert(srcId,source);
}
const char* vertexId = vertices2->Attribute("id");
//printf("vertices id=%s\n",vertexId);
VertexSource vs;
for(TiXmlElement* input = vertices2->FirstChildElement("input");input != NULL;input = input->NextSiblingElement("input"))
{
const char* sem = input->Attribute("semantic");
std::string semName(sem);
// printf("sem=%s\n",sem);
const char* src = input->Attribute("source");
// printf("src=%s\n",src);
const char* srcIdRef = input->Attribute("source");
std::string source_name;
source_name = std::string(srcIdRef);
source_name = source_name.erase(0, 1);
if (semName=="POSITION")
{
vs.m_positionArrayId = source_name;
}
if (semName=="NORMAL")
{
vs.m_normalArrayId = source_name;
}
}
vertexSources.insert(vertexId,vs);
for (TiXmlElement* primitive = mesh->FirstChildElement("triangles"); primitive; primitive = primitive->NextSiblingElement("triangles"))
{
std::string positionSourceName;
std::string normalSourceName;
int primitiveCount;
primitive->QueryIntAttribute("count", &primitiveCount);
bool positionAndNormalInVertex=false;
int indexStride=1;
int posOffset = 0;
int normalOffset = 0;
int numIndices = 0;
{
for (TiXmlElement* input = primitive->FirstChildElement("input");input != NULL;input = input->NextSiblingElement("input"))
{
const char* sem = input->Attribute("semantic");
std::string semName(sem);
int offset = atoi(input->Attribute("offset"));
if ((offset+1)>indexStride)
indexStride=offset+1;
//printf("sem=%s\n",sem);
const char* src = input->Attribute("source");
//printf("src=%s\n",src);
const char* srcIdRef = input->Attribute("source");
std::string source_name;
source_name = std::string(srcIdRef);
source_name = source_name.erase(0, 1);
if (semName=="VERTEX")
{
//now we have POSITION and possibly NORMAL too, using same index array (<p>)
VertexSource* vs = vertexSources[source_name.c_str()];
if (vs->m_positionArrayId.length())
{
positionSourceName = vs->m_positionArrayId;
posOffset = offset;
}
if (vs->m_normalArrayId.length())
{
normalSourceName = vs->m_normalArrayId;
normalOffset = offset;
positionAndNormalInVertex = true;
}
}
if (semName=="NORMAL")
{
btAssert(normalSourceName.length()==0);
normalSourceName = source_name;
normalOffset = offset;
positionAndNormalInVertex = false;
}
}
numIndices = primitiveCount * 3;
}
btAlignedObjectArray<float> positionFloatArray;
int posStride=1;
TiXmlElement** sourcePtr = allSources[positionSourceName.c_str()];
if (sourcePtr)
{
readFloatArray(*sourcePtr,positionFloatArray, posStride);
}
btAlignedObjectArray<float> normalFloatArray;
int normalStride=1;
sourcePtr = allSources[normalSourceName.c_str()];
if (sourcePtr)
{
readFloatArray(*sourcePtr,normalFloatArray,normalStride);
}
btAlignedObjectArray<int> curIndices;
curIndices.reserve(numIndices*indexStride);
TokenIntArray adder(curIndices);
tokenize(primitive->FirstChildElement("p")->GetText(),adder);
assert(curIndices.size() == numIndices*indexStride);
int indexOffset = vertexPositions.size();
for(int index=0; index<numIndices; index++)
{
int posIndex = curIndices[index*indexStride+posOffset];
int normalIndex = curIndices[index*indexStride+normalOffset];
vertexPositions.push_back(btVector3(extraScaling*positionFloatArray[posIndex*3+0],
extraScaling*positionFloatArray[posIndex*3+1],
extraScaling*positionFloatArray[posIndex*3+2]));
