void Mesh::GetNormals(FbxMesh* pMesh, MeshInfo& pMeshInfo) { FbxGeometryElementNormal* lNormalElement = pMesh->GetElementNormal(); if (lNormalElement) { if (lNormalElement->GetReferenceMode() == FbxGeometryElement::eDirect) { for (int lVertexIndex = 0; lVertexIndex < pMesh->GetLayer(0)->GetNormals()->GetDirectArray().GetCount(); lVertexIndex++) { int lNormalIndex = 0; lNormalIndex = lVertexIndex; pMeshInfo.normals.push_back(lNormalElement->GetDirectArray().GetAt(lNormalIndex)); } } if (lNormalElement->GetReferenceMode() == FbxGeometryElement::eIndexToDirect) { for (int lVertexIndex = 0; lVertexIndex < pMesh->GetLayer(0)->GetNormals()->GetIndexArray().GetCount(); lVertexIndex++) { int lNormalIndex = 0; lNormalIndex = lNormalElement->GetIndexArray().GetAt(lVertexIndex); pMeshInfo.normals.push_back(lNormalElement->GetDirectArray().GetAt(lNormalIndex)); } } } }
//------------------------------------------------------------------------------------------------------------------------------------------- void transferNormals(FbxMesh* fbxMesh, Mesh* mesh){ int numVertices = fbxMesh->GetControlPointsCount(); FbxGeometryElementNormal* normals = fbxMesh->GetElementNormal(0); mesh->InitEmptyNormals(numVertices); for (int i = 0; i < numVertices; i++){ FbxVector4 normal = normals->GetDirectArray().GetAt(i); mesh->Push_back(Mesh::MeshType::NORMAL, &Vector3s((double)normal[0], (double)normal[1], (double)normal[2])); } LOG_DEBUG << "Transfer normals successfully! "; }
reVec3 reFBXAsset::getNormal(FbxMesh* fmesh, int vi) { FbxVector4 normal; for(int l = 0; l < fmesh->GetElementNormalCount(); ++l) { FbxGeometryElementNormal* leNormal = fmesh->GetElementNormal(l); if(leNormal->GetMappingMode() == FbxGeometryElement::eByPolygonVertex) { switch (leNormal->GetReferenceMode()) { case FbxGeometryElement::eDirect: normal = leNormal->GetDirectArray().GetAt(vi); return reVec3(normal[0], normal[1], normal[2]); case FbxGeometryElement::eIndexToDirect: int id = leNormal->GetIndexArray().GetAt(vi); normal = leNormal->GetDirectArray().GetAt(id); return reVec3(normal[0], normal[1], normal[2]); } } } return reVec3(0,0,0); }
std::shared_ptr<Mesh> FbxUtil::CreateMesh(FbxMesh *fbxMesh) { Mesh::Ptr mesh = Mesh::Create(fbxMesh->GetName()); // read physical data. int polygonCount = fbxMesh->GetPolygonCount(); int indicesCount = polygonCount * 3; mesh->Positions.Data.reserve(indicesCount * 3); mesh->Indices.Data.reserve(indicesCount); if ((m_Options & Options::UV) && fbxMesh->GetElementUVCount() > 0) mesh->UVs.Data.reserve(indicesCount * 2); if ((m_Options & Options::NORMAL) && fbxMesh->GetElementNormalCount() > 0) mesh->Normals.Data.reserve(indicesCount * 3); if ((m_Options & Options::TANGENT) && fbxMesh->GetElementTangent() > 0) mesh->Tangents.Data.reserve(indicesCount * 3); int normalCounter = 0, uvCounter = 0, tangentCounter = 0; for (int i = 0; i < polygonCount; i++) { for (int j = 0; j < 3; j++) { int ctrPtrIndex = fbxMesh->GetPolygonVertex(i, j); auto position = fbxMesh->GetControlPointAt(ctrPtrIndex); mesh->Positions.Data.push_back((float)position.mData[0]); mesh->Positions.Data.push_back((float)position.mData[1]); mesh->Positions.Data.push_back((float)position.mData[2]); // uv if ((m_Options & Options::UV) && fbxMesh->GetElementUVCount() > 0) { int uvIndex = 0; FbxGeometryElementUV* vertexUV = fbxMesh->GetElementUV(); if (vertexUV->GetMappingMode() == FbxGeometryElement::eByControlPoint) { if (vertexUV->GetReferenceMode() == FbxGeometryElement::eDirect) uvIndex = ctrPtrIndex; else if (vertexUV->GetReferenceMode() == FbxGeometryElement::eIndexToDirect) uvIndex = vertexUV->GetIndexArray().GetAt(ctrPtrIndex); else ASSERT_MSG(false, "Error: Invalid Reference Mode!"); } else if (vertexUV->GetMappingMode() == FbxGeometryElement::eByPolygonVertex) { if (vertexUV->GetReferenceMode() == FbxGeometryElement::eDirect) uvIndex = uvCounter; else if (vertexUV->GetReferenceMode() == FbxGeometryElement::eIndexToDirect) uvIndex = vertexUV->GetIndexArray().GetAt(uvCounter); else ASSERT_MSG(false, "Error: Invalid Reference Mode!"); uvCounter++; } auto uv = vertexUV->GetDirectArray().GetAt(uvIndex); mesh->UVs.Data.push_back((float)uv.mData[0]); mesh->UVs.Data.push_back(1.0f - (float)uv.mData[1]); } // normal if ((m_Options & Options::NORMAL) && fbxMesh->GetElementNormalCount() > 0) { int normalIndex = 0; FbxGeometryElementNormal* vertexNormal = fbxMesh->GetElementNormal(); if (vertexNormal->GetMappingMode() == FbxGeometryElement::eByControlPoint) { if (vertexNormal->GetReferenceMode() == FbxGeometryElement::eDirect) normalIndex = ctrPtrIndex; else if (vertexNormal->GetReferenceMode() == FbxGeometryElement::eIndexToDirect) normalIndex = vertexNormal->GetIndexArray().GetAt(ctrPtrIndex); else ASSERT_MSG(false, "Error: Invalid Reference Mode!"); } else if (vertexNormal->GetMappingMode() == FbxGeometryElement::eByPolygonVertex) { if (vertexNormal->GetReferenceMode() == FbxGeometryElement::eDirect) normalIndex = normalCounter; else if (vertexNormal->GetReferenceMode() == FbxGeometryElement::eIndexToDirect) normalIndex = vertexNormal->GetIndexArray().GetAt(normalCounter); else ASSERT_MSG(false, "Error: Invalid Reference Mode!"); normalCounter++; } auto normal = vertexNormal->GetDirectArray().GetAt(normalIndex); mesh->Normals.Data.push_back((float)normal.mData[0]); mesh->Normals.Data.push_back((float)normal.mData[1]); mesh->Normals.Data.push_back((float)normal.mData[2]); } // tangent if ((m_Options & Options::TANGENT) && fbxMesh->GetElementNormalCount() > 0) { int tangentIndex = 0; FbxGeometryElementTangent* vertexTangent = fbxMesh->GetElementTangent(); if (vertexTangent->GetMappingMode() == FbxGeometryElement::eByControlPoint) { if (vertexTangent->GetReferenceMode() == FbxGeometryElement::eDirect) tangentIndex = ctrPtrIndex; else if (vertexTangent->GetReferenceMode() == FbxGeometryElement::eIndexToDirect) tangentIndex = vertexTangent->GetIndexArray().GetAt(ctrPtrIndex); else ASSERT_MSG(false, "Error: Invalid Reference Mode!"); } else if (vertexTangent->GetMappingMode() == FbxGeometryElement::eByPolygonVertex) { if (vertexTangent->GetReferenceMode() == FbxGeometryElement::eDirect) tangentIndex = tangentCounter; else if (vertexTangent->GetReferenceMode() == FbxGeometryElement::eIndexToDirect) tangentIndex = vertexTangent->GetIndexArray().GetAt(tangentCounter); else ASSERT_MSG(false, "Error: Invalid Reference Mode!"); tangentCounter++; } auto tangent = vertexTangent->GetDirectArray().GetAt(tangentIndex); mesh->Tangents.Data.push_back((float)tangent.mData[0]); mesh->Tangents.Data.push_back((float)tangent.mData[1]); mesh->Tangents.Data.push_back((float)tangent.mData[2]); } mesh->Indices.Data.push_back(i * 3 + j); } } LOGD << mesh->GetName() << " [vtx: " << mesh->Positions.Data.size() / 3 << " tris: " << mesh->Indices.Data.size() / 3 << "]"; if(m_Options & Options::OPTIMIZE_MESH) MeshUtil::Instance()->OptimizeMesh(mesh); mesh->CalculateAABB(); return mesh; }