if (normalFloatArray.size() && (normalFloatArray.size()>normalIndex))
{
vertexNormals.push_back(btVector3(normalFloatArray[normalIndex*3+0],
normalFloatArray[normalIndex*3+1],
normalFloatArray[normalIndex*3+2]));
} else
{
//add a dummy normal of length zero, so it is easy to detect that it is an invalid normal
vertexNormals.push_back(btVector3(0,0,0));
}
}
int curNumIndices = indices.size();
indices.resize(curNumIndices+numIndices);
for(int index=0; index<numIndices; index++)
{
indices[curNumIndices+index] = index+indexOffset;
}
}//if(primitive != NULL)
}//for each mesh
int shapeIndex = visualShapes.size();
GLInstanceGraphicsShape& visualShape = visualShapes.expand();
{
visualShape.m_vertices = new b3AlignedObjectArray<GLInstanceVertex>;
visualShape.m_indices = new b3AlignedObjectArray<int>;
int indexBase = 0;
btAssert(vertexNormals.size()==vertexPositions.size());
for (int v=0;v<vertexPositions.size();v++)
{
GLInstanceVertex vtx;
vtx.xyzw[0] = vertexPositions[v].x();
vtx.xyzw[1] = vertexPositions[v].y();
vtx.xyzw[2] = vertexPositions[v].z();
vtx.xyzw[3] = 1.f;
vtx.normal[0] = vertexNormals[v].x();
vtx.normal[1] = vertexNormals[v].y();
vtx.normal[2] = vertexNormals[v].z();
vtx.uv[0] = 0.5f;
vtx.uv[1] = 0.5f;
visualShape.m_vertices->push_back(vtx);
}
for (int index=0;index<indices.size();index++)
{
visualShape.m_indices->push_back(indices[index]+indexBase);
}
printf(" index_count =%dand vertexPositions.size=%d\n",indices.size(), vertexPositions.size());
indexBase=visualShape.m_vertices->size();
visualShape.m_numIndices = visualShape.m_indices->size();
visualShape.m_numvertices = visualShape.m_vertices->size();
}
printf("geometry name=%s\n",geometryName);
name2Shape.insert(geometryName,shapeIndex);
}//for each geometry
}
virtual bool convertAllObjects( bParse::btBulletFile* bulletFile2)
{
bool result = btBulletWorldImporter::convertAllObjects(bulletFile2);
int i;
//now the soft bodies
for (i=0;i<bulletFile2->m_softBodies.size();i++)
{
if (bulletFile2->getFlags() & bParse::FD_DOUBLE_PRECISION)
{
btAssert(0); //not yet
//btSoftBodyFloatData* softBodyData = (btSoftBodyFloatData*)bulletFile2->m_softBodies[i];
} else
{
btSoftBodyFloatData* softBodyData = (btSoftBodyFloatData*)bulletFile2->m_softBodies[i];
int i;
int numNodes = softBodyData->m_numNodes;
btSoftBody* psb=new btSoftBody(&m_softRigidWorld->getWorldInfo());
m_softBodyMap.insert(softBodyData,psb);
//materials
for (i=0;i<softBodyData->m_numMaterials;i++)
{
SoftBodyMaterialData* matData = softBodyData->m_materials[i];
btSoftBody::Material** matPtr = m_materialMap.find(matData);
btSoftBody::Material* mat = 0;
if (matPtr&& *matPtr)
{
mat = *matPtr;
} else
{
mat = psb->appendMaterial();
mat->m_flags = matData->m_flags;
mat->m_kAST = matData->m_angularStiffness;
mat->m_kLST = matData->m_linearStiffness;
mat->m_kVST = matData->m_volumeStiffness;
m_materialMap.insert(matData,mat);
}
}
for (i=0;i<numNodes;i++)
{
SoftBodyNodeData& nodeData = softBodyData->m_nodes[i];
btVector3 position;
position.deSerializeFloat(nodeData.m_position);
btScalar mass = nodeData.m_inverseMass? 1./nodeData.m_inverseMass : 0.f;
psb->appendNode(position,mass);
btSoftBody::Node* node = &psb->m_nodes[psb->m_nodes.size()-1];
node->m_area = nodeData.m_area;
node->m_battach = nodeData.m_attach;
node->m_f.deSerializeFloat(nodeData.m_accumulatedForce);