void FbxParser::ReadNormal(FbxMesh* pMesh, int ctrlPointIndex , int vertexCounter , GS::double3& normal) { if(pMesh->GetElementNormalCount() < 1) { return; } FbxGeometryElementNormal* leNormal = pMesh->GetElementNormal( 0); switch(leNormal->GetMappingMode()) { case FbxGeometryElement::eByControlPoint: { switch(leNormal->GetReferenceMode()) { case FbxGeometryElement::eDirect: { normal.x = leNormal->GetDirectArray().GetAt(ctrlPointIndex)[0]; normal.y = leNormal->GetDirectArray().GetAt(ctrlPointIndex)[1]; normal.z = leNormal->GetDirectArray().GetAt(ctrlPointIndex)[2]; } break; case FbxGeometryElement::eIndexToDirect: { int id = leNormal->GetIndexArray().GetAt(ctrlPointIndex); normal.x = leNormal->GetDirectArray().GetAt(id)[0]; normal.y = leNormal->GetDirectArray().GetAt(id)[1]; normal.z = leNormal->GetDirectArray().GetAt(id)[2]; } break; default: break; } } break; case FbxGeometryElement::eByPolygonVertex: { switch(leNormal->GetReferenceMode()) { case FbxGeometryElement::eDirect: { normal.x = leNormal->GetDirectArray().GetAt(vertexCounter)[0]; normal.y = leNormal->GetDirectArray().GetAt(vertexCounter)[1]; normal.z = leNormal->GetDirectArray().GetAt(vertexCounter)[2]; } break; case FbxGeometryElement::eIndexToDirect: { int id = leNormal->GetIndexArray().GetAt(vertexCounter); normal.x = leNormal->GetDirectArray().GetAt(id)[0]; normal.y = leNormal->GetDirectArray().GetAt(id)[1]; normal.z = leNormal->GetDirectArray().GetAt(id)[2]; } break; default: break; } } break; } }
void FBXImporter::ReadNormals(FBXMeshData* fbxMeshData, int contorlPointIndex, int normalIndex) { FbxMesh* mesh = fbxMeshData->mMesh; vector<XMFLOAT3>& normals = fbxMeshData->mNormals; if (mesh->GetElementNormalCount() < 1) { return; } FbxGeometryElementNormal* normalElement = mesh->GetElementNormal(0); switch (normalElement->GetMappingMode()) { case FbxGeometryElement::eByControlPoint: switch (normalElement->GetReferenceMode()) { case FbxGeometryElement::eDirect: { FbxVector4 fbxNormal = normalElement->GetDirectArray().GetAt(contorlPointIndex); XMFLOAT3 normal; normal.x = static_cast<float>(fbxNormal[0]); normal.y = static_cast<float>(fbxNormal[1]); normal.z = static_cast<float>(fbxNormal[2]); normals.push_back(normal); } break; case FbxGeometryElement::eIndexToDirect: { int id = normalElement->GetIndexArray().GetAt(contorlPointIndex); FbxVector4 fbxNormal = normalElement->GetDirectArray().GetAt(id); XMFLOAT3 normal; normal.x = static_cast<float>(fbxNormal[0]); normal.y = static_cast<float>(fbxNormal[1]); normal.z = static_cast<float>(fbxNormal[2]); normals.push_back(normal); } default: break; } break; case FbxGeometryElement::eByPolygonVertex: switch (normalElement->GetReferenceMode()) { case FbxGeometryElement::eDirect: { FbxVector4 fbxNormal = normalElement->GetDirectArray().GetAt(normalIndex); XMFLOAT3 normal; normal.x = static_cast<float>(fbxNormal[0]); normal.y = static_cast<float>(fbxNormal[1]); normal.z = static_cast<float>(fbxNormal[2]); normals.push_back(normal); } break; case FbxGeometryElement::eIndexToDirect: { int id = normalElement->GetIndexArray().GetAt(normalIndex); FbxVector4 fbxNormal = normalElement->GetDirectArray().GetAt(id); XMFLOAT3 normal; normal.x = static_cast<float>(fbxNormal[0]); normal.y = static_cast<float>(fbxNormal[1]); normal.z = static_cast<float>(fbxNormal[2]); normals.push_back(normal); } default: break; } break; default: break; } }
//converts a FBX mesh to a CC mesh static ccMesh* FromFbxMesh(FbxMesh* fbxMesh, bool alwaysDisplayLoadDialog/*=true*/, bool* coordinatesShiftEnabled/*=0*/, CCVector3d* coordinatesShift/*=0*/) { if (!fbxMesh) return 0; int polyCount = fbxMesh->GetPolygonCount(); //fbxMesh->GetLayer( unsigned triCount = 0; unsigned polyVertCount = 0; //different from vertCount (vertices can be counted multiple times here!) //as we can't load all polygons (yet ;) we already look if we can load any! { unsigned skipped = 0; for (int i=0; i<polyCount; ++i) { int pSize = fbxMesh->GetPolygonSize(i); if (pSize == 3) { ++triCount; polyVertCount += 3; } else if (pSize == 4) { triCount += 2; polyVertCount += 4; } else { ++skipped; } } if (triCount == 0) { ccLog::Warning(QString("[FBX] No triangle or quad found in mesh '%1'! (polygons with more than 4 vertices are not supported for the moment)").arg(fbxMesh->GetName())); return 0; } else if (skipped != 0) { ccLog::Warning(QString("[FBX] Some polygons in mesh '%1' were ignored (%2): polygons with more than 4 vertices are not supported for the moment)").arg(fbxMesh->GetName()).arg(skipped)); return 0; } } int vertCount = fbxMesh->GetControlPointsCount(); if (vertCount <= 0) { ccLog::Warning(QString("[FBX] Mesh '%1' has no vetex or no polygon?!").arg(fbxMesh->GetName())); return 0; } ccPointCloud* vertices = new ccPointCloud("vertices"); ccMesh* mesh = new ccMesh(vertices); mesh->setName(fbxMesh->GetName()); mesh->addChild(vertices); vertices->setEnabled(false); if (!mesh->reserve(static_cast<unsigned>(triCount)) || !vertices->reserve(vertCount)) { ccLog::Warning(QString("[FBX] Not enough memory to load mesh '%1'!").arg(fbxMesh->GetName())); delete mesh; return 0; } //colors { for (int l=0; l<fbxMesh->GetElementVertexColorCount(); l++) { FbxGeometryElementVertexColor* vertColor = fbxMesh->GetElementVertexColor(l); //CC can only handle