node->m_im = nodeData.m_inverseMass;
btSoftBody::Material** matPtr = m_materialMap.find(nodeData.m_material);
if (matPtr && *matPtr)
{
node->m_material = *matPtr;
} else
{
printf("no mat?\n");
}
node->m_n.deSerializeFloat(nodeData.m_normal);
node->m_q = node->m_x;
node->m_v.deSerializeFloat(nodeData.m_velocity);
}
for (i=0;i<softBodyData->m_numLinks;i++)
{
SoftBodyLinkData& linkData = softBodyData->m_links[i];
btSoftBody::Material** matPtr = m_materialMap.find(linkData.m_material);
if (matPtr && *matPtr)
{
psb->appendLink(linkData.m_nodeIndices[0],linkData.m_nodeIndices[1],*matPtr);
} else
{
psb->appendLink(linkData.m_nodeIndices[0],linkData.m_nodeIndices[1]);
}
btSoftBody::Link* link = &psb->m_links[psb->m_links.size()-1];
link->m_bbending = linkData.m_bbending;
link->m_rl = linkData.m_restLength;
}
for (i=0;i<softBodyData->m_numFaces;i++)
{
SoftBodyFaceData& faceData = softBodyData->m_faces[i];
btSoftBody::Material** matPtr = m_materialMap.find(faceData.m_material);
if (matPtr && *matPtr)
{
psb->appendFace(faceData.m_nodeIndices[0],faceData.m_nodeIndices[1],faceData.m_nodeIndices[2],*matPtr);
} else
{
psb->appendFace(faceData.m_nodeIndices[0],faceData.m_nodeIndices[1],faceData.m_nodeIndices[2]);
}
btSoftBody::Face* face = &psb->m_faces[psb->m_faces.size()-1];
face->m_normal.deSerializeFloat(faceData.m_normal);
face->m_ra = faceData.m_restArea;
}
//anchors
for (i=0;i<softBodyData->m_numAnchors;i++)
{
btCollisionObject** colAptr = m_bodyMap.find(softBodyData->m_anchors[i].m_rigidBody);
if (colAptr && *colAptr)
{
btRigidBody* body = btRigidBody::upcast(*colAptr);
if (body)
{
bool disableCollision = false;
btVector3 localPivot;
localPivot.deSerializeFloat(softBodyData->m_anchors[i].m_localFrame);
psb->appendAnchor(softBodyData->m_anchors[i].m_nodeIndex,body,localPivot, disableCollision);
}
}
}
if (softBodyData->m_pose)
{
psb->m_pose.m_aqq.deSerializeFloat( softBodyData->m_pose->m_aqq);
psb->m_pose.m_bframe = (softBodyData->m_pose->m_bframe!=0);
psb->m_pose.m_bvolume = (softBodyData->m_pose->m_bvolume!=0);
psb->m_pose.m_com.deSerializeFloat(softBodyData->m_pose->m_com);
psb->m_pose.m_pos.resize(softBodyData->m_pose->m_numPositions);
for (i=0;i<softBodyData->m_pose->m_numPositions;i++)
{
psb->m_pose.m_pos[i].deSerializeFloat(softBodyData->m_pose->m_positions[i]);
}
psb->m_pose.m_rot.deSerializeFloat(softBodyData->m_pose->m_rot);
psb->m_pose.m_scl.deSerializeFloat(softBodyData->m_pose->m_scale);
psb->m_pose.m_wgh.resize(softBodyData->m_pose->m_numWeigts);
for (i=0;i<softBodyData->m_pose->m_numWeigts;i++)
{
psb->m_pose.m_wgh[i] = softBodyData->m_pose->m_weights[i];
}
psb->m_pose.m_volume = softBodyData->m_pose->m_restVolume;
}
#if 1
psb->m_cfg.piterations=softBodyData->m_config.m_positionIterations;
psb->m_cfg.diterations=softBodyData->m_config.m_driftIterations;
psb->m_cfg.citerations=softBodyData->m_config.m_clusterIterations;
psb->m_cfg.viterations=softBodyData->m_config.m_velocityIterations;
//psb->setTotalMass(0.1);
psb->m_cfg.aeromodel = (btSoftBody::eAeroModel::_)softBodyData->m_config.m_aeroModel;
psb->m_cfg.kLF = softBodyData->m_config.m_lift;
psb->m_cfg.kDG = softBodyData->m_config.m_drag;
psb->m_cfg.kMT = softBodyData->m_config.m_poseMatch;
psb->m_cfg.collisions = softBodyData->m_config.m_collisionFlags;