per-vertex colors if (vertColor->GetMappingMode() == FbxGeometryElement::eByControlPoint) { if (vertColor->GetReferenceMode() == FbxGeometryElement::eDirect || vertColor->GetReferenceMode() == FbxGeometryElement::eIndexToDirect) { if (vertices->reserveTheRGBTable()) { switch (vertColor->GetReferenceMode()) { case FbxGeometryElement::eDirect: { for (int i=0; i<vertCount; ++i) { FbxColor c = vertColor->GetDirectArray().GetAt(i); vertices->addRGBColor( static_cast<colorType>(c.mRed * MAX_COLOR_COMP), static_cast<colorType>(c.mGreen * MAX_COLOR_COMP), static_cast<colorType>(c.mBlue * MAX_COLOR_COMP) ); } } break; case FbxGeometryElement::eIndexToDirect: { for (int i=0; i<vertCount; ++i) { int id = vertColor->GetIndexArray().GetAt(i); FbxColor c = vertColor->GetDirectArray().GetAt(id); vertices->addRGBColor( static_cast<colorType>(c.mRed * MAX_COLOR_COMP), static_cast<colorType>(c.mGreen * MAX_COLOR_COMP), static_cast<colorType>(c.mBlue * MAX_COLOR_COMP) ); } } break; default: assert(false); break; } vertices->showColors(true); mesh->showColors(true); break; //no need to look for other color fields (we won't be able to handle them! } else { ccLog::Warning(QString("[FBX] Not enough memory to load mesh '%1' colors!").arg(fbxMesh->GetName())); } } else { ccLog::Warning(QString("[FBX] Color field #%i of mesh '%1' will be ignored (unhandled type)").arg(l).arg(fbxMesh->GetName())); } } else { ccLog::Warning(QString("[FBX] Color field #%i of mesh '%1' will be ignored (unhandled type)").arg(l).arg(fbxMesh->GetName())); } } } //normals can be per vertices or per-triangle int perPointNormals = -1; int perVertexNormals = -1; int perPolygonNormals = -1; { for (int j=0; j<fbxMesh->GetElementNormalCount(); j++) { FbxGeometryElementNormal* leNormals = fbxMesh->GetElementNormal(j); switch(leNormals->GetMappingMode()) { case FbxGeometryElement::eByControlPoint: perPointNormals = j; break; case FbxGeometryElement::eByPolygonVertex: perVertexNormals = j; break; case FbxGeometryElement::eByPolygon: perPolygonNormals = j; break; default: //not handled break; } } } //per-point normals if (perPointNormals >= 0) { FbxGeometryElementNormal* leNormals = fbxMesh->GetElementNormal(perPointNormals); FbxLayerElement::EReferenceMode refMode = leNormals->GetReferenceMode(); const FbxLayerElementArrayTemplate<FbxVector4>& normals = leNormals->GetDirectArray(); assert(normals.GetCount() == vertCount); if (normals.GetCount() != vertCount) { ccLog::Warning(QString("[FBX] Wrong number of normals on mesh '%1'!").arg(fbxMesh->GetName())); perPointNormals = -1; } else if (!vertices->reserveTheNormsTable()) { ccLog::Warning(QString("[FBX] Not enough memory to load mesh '%1' normals!").arg(fbxMesh->GetName())); perPointNormals = -1; } else { //import normals for (int i=0; i<vertCount; ++i) { int id = refMode != FbxGeometryElement::eDirect ? leNormals->GetIndexArray().GetAt(i) : i; FbxVector4 N = normals.GetAt(id); //convert to CC-structure CCVector3 Npc( static_cast<PointCoordinateType>(N.Buffer()[0]), static_cast<PointCoordinateType>(N.Buffer()[1]), static_cast<PointCoordinateType>(N.Buffer()[2]) ); vertices->addNorm(Npc.u); } vertices->showNormals(true); mesh->showNormals(true); //no need to import the other normals (if any) perVertexNormals = -1; perPolygonNormals = -1; } } //per-triangle normals NormsIndexesTableType* normsTable = 0; if (perVertexNormals >= 0 || perPolygonNormals >= 0) { normsTable = new NormsIndexesTableType(); if (!normsTable->reserve(polyVertCount) || !mesh->reservePerTriangleNormalIndexes()) { ccLog::Warning(QString("[FBX] Not enough memory to load mesh '%1' normals!").arg(fbxMesh->GetName())); normsTable->release(); normsTable = 0; } else { mesh->setTriNormsTable(normsTable); mesh->addChild(normsTable); vertices->showNormals(true); mesh->showNormals(true); } } //import textures UV int perVertexUV = -1; bool hasTexUV = false; { for (int l=0; l<fbxMesh->GetElementUVCount(); ++l) { FbxGeometryElementUV* leUV = fbxMesh->GetElementUV(l); //per-point UV coordinates if (leUV->GetMappingMode() == FbxGeometryElement::eByControlPoint) { TextureCoordsContainer* vertTexUVTable = new TextureCoordsContainer(); if (!vertTexUVTable->reserve(vertCount) || !mesh->reservePerTriangleTexCoordIndexes()) { vertTexUVTable->release(); ccLog::Warning(QString("[FBX] Not enough memory to load mesh '%1' UV coordinates!").arg(fbxMesh->GetName())); } else { FbxLayerElement::EReferenceMode refMode = leUV->GetReferenceMode(); for (int i=0; i<vertCount; ++i) { int id = refMode != FbxGeometryElement::eDirect ? leUV->GetIndexArray().GetAt(i) : i; FbxVector2 uv = leUV->GetDirectArray().GetAt(id); //convert to CC-structure float uvf[2] = {static_cast<float>(uv.Buffer()[0]), static_cast<float>(uv.Buffer()[1])}; vertTexUVTable->addElement(uvf); } mesh->addChild(vertTexUVTable); hasTexUV = true; } perVertexUV = -1; break; //no need to look to the other UV fields (can't handle them!) } else if (leUV->GetMappingMode() == FbxGeometryElement::eByPolygonVertex) { //per-vertex UV coordinates perVertexUV = l; } } } //per-vertex UV coordinates TextureCoordsContainer* texUVTable = 0; if (perVertexUV >= 0) { texUVTable = new TextureCoordsContainer(); if (!texUVTable->reserve(polyVertCount) || !mesh->reservePerTriangleTexCoordIndexes()) { texUVTable->release(); ccLog::Warning(QString("[FBX] Not enough memory to load mesh '%1' UV coordinates!").arg(fbxMesh->GetName())); } else { mesh->addChild(texUVTable); hasTexUV = true; } } //import polygons { for (int i=0; i<polyCount; ++i) { int pSize = fbxMesh->GetPolygonSize(i); if (pSize > 4) { //not handled for the moment continue; } //we split quads into two triangles //vertex indices int i1 = fbxMesh->GetPolygonVertex(i, 0); int i2 = fbxMesh->GetPolygonVertex(i, 1); int i3 = fbxMesh->GetPolygonVertex(i, 2); mesh->addTriangle(i1,i2,i3); int i4 = -1; if (pSize == 4) { i4 = fbxMesh->GetPolygonVertex(i, 3); mesh->addTriangle(i1,i3,i4); } if (hasTexUV) { if (texUVTable) { assert(perVertexUV >= 0); int uvIndex = static_cast<int>(texUVTable->currentSize()); for (int j=0; j<pSize; ++j) { int lTextureUVIndex = fbxMesh->GetTextureUVIndex(i, j); FbxGeometryElementUV* leUV = fbxMesh->GetElementUV(perVertexUV); FbxVector2 uv = leUV->GetDirectArray().GetAt(lTextureUVIndex); //convert to CC-structure float uvf[2] = {static_cast<float>(uv.Buffer()[0]), static_cast<float>(uv.Buffer()[1])}; texUVTable->addElement(uvf); } mesh->addTriangleTexCoordIndexes(uvIndex,uvIndex+1,uvIndex+2); if (pSize == 4) mesh->addTriangleTexCoordIndexes(uvIndex,uvIndex+2,uvIndex+3); } else { mesh->addTriangleTexCoordIndexes(i1,i2,i3); if (pSize == 4) mesh->addTriangleTexCoordIndexes(i1,i3,i4); } } //per-triangle normals if (normsTable) { int nIndex = static_cast<int>(normsTable->currentSize()); for (int j=0; j<pSize; ++j) { FbxVector4 N; fbxMesh->GetPolygonVertexNormal(i, j, N); CCVector3 Npc( static_cast<PointCoordinateType>(N.Buffer()[0]), static_cast<PointCoordinateType>(N.Buffer()[1]), static_cast<PointCoordinateType>(N.Buffer()[2]) ); normsTable->addElement(ccNormalVectors::GetNormIndex(Npc.u)); } mesh->addTriangleNormalIndexes(nIndex,nIndex+1,nIndex+2); if (pSize == 4) mesh->addTriangleNormalIndexes(nIndex,nIndex+2,nIndex+3); } } if (mesh->size() == 0) { ccLog::Warning(QString("[FBX] No triangle found in mesh '%1'! (only triangles are supported for the moment)").arg(fbxMesh->GetName())); delete mesh; return 0; } } //import vertices { const FbxVector4* fbxVertices = fbxMesh->GetControlPoints(); assert(vertices && fbxVertices); CCVector3d Pshift(0,0,0); for (int i=0; i<vertCount; ++i, ++fbxVertices) { const double* P = fbxVertices->Buffer(); assert(P[3] == 0); //coordinate shift management if (i == 0) { bool shiftAlreadyEnabled = (coordinatesShiftEnabled && *coordinatesShiftEnabled && coordinatesShift); if (shiftAlreadyEnabled) Pshift = *coordinatesShift; bool applyAll = false; if ( sizeof(PointCoordinateType) < 8 && ccCoordinatesShiftManager::Handle(P,0,alwaysDisplayLoadDialog,shiftAlreadyEnabled,Pshift,0,applyAll)) { vertices->setGlobalShift(Pshift); ccLog::Warning("[FBX] Mesh has been recentered! Translation: (%.2f,%.2f,%.2f)",Pshift.x,Pshift.y,Pshift.z); //we save coordinates shift information if (applyAll && coordinatesShiftEnabled && coordinatesShift) { *coordinatesShiftEnabled = true; *coordinatesShift = Pshift; } } } CCVector3 PV( static_cast<PointCoordinateType>(P[0] + Pshift.x), static_cast<PointCoordinateType>(P[1] + Pshift.y), static_cast<PointCoordinateType>(P[2] + Pshift.z) ); vertices->addPoint(PV); } } //import textures { //TODO } return mesh; }
// Converts a CC mesh to an FBX mesh static FbxNode* ToFbxMesh(ccGenericMesh* mesh, FbxScene* pScene) { if (!mesh) return 0; FbxMesh* lMesh = FbxMesh::Create(pScene, qPrintable(mesh->getName())); ccGenericPointCloud* cloud = mesh->getAssociatedCloud(); if (!cloud) return 0; unsigned vertCount = cloud->size(); unsigned faceCount = mesh->size(); // Create control points. { lMesh->InitControlPoints(vertCount); FbxVector4* lControlPoints = lMesh->GetControlPoints(); for (unsigned i=0; i<vertCount; ++i) { const CCVector3* P = cloud->getPoint(i); lControlPoints[i] = FbxVector4(P->x,P->y,P->z); } } ccMesh* asCCMesh = 0; if (mesh->isA(CC_MESH)) asCCMesh = static_cast<ccMesh*>(mesh); // normals if (mesh->hasNormals()) { FbxGeometryElementNormal* lGeometryElementNormal = lMesh->CreateElementNormal(); if (mesh->hasTriNormals()) { // We want to have one normal per vertex of each polygon, // so we set the mapping mode to eByPolygonVertex. lGeometryElementNormal->SetMappingMode(FbxGeometryElement::eByPolygonVertex); lGeometryElementNormal->SetReferenceMode(FbxGeometryElement::eIndexToDirect); lGeometryElementNormal->GetIndexArray().SetCount(faceCount*3); if (asCCMesh) { NormsIndexesTableType* triNorms = asCCMesh->getTriNormsTable(); assert(triNorms); for (unsigned i=0; i<triNorms->currentSize(); ++i) { const PointCoordinateType* N = ccNormalVectors::GetNormal(triNorms->getValue(i)); FbxVector4 Nfbx(N[0],N[1],N[2]); lGeometryElementNormal->GetDirectArray().Add(Nfbx); } for (unsigned j=0; j<faceCount; ++j) { int i1,i2,i3; asCCMesh->getTriangleNormalIndexes(j,i1,i2,i3); lGeometryElementNormal->GetIndexArray().SetAt(static_cast<int>(j)*3+0, i1); lGeometryElementNormal->GetIndexArray().SetAt(static_cast<int>(j)*3+1, i2); lGeometryElementNormal->GetIndexArray().SetAt(static_cast<int>(j)*3+2, i3); } } else { for (unsigned j=0; j<faceCount; ++j) { //we can't use the 'NormsIndexesTable' so we save all the normals of all the vertices CCVector3 Na,Nb,Nc; lGeometryElementNormal->GetDirectArray().Add(FbxVector4(Na.x,Na.y,Na.z)); lGeometryElementNormal->GetDirectArray().Add(FbxVector4(Nb.x,Nb.y,Nb.z)); lGeometryElementNormal->GetDirectArray().Add(FbxVector4(Nc.x,Nc.y,Nc.z)); mesh->getTriangleNormals(j,Na,Nb,Nc); lGeometryElementNormal->GetIndexArray().SetAt(static_cast<int>(j)*3+0, static_cast<int>(j)*3+0); lGeometryElementNormal->GetIndexArray().SetAt(static_cast<int>(j)*3+1, static_cast<int>(j)*3+1); lGeometryElementNormal->GetIndexArray().SetAt(static_cast<int>(j)*3+2, static_cast<int>(j)*3+2); } } } else { // We want to have one normal for each vertex (or control point), // so we set the mapping mode to eByControlPoint. lGeometryElementNormal->SetMappingMode(FbxGeometryElement::eByControlPoint); // The first method is to set the actual normal value // for every control point. lGeometryElementNormal->SetReferenceMode(FbxGeometryElement::eDirect); for (unsigned i=0; i<vertCount; ++i) { const PointCoordinateType* N = cloud->getPointNormal(i); FbxVector4 Nfbx(N[0],N[1],N[2]); lGeometryElementNormal->GetDirectArray().Add(Nfbx); } } } else { ccLog::Warning("[FBX] Mesh has no normal! You can manually compute them (select it then call \"Edit > Normals > Compute\")"); } // colors if (cloud->hasColors()) { FbxGeometryElementVertexColor* lGeometryElementVertexColor = lMesh->CreateElementVertexColor(); lGeometryElementVertexColor->SetMappingMode(FbxGeometryElement::eByControlPoint); lGeometryElementVertexColor->SetReferenceMode(FbxGeometryElement::eDirect); for (unsigned i=0; i<vertCount; ++i) { const colorType* C = cloud->getPointColor(i); FbxColor col( FbxDouble3( static_cast<double>(C[0])/MAX_COLOR_COMP, static_cast<double>(C[1])/MAX_COLOR_COMP, static_cast<double>(C[2])/MAX_COLOR_COMP ) ); lGeometryElementVertexColor->GetDirectArray().Add(col); } } // Set material mapping. //FbxGeometryElementMaterial* lMaterialElement = lMesh->CreateElementMaterial(); //lMaterialElement->SetMappingMode(FbxGeometryElement::eByPolygon); //lMaterialElement->SetReferenceMode(FbxGeometryElement::eIndexToDirect); // Create polygons. Assign material indices. { for (unsigned j=0; j<faceCount; ++j) { const CCLib::TriangleSummitsIndexes* tsi = mesh->getTriangleIndexes(j); lMesh->BeginPolygon(static_cast<int>(j)); lMesh->AddPolygon(tsi->i1); lMesh->AddPolygon(tsi->i2); lMesh->AddPolygon(tsi->i3); lMesh->EndPolygon(); } } FbxNode* lNode = FbxNode::Create(pScene,qPrintable(mesh->getName())); lNode->SetNodeAttribute(lMesh); //CreateMaterials(pScene, lMesh); return lNode; }