psb->m_cfg.kDF = 1.f;//softBodyData->m_config.m_dynamicFriction;
psb->m_cfg.kDP = softBodyData->m_config.m_damping;
psb->m_cfg.kPR = softBodyData->m_config.m_pressure;
psb->m_cfg.kVC = softBodyData->m_config.m_volume;
psb->m_cfg.kAHR = softBodyData->m_config.m_anchorHardness;
psb->m_cfg.kKHR = softBodyData->m_config.m_kineticContactHardness;
psb->m_cfg.kSHR = softBodyData->m_config.m_softContactHardness;
psb->m_cfg.kSRHR_CL = softBodyData->m_config.m_softRigidClusterHardness;
psb->m_cfg.kSKHR_CL = softBodyData->m_config.m_softKineticClusterHardness;
psb->m_cfg.kSSHR_CL = softBodyData->m_config.m_softSoftClusterHardness;
#endif
// pm->m_kLST = 1;
#if 1
//clusters
if (softBodyData->m_numClusters)
{
m_clusterBodyMap.insert(softBodyData->m_clusters,psb);
int j;
psb->m_clusters.resize(softBodyData->m_numClusters);
for (i=0;i<softBodyData->m_numClusters;i++)
{
psb->m_clusters[i] = new(btAlignedAlloc(sizeof(btSoftBody::Cluster),16)) btSoftBody::Cluster();
psb->m_clusters[i]->m_adamping = softBodyData->m_clusters[i].m_adamping;
psb->m_clusters[i]->m_av.deSerializeFloat(softBodyData->m_clusters[i].m_av);
psb->m_clusters[i]->m_clusterIndex = softBodyData->m_clusters[i].m_clusterIndex;
psb->m_clusters[i]->m_collide = (softBodyData->m_clusters[i].m_collide!=0);
psb->m_clusters[i]->m_com.deSerializeFloat(softBodyData->m_clusters[i].m_com);
psb->m_clusters[i]->m_containsAnchor = (softBodyData->m_clusters[i].m_containsAnchor!=0);
psb->m_clusters[i]->m_dimpulses[0].deSerializeFloat(softBodyData->m_clusters[i].m_dimpulses[0]);
psb->m_clusters[i]->m_dimpulses[1].deSerializeFloat(softBodyData->m_clusters[i].m_dimpulses[1]);
psb->m_clusters[i]->m_framerefs.resize(softBodyData->m_clusters[i].m_numFrameRefs);
for (j=0;j<softBodyData->m_clusters[i].m_numFrameRefs;j++)
{
psb->m_clusters[i]->m_framerefs[j].deSerializeFloat(softBodyData->m_clusters[i].m_framerefs[j]);
}
psb->m_clusters[i]->m_nodes.resize(softBodyData->m_clusters[i].m_numNodes);
for (j=0;j<softBodyData->m_clusters[i].m_numNodes;j++)
{
int nodeIndex = softBodyData->m_clusters[i].m_nodeIndices[j];
psb->m_clusters[i]->m_nodes[j] = &psb->m_nodes[nodeIndex];
}
psb->m_clusters[i]->m_masses.resize(softBodyData->m_clusters[i].m_numMasses);
for (j=0;j<softBodyData->m_clusters[i].m_numMasses;j++)
{
psb->m_clusters[i]->m_masses[j] = softBodyData->m_clusters[i].m_masses[j];
}
psb->m_clusters[i]->m_framexform.deSerializeFloat(softBodyData->m_clusters[i].m_framexform);
psb->m_clusters[i]->m_idmass = softBodyData->m_clusters[i].m_idmass;
psb->m_clusters[i]->m_imass = softBodyData->m_clusters[i].m_imass;
psb->m_clusters[i]->m_invwi.deSerializeFloat(softBodyData->m_clusters[i].m_invwi);
psb->m_clusters[i]->m_ldamping = softBodyData->m_clusters[i].m_ldamping;
psb->m_clusters[i]->m_locii.deSerializeFloat(softBodyData->m_clusters[i].m_locii);
psb->m_clusters[i]->m_lv.deSerializeFloat(softBodyData->m_clusters[i].m_lv);
psb->m_clusters[i]->m_matching = softBodyData->m_clusters[i].m_matching;
psb->m_clusters[i]->m_maxSelfCollisionImpulse = 0;//softBodyData->m_clusters[i].m_maxSelfCollisionImpulse;
psb->m_clusters[i]->m_ndamping = softBodyData->m_clusters[i].m_ndamping;
psb->m_clusters[i]->m_ndimpulses = softBodyData->m_clusters[i].m_ndimpulses;
psb->m_clusters[i]->m_nvimpulses = softBodyData->m_clusters[i].m_nvimpulses;