HRESULT CStaticMesh::Load_StaticMesh(const char* szFilePath,const char* szFileName, FbxManager* _pFBXManager, FbxIOSettings* _pIOsettings, FbxScene* _pFBXScene, FbxImporter* _pImporter) { HRESULT hr = E_FAIL; vector<UINT> vecIndeces; string strFullPath; strFullPath.clear(); strFullPath = szFilePath; strFullPath += szFileName;//경로에 파일이름 추가 if (!(_pImporter->Initialize(strFullPath.c_str(), -1, _pFBXManager->GetIOSettings()))) FAILED_CHECK_MSG(E_FAIL, L"Static Mesh Init Failed"); if (!(_pImporter->Import(_pFBXScene))) FAILED_CHECK_MSG(E_FAIL, L"Static Mesh Import Failed"); FbxGeometryConverter clsConverter(_pFBXManager); clsConverter.Triangulate(_pFBXScene, false); FbxNode* pRootNode = _pFBXScene->GetRootNode(); if (!pRootNode) return E_FAIL; vector<VTXTEX> vecVTXTEX; for (int i = 0; i < pRootNode->GetChildCount(); ++i) { FbxNode* pChildNode = pRootNode->GetChild(i); if (pChildNode->GetNodeAttribute() == NULL) continue; FbxNodeAttribute::EType AttributeType = pChildNode->GetNodeAttribute()->GetAttributeType(); if (AttributeType != FbxNodeAttribute::eMesh) continue; FbxMesh* pMesh = (FbxMesh*)pChildNode->GetNodeAttribute(); // 임폴트 하려는 메쉬의 데이터 D3DXVECTOR3 vPos; D3DXVECTOR2 vOutUV; D3DXVECTOR3 vOutNormal; FbxVector4* mControlPoints = pMesh->GetControlPoints(); int iVTXCounter = 0; for (int j = 0; j < pMesh->GetPolygonCount(); j++) // 폴리곤의 인덱스 { int iNumVertices = pMesh->GetPolygonSize(j); assert(iNumVertices == 3); FbxGeometryElementUV* VtxUV = pMesh->GetElementUV(0); FbxGeometryElementNormal* VtxNormal = pMesh->GetElementNormal(0); for (int k = 0; k < iNumVertices; k++) // 폴리곤을 구성하는 버텍스의 인덱스 { //정점 데이터 얻는곳 int iControlPointIndex = pMesh->GetPolygonVertex(j, k); // 컨트롤 포인트 = 하나의 버텍스 int iTextureUVIndex = pMesh->GetTextureUVIndex(j, k); // Control = Vertex //int iNormalIndex = pMesh->GetPolygonVertexIndex(j, k); ++iVTXCounter; vPos.x = (float)mControlPoints[iControlPointIndex].mData[0]; vPos.y = -(float)mControlPoints[iControlPointIndex].mData[1]; vPos.z = (float)mControlPoints[iControlPointIndex].mData[2]; //uv 얻기 switch (VtxUV->GetMappingMode()) // UV값 추출 { case FbxGeometryElement::eByControlPoint: // 하나의 컨트롤 포인트가 하나의 노멀벡터를 가질때 switch (VtxUV->GetReferenceMode()) { case FbxGeometryElement::eDirect: { vOutUV.x = static_cast<float>(VtxUV->GetDirectArray().GetAt(iControlPointIndex).mData[0]); vOutUV.y = static_cast<float>(VtxUV->GetDirectArray().GetAt(iControlPointIndex).mData[1]); } break; case FbxGeometryElement::eIndexToDirect: { int index = VtxUV->GetIndexArray().GetAt(iControlPointIndex); vOutUV.x = static_cast<float>(VtxUV->GetDirectArray().GetAt(index).mData[0]); vOutUV.y = static_cast<float>(VtxUV->GetDirectArray().GetAt(index).mData[1]); } break; default: throw std::exception("Invalid Reference"); } break; case FbxGeometryElement::eByPolygonVertex: // Sharp Edge 포인트가 존재할때 고로 우리가 실질적으로 쓰는곳 switch (VtxUV->GetReferenceMode()) { case FbxGeometryElement::eDirect: { vOutUV.x = static_cast<float>(VtxUV->GetDirectArray().GetAt(iTextureUVIndex).mData[0]); vOutUV.y = 1 - static_cast<float>(VtxUV->GetDirectArray().GetAt(iTextureUVIndex).mData[1]); } case FbxGeometryElement::eIndexToDirect: { vOutUV.x = static_cast<float>(VtxUV->GetDirectArray().GetAt(iTextureUVIndex).mData[0]); vOutUV.y = 1 - static_cast<float>(VtxUV->GetDirectArray().GetAt(iTextureUVIndex).mData[1]); } break; default: throw std::exception("invalid Reference"); } break; default: throw std::exception("Invalid Reference"); break; } //노멀얻기 switch (VtxNormal->GetMappingMode()) // 노멀값 추출 { case FbxGeometryElement::eByControlPoint: // 하나의 컨트롤 포인트가 하나의 노멀벡터를 가질때 switch (VtxNormal->GetReferenceMode()) { case FbxGeometryElement::eDirect: { vOutNormal.x = static_cast<float>(VtxNormal->GetDirectArray().GetAt(iControlPointIndex).mData[0]); vOutNormal.y = static_cast<float>(VtxNormal->GetDirectArray().GetAt(iControlPointIndex).mData[1]); vOutNormal.z = static_cast<float>(VtxNormal->GetDirectArray().GetAt(iControlPointIndex).mData[2]); } break; case FbxGeometryElement::eIndexToDirect: { int index = VtxNormal->GetIndexArray().GetAt(iControlPointIndex); vOutNormal.x = static_cast<float>(VtxNormal->GetDirectArray().GetAt(index).mData[0]); vOutNormal.y = static_cast<float>(VtxNormal->GetDirectArray().GetAt(index).mData[1]); vOutNormal.z = static_cast<float>(VtxNormal->GetDirectArray().GetAt(index).mData[2]); } break; default: throw std::exception("Invalid Reference"); } break; case FbxGeometryElement::eByPolygonVertex: // Sharp Edge 포인트가 존재할때 고로 우리가 실질적으로 쓰는곳 switch (VtxNormal->GetReferenceMode()) { case FbxGeometryElement::eDirect: { int index = VtxNormal->GetIndexArray().GetAt(iVTXCounter); vOutNormal.x = static_cast<float>(VtxNormal->GetDirectArray().GetAt(index).mData[0]); vOutNormal.y = static_cast<float>(VtxNormal->GetDirectArray().GetAt(index).mData[1]); vOutNormal.z = static_cast<float>(VtxNormal->GetDirectArray().GetAt(index).mData[2]); } case FbxGeometryElement::eIndexToDirect: { int index = VtxNormal->GetIndexArray().GetAt(iVTXCounter); vOutNormal.x = static_cast<float>(VtxNormal->GetDirectArray().GetAt(index).mData[0]); vOutNormal.y = static_cast<float>(VtxNormal->GetDirectArray().GetAt(index).mData[1]); vOutNormal.z = static_cast<float>(VtxNormal->GetDirectArray().GetAt(index).mData[2]); } break; default: throw std::exception("invalid Reference"); } break; default: throw std::exception("Invalid Reference"); break; } VTXTEX vtxtex; vtxtex.vPos = vPos; vtxtex.vNormal = vOutNormal; vtxtex.vTexUV = vOutUV; vecVTXTEX.push_back(vtxtex); //int index = VtxUV->GetIndexArray().GetAt(iTextureUVIndex); vecIndeces.push_back(VtxUV->GetIndexArray().GetAt(iTextureUVIndex)); } } } unsigned int n = vecVTXTEX.size(); VTXTEX* pVTXTex = new VTXTEX[n]; for (unsigned int i = 0; i < vecVTXTEX.size(); ++i) { pVTXTex[i].vPos = vecVTXTEX[i].vPos; pVTXTex[i].vNormal = vecVTXTEX[i].vNormal; pVTXTex[i].vTexUV = vecVTXTEX[i].vTexUV; } m_iVertices = vecVTXTEX.size(); m_iVertexStrides = sizeof(VTXTEX); m_iVertexOffsets = 0; MakeVertexNormal((BYTE*)pVTXTex, NULL); D3D11_BUFFER_DESC tBufferDesc; ZeroMemory(&tBufferDesc, sizeof(D3D11_BUFFER_DESC)); tBufferDesc.Usage = D3D11_USAGE_DEFAULT; tBufferDesc.ByteWidth = m_iVertexStrides * m_iVertices; tBufferDesc.BindFlags = D3D11_BIND_VERTEX_BUFFER; tBufferDesc.CPUAccessFlags = 0; D3D11_SUBRESOURCE_DATA tData; ZeroMemory(&tData, sizeof(D3D11_SUBRESOURCE_DATA)); tData.pSysMem = pVTXTex; hr = CDevice::GetInstance()->m_pDevice->CreateBuffer(&tBufferDesc, &tData, &m_VertexBuffer); ::Safe_Delete(pVTXTex); if (FAILED(hr)) return E_FAIL; D3D11_BUFFER_DESC cbd; cbd.Usage = D3D11_USAGE_DEFAULT; cbd.ByteWidth = sizeof(ConstantBuffer); cbd.BindFlags = D3D11_BIND_CONSTANT_BUFFER; cbd.CPUAccessFlags = 0; cbd.MiscFlags = 0; cbd.StructureByteStride = 0; hr = CDevice::GetInstance()->m_pDevice->CreateBuffer(&cbd, NULL, &m_ConstantBuffer); if (FAILED(hr)) { MessageBox(NULL, L"System Message", L"Constant Buffer Error", MB_OK); return hr; } return S_OK; }
void loadNormal(FbxMesh* fbxMesh, int vertexIndex, int controlPointIndex, Vertex* vertex) { if (fbxMesh->GetElementNormalCount() > 0) { // Get only the first FbxGeometryElementNormal* normal = fbxMesh->GetElementNormal(0); FbxGeometryElement::EMappingMode mappingMode = normal->GetMappingMode(); if (mappingMode == FbxGeometryElement::eByControlPoint) { switch (normal->GetReferenceMode()) { case FbxGeometryElement::eDirect: { FbxVector4 vec4 = normal->GetDirectArray().GetAt(controlPointIndex); vertex->hasNormal = true; vertex->normal.x = (float)vec4[0]; vertex->normal.y = (float)vec4[1]; vertex->normal.z = (float)vec4[2]; } break; case FbxGeometryElement::eIndexToDirect: { int id = normal->GetIndexArray().GetAt(controlPointIndex); FbxVector4 vec4 = normal->GetDirectArray().GetAt(id); vertex->hasNormal = true; vertex->normal.x = (float)vec4[0]; vertex->normal.y = (float)vec4[1]; vertex->normal.z = (float)vec4[2]; } break; default: break; } } else if (mappingMode == FbxGeometryElement::eByPolygonVertex) { switch (normal->GetReferenceMode()) { case FbxGeometryElement::eDirect: { FbxVector4 vec4 = normal->GetDirectArray().GetAt(vertexIndex); vertex->hasNormal = true; vertex->normal.x = (float)vec4[0]; vertex->normal.y = (float)vec4[1]; vertex->normal.z = (float)vec4[2]; } break; case FbxGeometryElement::eIndexToDirect: { int id = normal->GetIndexArray().GetAt(vertexIndex); FbxVector4 vec4 = normal->GetDirectArray().GetAt(id); vertex->hasNormal = true; vertex->normal.x = (float)vec4[0]; vertex->normal.y = (float)vec4[1]; vertex->normal.z = (float)vec4[2]; } break; default: break; } } } }
void fbxLoader2::readNormal(FbxMesh* mesh, int controlPointIndex, D3DXVECTOR3* normal) { if (mesh->GetElementNormalCount()<1) { return; } FbxGeometryElementNormal* normalEl = mesh->GetElementNormal(0); switch(normalEl->GetMappingMode()) { case FbxGeometryElement::eDirect: { switch(normalEl->GetReferenceMode()) { case FbxGeometryElement::eDirect: { normal->x = (float)normalEl->GetDirectArray().GetAt(controlPointIndex).mData[0]; normal->y = (float)normalEl->GetDirectArray().GetAt(controlPointIndex).mData[1]; normal->z = (float)normalEl->GetDirectArray().GetAt(controlPointIndex).mData[2]; } break; case FbxGeometryElement::eIndexToDirect: { int id = normalEl->GetIndexArray().GetAt(controlPointIndex); normal->x = (float)normalEl->GetDirectArray().GetAt(id).mData[0]; normal->y = (float)normalEl->GetDirectArray().GetAt(id).mData[1]; normal->z = (float)normalEl->GetDirectArray().GetAt(id).mData[2]; } break; } } break; case FbxGeometryElement::eByPolygonVertex: { switch(normalEl->GetReferenceMode()) { case FbxGeometryElement::eDirect: { normal->x = (float)normalEl->GetDirectArray().GetAt(controlPointIndex).mData[0]; normal->y = (float)normalEl->GetDirectArray().GetAt(controlPointIndex).mData[1]; normal->z = (float)normalEl->GetDirectArray().GetAt(controlPointIndex).mData[2]; } break; case FbxGeometryElement::eIndexToDirect: { int id = normalEl->GetIndexArray().GetAt(controlPointIndex); normal->x = (float)normalEl->GetDirectArray().GetAt(id).mData[0]; normal->y = (float)normalEl->GetDirectArray().GetAt(id).mData[1]; normal->z = (float)normalEl->GetDirectArray().GetAt(id).mData[2]; } break; } } break; default: int id = normalEl->GetIndexArray().GetAt(controlPointIndex); normal->x = (float)normalEl->GetDirectArray().GetAt(id).mData[0]; normal->y = (float)normalEl->GetDirectArray().GetAt(id).mData[1]; normal->z = (float)normalEl->GetDirectArray().GetAt(id).mData[2]; } }
//converts a FBX mesh to a CC mesh static ccMesh* FromFbxMesh(FbxMesh* fbxMesh, FileIOFilter::LoadParameters& parameters) { if (!fbxMesh) return 0; int polyCount = fbxMesh->GetPolygonCount(); //fbxMesh->GetLayer( unsigned triCount = 0; unsigned polyVertCount = 0; //different from vertCount (vertices can be counted multiple times here!) //as we can't load all polygons (yet ;) we already look if we can load any! { unsigned skipped = 0; for (int i=0; i<polyCount; ++i) { int pSize = fbxMesh->GetPolygonSize(i); if (pSize == 3) { ++triCount; polyVertCount += 3; } else if (pSize == 4) { triCount += 2; polyVertCount += 4; } else { ++skipped; } } if (triCount == 0) { ccLog::Warning(QString("[FBX] No triangle or quad found in mesh '%1'! (polygons with more than 4 vertices are not supported for the moment)").arg(fbxMesh->GetName())); return 0; } else if (skipped != 0) { ccLog::Warning(QString("[FBX] Some polygons in mesh '%1' were ignored (%2): polygons with more than 4 vertices are not supported for the moment)").arg(fbxMesh->GetName()).arg(skipped)); return 0; } } int vertCount = fbxMesh->GetControlPointsCount(); if (vertCount <= 0) { ccLog::Warning(QString("[FBX] Mesh '%1' has no vetex or no polygon?!").arg(fbxMesh->GetName())); return 0; } ccPointCloud* vertices = new ccPointCloud("vertices"); ccMesh* mesh = new ccMesh(vertices); mesh->setName(fbxMesh->GetName()); mesh->addChild(vertices); vertices->setEnabled(false); if (!mesh->reserve(static_cast<unsigned>(triCount)) || !vertices->reserve(vertCount)) { ccLog::Warning(QString("[FBX] Not enough memory to load mesh '%1'!").arg(fbxMesh->GetName())); delete mesh; return 0; } //colors { for (int l=0; l<fbxMesh->GetElementVertexColorCount(); l++) { FbxGeometryElementVertexColor* vertColor = fbxMesh->GetElementVertexColor(l); //CC can only handle per-vertex colors if (vertColor->GetMappingMode() == FbxGeometryElement::eByControlPoint) { if (vertColor->GetReferenceMode() == FbxGeometryElement::eDirect || vertColor->GetReferenceMode() == FbxGeometryElement::eIndexToDirect) { if (vertices->reserveTheRGBTable()) { switch (vertColor->GetReferenceMode()) { case FbxGeometryElement::eDirect: { for (int i=0; i<vertCount; ++i) { FbxColor c = vertColor->GetDirectArray().GetAt(i); vertices->addRGBColor( static_cast<colorType>(c.mRed * ccColor::MAX), static_cast<colorType>(c.mGreen * ccColor::MAX), static_cast<colorType>(c.mBlue * ccColor::MAX) ); } } break; case FbxGeometryElement::eIndexToDirect: { for (int i=0; i<vertCount; ++i) { int id = vertColor->GetIndexArray().GetAt(i); FbxColor c = vertColor->GetDirectArray().GetAt(id); vertices->addRGBColor( static_cast<colorType>(c.mRed * ccColor::MAX), static_cast<colorType>(c.mGreen * ccColor::MAX), static_cast<colorType>(c.mBlue * ccColor::MAX) ); } } break; default: assert(false); break; } vertices->showColors(true); mesh->showColors(true); break; //no need to look for other color fields (we won't be able to handle them! } else { ccLog::Warning(QString("[FBX] Not enough memory to load mesh '%1' colors!").arg(fbxMesh->GetName())); } } else { ccLog::Warning(QString("[FBX] Color field #%i of mesh '%1' will be ignored (unhandled type)").arg(l).arg(fbxMesh->GetName())); } } else { ccLog::Warning(QString("[FBX] Color field #%i of mesh '%1' will be ignored (unhandled type)").arg(l).arg(fbxMesh->GetName())); } } } //normals can be per vertices or per-triangle int perPointNormals = -1; int perVertexNormals = -1; int perPolygonNormals = -1; { for (int j=0; j<fbxMesh->GetElementNormalCount(); j++) { FbxGeometryElementNormal* leNormals = fbxMesh->GetElementNormal(j); switch(leNormals->GetMappingMode()) { case FbxGeometryElement::eByControlPoint: perPointNormals = j; break; case FbxGeometryElement::eByPolygonVertex: perVertexNormals = j; break; case FbxGeometryElement::eByPolygon: perPolygonNormals = j; break; default: //not handled break; } } } //per-point normals if (perPointNormals >= 0) { FbxGeometryElementNormal* leNormals = fbxMesh->GetElementNormal(perPointNormals); FbxLayerElement::EReferenceMode refMode = leNormals->GetReferenceMode(); const FbxLayerElementArrayTemplate<FbxVector4>& normals = leNormals->GetDirectArray(); assert(normals.GetCount() == vertCount); if (normals.GetCount() != vertCount) { ccLog::Warning(QString("[FBX] Wrong number of normals on mesh '%1'!").arg(fbxMesh->GetName())); perPointNormals = -1; } else if (!vertices->reserveTheNormsTable()) { ccLog::Warning(QString("[FBX] Not enough memory to load mesh '%1' normals!").arg(fbxMesh->GetName())); perPointNormals = -1; } else { //import normals for (int i=0; i<vertCount; ++i) { int id = refMode != FbxGeometryElement::eDirect ? leNormals->GetIndexArray().GetAt(i) : i; FbxVector4 N = normals.GetAt(id); //convert to CC-structure CCVector3 Npc( static_cast<PointCoordinateType>(N.Buffer()[0]), static_cast<PointCoordinateType>(N.Buffer()[1]), static_cast<PointCoordinateType>(N.Buffer()[2]) ); vertices->addNorm(Npc); } vertices->showNormals(true); mesh->showNormals(true); //no need to import the other normals (if any) perVertexNormals = -1; perPolygonNormals = -1; } } //per-triangle normals NormsIndexesTableType* normsTable = 0; if (perVertexNormals >= 0 || perPolygonNormals >= 0) { normsTable = new NormsIndexesTableType(); if (!normsTable->reserve(polyVertCount) || !mesh->reservePerTriangleNormalIndexes()) { ccLog::Warning(QString("[FBX] Not enough memory to load mesh '%1' normals!").arg(fbxMesh->GetName())); normsTable->release(); normsTable = 0; } else { mesh->setTriNormsTable(normsTable); vertices->showNormals(true); mesh->showNormals(true); } } //materials ccMaterialSet* materials = 0; { FbxNode* lNode = fbxMesh->GetNode(); int lMaterialCount = lNode ? lNode->GetMaterialCount() : 0; for (int i=0; i<lMaterialCount; i++) { FbxSurfaceMaterial *lBaseMaterial = lNode->GetMaterial(i); bool isLambert = lBaseMaterial->GetClassId().Is(FbxSurfaceLambert::ClassId); bool isPhong = lBaseMaterial->GetClassId().Is(FbxSurfacePhong::ClassId); if (isLambert || isPhong) { ccMaterial::Shared mat(new ccMaterial(lBaseMaterial->GetName())); FbxSurfaceLambert* lLambertMat = static_cast<FbxSurfaceLambert*>(lBaseMaterial); float ambient[4]; float diffuse[4]; float emission[4]; float specular[4]; FbxSurfacePhong* lPhongMat = isPhong ? static_cast<FbxSurfacePhong*>(lBaseMaterial) : 0; for (int k=0; k<3; ++k) { ambient[k] = static_cast<float>(lLambertMat->Ambient.Get()[k]); diffuse[k] = static_cast<float>(lLambertMat->Diffuse.Get()[k]); emission[k] = static_cast<float>(lLambertMat->Emissive.Get()[k]); if (lPhongMat) { specular[k] = static_cast<float>(lPhongMat->Specular.Get()[k]); } } mat->setAmbient(ambient); mat->setDiffuse(diffuse); mat->setEmission(emission); if (isPhong) { mat->setSpecular(specular); assert(lPhongMat); mat->setShininess(static_cast<float>(lPhongMat->Shininess)); } //import associated texture (if any) { int lTextureIndex; FBXSDK_FOR_EACH_TEXTURE(lTextureIndex) { FbxProperty lProperty = lBaseMaterial->FindProperty(FbxLayerElement::sTextureChannelNames[lTextureIndex]); if( lProperty.IsValid() ) { int