psb->m_clusters[i]->m_selfCollisionImpulseFactor = softBodyData->m_clusters[i].m_selfCollisionImpulseFactor;
psb->m_clusters[i]->m_vimpulses[0].deSerializeFloat(softBodyData->m_clusters[i].m_vimpulses[0]);
psb->m_clusters[i]->m_vimpulses[1].deSerializeFloat(softBodyData->m_clusters[i].m_vimpulses[1]);
}
//psb->initializeClusters();
//psb->updateClusters();
}
#else
psb->m_cfg.piterations = 2;
psb->m_cfg.collisions = btSoftBody::fCollision::CL_SS+ btSoftBody::fCollision::CL_RS;
//psb->setTotalMass(50,true);
//psb->generateClusters(64);
//psb->m_cfg.kDF=1;
psb->generateClusters(8);
#endif //
psb->updateConstants();
m_softRigidWorld->getWorldInfo().m_dispatcher = m_softRigidWorld->getDispatcher();
m_softRigidWorld->addSoftBody(psb);
}
}
//now the soft body joints
for (i=0;i<bulletFile2->m_softBodies.size();i++)
{
if (bulletFile2->getFlags() & bParse::FD_DOUBLE_PRECISION)
{
btAssert(0); //not yet
//btSoftBodyFloatData* softBodyData = (btSoftBodyFloatData*)bulletFile2->m_softBodies[i];
} else
{
btSoftBodyFloatData* softBodyData = (btSoftBodyFloatData*)bulletFile2->m_softBodies[i];
btSoftBody** sbp = m_softBodyMap.find(softBodyData);
if (sbp && *sbp)
{
btSoftBody* sb = *sbp;
for (int i=0;i<softBodyData->m_numJoints;i++)
{
btSoftBodyJointData* sbjoint = &softBodyData->m_joints[i];
btSoftBody::Body bdyB;
btSoftBody* sbB = 0;
btTransform transA;
transA.setIdentity();
transA = sb->m_clusters[0]->m_framexform;
btCollisionObject** colBptr = m_bodyMap.find(sbjoint->m_bodyB);
if (colBptr && *colBptr)
{
btRigidBody* rbB = btRigidBody::upcast(*colBptr);
if (rbB)
{
bdyB = rbB;
} else
{
bdyB = *colBptr;
}
}
btSoftBody** bodyBptr = m_clusterBodyMap.find(sbjoint->m_bodyB);
if (bodyBptr && *bodyBptr )
{
sbB = *bodyBptr;
bdyB = sbB->m_clusters[0];
}
if (sbjoint->m_jointType==btSoftBody::Joint::eType::Linear)
{
btSoftBody::LJoint::Specs specs;
specs.cfm = sbjoint->m_cfm;
specs.erp = sbjoint->m_erp;
specs.split = sbjoint->m_split;
btVector3 relA;
relA.deSerializeFloat(sbjoint->m_refs[0]);
specs.position = transA*relA;
sb->appendLinearJoint(specs,sb->m_clusters[0],bdyB);
}
if (sbjoint->m_jointType==btSoftBody::Joint::eType::Angular)
{
btSoftBody::AJoint::Specs specs;
specs.cfm = sbjoint->m_cfm;
specs.erp = sbjoint->m_erp;
specs.split = sbjoint->m_split;
btVector3 relA;
relA.deSerializeFloat(sbjoint->m_refs[0]);
specs.axis = transA.getBasis()*relA;
sb->appendAngularJoint(specs,sb->m_clusters[0],bdyB);
}
}
}
}
}
return result;
}
//after each object is converter, including collision object, create a graphics object (and bind them)
virtual void createGraphicsObject(_bObj* tmpObject, class btCollisionObject* bulletObject)
{
btRigidBody* body = btRigidBody::upcast(bulletObject);
btRenderMesh* mesh = 0;
if (tmpObject->data.mesh && tmpObject->data.mesh->vert_count && tmpObject->data.mesh->face_count)
{
if (tmpObject->data.mesh->vert_count> 16300)
{
printf("tmpObject->data.mesh->vert_count = %d\n",tmpObject->data.mesh->vert_count);
}
mesh = new btRenderMesh();
mesh->m_bulletObject = bulletObject;
btAlignedObjectArray<btVector3> originalVertices;
originalVertices.resize(tmpObject->data.mesh->vert_count);
for (int v=0;v<tmpObject->data.mesh->vert_count;v++)
{
float* vt3 = tmpObject->data.mesh->vert[v].xyz;
originalVertices[v].setValue( IRR_X_M*vt3[IRR_X],IRR_Y_M*vt3[IRR_Y],IRR_Z_M*vt3[IRR_Z]);
}
int numVertices = 0;
int numTriangles=0;
int currentIndex=0;
btTexVert* texVert = 0;
for (int t=0;t<tmpObject->data.mesh->face_count;t++)
{
int originalIndex = tmpObject->data.mesh->face[t].v[IRR_TRI_0_X];
mesh->m_indices.push_back(currentIndex);
texVert = &mesh->m_vertices.expand();
texVert->m_localxyz = originalVertices[originalIndex];
texVert->m_uv1[0] = tmpObject->data.mesh->face[t].uv[IRR_TRI_0_X][0];
texVert->m_uv1[1] = tmpObject->data.mesh->face[t].uv[IRR_TRI_0_X][1];
numVertices++;
currentIndex++;
originalIndex = tmpObject->data.mesh->face[t].v[IRR_TRI_0_Y];
mesh->m_indices.push_back(currentIndex);
texVert = &mesh->m_vertices.expand();
texVert->m_localxyz = originalVertices[originalIndex];
texVert->m_uv1[0] = tmpObject->data.mesh->face[t].uv[IRR_TRI_0_Y][0];
texVert->m_uv1[1] = tmpObject->data.mesh->face[t].uv[IRR_TRI_0_Y][1];
numVertices++;
currentIndex++;
originalIndex = tmpObject->data.mesh->face[t].v[IRR_TRI_0_Z];
mesh->m_indices.push_back(currentIndex);
texVert = &mesh->m_vertices.expand();
texVert->m_localxyz = originalVertices[originalIndex];
texVert->m_uv1[0] = tmpObject->data.mesh->face[t].uv[IRR_TRI_0_Z][0];
texVert->m_uv1[1] = tmpObject->data.mesh->face[t].uv[IRR_TRI_0_Z][1];
numVertices++;
currentIndex++;
numTriangles++;
if (tmpObject->data.mesh->face[t].v[3])
{
originalIndex = tmpObject->data.mesh->face[t].v[IRR_TRI_1_X];
mesh->m_indices.push_back(currentIndex);
texVert = &mesh->m_vertices.expand();
texVert->m_localxyz = originalVertices[originalIndex];
texVert->m_uv1[0] = tmpObject->data.mesh->face[t].uv[IRR_TRI_1_X][0];
texVert->m_uv1[1] = tmpObject->data.mesh->face[t].uv[IRR_TRI_1_X][1];
numVertices++;
currentIndex++;
originalIndex = tmpObject->data.mesh->face[t].v[IRR_TRI_1_Y];
mesh->m_indices.push_back(currentIndex);
texVert = &mesh->m_vertices.expand();
texVert->m_localxyz = originalVertices[originalIndex];
texVert->m_uv1[0] = tmpObject->data.mesh->face[t].uv[IRR_TRI_1_Y][0];
texVert->m_uv1[1] = tmpObject->data.mesh->face[t].uv[IRR_TRI_1_Y][1];
numVertices++;
currentIndex++;
originalIndex = tmpObject->data.mesh->face[t].v[IRR_TRI_1_Z];
mesh->m_indices.push_back(currentIndex);
texVert = &mesh->m_vertices.expand();
texVert->m_localxyz = originalVertices[originalIndex];
texVert->m_uv1[0] = tmpObject->data.mesh->face[t].uv[IRR_TRI_1_Z][0];
texVert->m_uv1[1] = tmpObject->data.mesh->face[t].uv[IRR_TRI_1_Z][1];
numVertices++;
numTriangles++;
currentIndex++;
}
}
if (numTriangles>0)
{
m_renderMeshes.push_back(mesh);
printf("numTris = %d\n",numTriangles);
//scene::ISceneNode* node = createMeshNode(mesh->m_vertices,numVertices,indices,numIndices,numTriangles,bulletObject,tmpObject);
//if (newMotionState && node)
// newMotionState->addIrrlichtNode(node);
}
}
if (tmpObject->data.mesh->face[0].m_image)
{
const char* fileName = tmpObject->data.mesh->face[0].m_image->m_imagePathName;
BasicTexture* texture0 = findTexture(fileName);
if (!texture0)
{
void* jpgData = tmpObject->data.mesh->face[0].m_image->m_packedImagePtr;
int jpgSize = tmpObject->data.mesh->face[0].m_image->m_sizePackedImage;
if (jpgSize)
{
texture0 = new BasicTexture((unsigned char*)jpgData,jpgSize);
printf("texture filename=%s\n",fileName);
texture0->loadTextureMemory(fileName);
m_textures.insert(fileName,texture0);
}
}
if (texture0 && mesh)
{
mesh->m_texture = texture0;
}
}
}