lTextureCount = lProperty.GetSrcObjectCount<FbxTexture>(); FbxTexture* texture = 0; //we can handle only one texture per material! We'll take the non layered one by default (if any) for (int j = 0; j < lTextureCount; ++j) { //Here we have to check if it's layeredtextures, or just textures: FbxLayeredTexture *lLayeredTexture = lProperty.GetSrcObject<FbxLayeredTexture>(j); if (lLayeredTexture) { //we don't handle layered textures! /*int lNbTextures = lLayeredTexture->GetSrcObjectCount<FbxTexture>(); for (int k=0; k<lNbTextures; ++k) { FbxTexture* lTexture = lLayeredTexture->GetSrcObject<FbxTexture>(k); if(lTexture) { } } //*/ } else { //non-layered texture FbxTexture* lTexture = lProperty.GetSrcObject<FbxTexture>(j); if(lTexture) { //we take the first non layered texture by default texture = lTexture; break; } } } if (texture) { FbxFileTexture *lFileTexture = FbxCast<FbxFileTexture>(texture); if (lFileTexture) { const char* texAbsoluteFilename = lFileTexture->GetFileName(); ccLog::PrintDebug(QString("[FBX] Texture absolue filename: %1").arg(texAbsoluteFilename)); if (texAbsoluteFilename != 0 && texAbsoluteFilename[0] != 0) { if (!mat->loadAndSetTexture(texAbsoluteFilename)) { ccLog::Warning(QString("[FBX] Failed to load texture file: %1").arg(texAbsoluteFilename)); } } } } } } } if (!materials) { materials = new ccMaterialSet("materials"); mesh->addChild(materials); } materials->addMaterial(mat); } else { ccLog::Warning(QString("[FBX] Material '%1' has an unhandled type").arg(lBaseMaterial->GetName())); } }
// Converts a CC mesh to an FBX mesh static FbxNode* ToFbxMesh(ccGenericMesh* mesh, FbxScene* pScene, QString filename, size_t meshIndex) { if (!mesh) return 0; FbxNode* lNode = FbxNode::Create(pScene,qPrintable(mesh->getName())); FbxMesh* lMesh = FbxMesh::Create(pScene, qPrintable(mesh->getName())); lNode->SetNodeAttribute(lMesh); ccGenericPointCloud* cloud = mesh->getAssociatedCloud(); if (!cloud) return 0; unsigned vertCount = cloud->size(); unsigned faceCount = mesh->size(); // Create control points. { lMesh->InitControlPoints(vertCount); FbxVector4* lControlPoints = lMesh->GetControlPoints(); for (unsigned i=0; i<vertCount; ++i) { const CCVector3* P = cloud->getPoint(i); lControlPoints[i] = FbxVector4(P->x,P->y,P->z); //lControlPoints[i] = FbxVector4(P->x,P->z,-P->y); //DGM: see loadFile (Y and Z are inverted) } } ccMesh* asCCMesh = 0; if (mesh->isA(CC_TYPES::MESH)) asCCMesh = static_cast<ccMesh*>(mesh); // normals if (mesh->hasNormals()) { FbxGeometryElementNormal* lGeometryElementNormal = lMesh->CreateElementNormal(); if (mesh->hasTriNormals()) { // We want to have one normal per vertex of each polygon, // so we set the mapping mode to eByPolygonVertex. lGeometryElementNormal->SetMappingMode(FbxGeometryElement::eByPolygonVertex); lGeometryElementNormal->SetReferenceMode(FbxGeometryElement::eIndexToDirect); lGeometryElementNormal->GetIndexArray().SetCount(faceCount*3); if (asCCMesh) { NormsIndexesTableType* triNorms = asCCMesh->getTriNormsTable(); assert(triNorms); for (unsigned i=0; i<triNorms->currentSize(); ++i) { const CCVector3& N = ccNormalVectors::GetNormal(triNorms->getValue(i)); FbxVector4 Nfbx(N.x,N.y,N.z); lGeometryElementNormal->GetDirectArray().Add(Nfbx); } for (unsigned j=0; j<faceCount; ++j) { int i1,i2,i3; asCCMesh->getTriangleNormalIndexes(j,i1,i2,i3); lGeometryElementNormal->GetIndexArray().SetAt(static_cast<int>(j)*3+0, i1); lGeometryElementNormal->GetIndexArray().SetAt(static_cast<int>(j)*3+1, i2); lGeometryElementNormal->GetIndexArray().SetAt(static_cast<int>(j)*3+2, i3); } } else { for (unsigned j=0; j<faceCount; ++j) { //we can't use the 'NormsIndexesTable' so we save all the normals of all the vertices CCVector3 Na,Nb,Nc; lGeometryElementNormal->GetDirectArray().Add(FbxVector4(Na.x,Na.y,Na.z)); lGeometryElementNormal->GetDirectArray().Add(FbxVector4(Nb.x,Nb.y,Nb.z)); lGeometryElementNormal->GetDirectArray().Add(FbxVector4(Nc.x,Nc.y,Nc.z)); mesh->getTriangleNormals(j,Na,Nb,Nc); lGeometryElementNormal->GetIndexArray().SetAt(static_cast<int>(j)*3+0, static_cast<int>(j)*3+0); lGeometryElementNormal->GetIndexArray().SetAt(static_cast<int>(j)*3+1, static_cast<int>(j)*3+1); lGeometryElementNormal->GetIndexArray().SetAt(static_cast<int>(j)*3+2, static_cast<int>(j)*3+2); } } } else { // We want to have one normal for each vertex (or control point), // so we set the mapping mode to eByControlPoint. lGeometryElementNormal->SetMappingMode(FbxGeometryElement::eByControlPoint); // The first method is to set the actual normal value // for every control point. lGeometryElementNormal->SetReferenceMode(FbxGeometryElement::eDirect); for (unsigned i=0; i<vertCount; ++i) { const CCVector3& N = cloud->getPointNormal(i); FbxVector4 Nfbx(N.x,N.y,N.z); lGeometryElementNormal->GetDirectArray().Add(Nfbx); } } } else { ccLog::Warning("[FBX] Mesh has no normal! You can manually compute them (select it then call \"Edit > Normals > Compute\")"); } // Set material mapping. bool hasMaterial = false; if (asCCMesh && asCCMesh->hasMaterials()) { const ccMaterialSet* matSet = asCCMesh->getMaterialSet(); size_t matCount = matSet->size(); //check if we have textures bool hasTextures = asCCMesh->hasTextures(); if (hasTextures) { //check that we actually have materials with textures as well! hasTextures = false; for (size_t i=0; i<matCount; ++i) { ccMaterial::CShared mat = matSet->at(i); if (mat->hasTexture()) { hasTextures = true; break; } } } static const char gDiffuseElementName[] = "DiffuseUV"; // Create UV for Diffuse channel if (hasTextures) { FbxGeometryElementUV* lUVDiffuseElement = lMesh->CreateElementUV(gDiffuseElementName); assert(lUVDiffuseElement != 0); lUVDiffuseElement->SetMappingMode(FbxGeometryElement::eByPolygonVertex); lUVDiffuseElement->SetReferenceMode(FbxGeometryElement::eIndexToDirect); //fill Direct Array const TextureCoordsContainer* texCoords = asCCMesh->getTexCoordinatesTable(); assert(texCoords); if (texCoords) { unsigned count = texCoords->currentSize(); lUVDiffuseElement->GetDirectArray().SetCount(static_cast<int>(count)); for (unsigned i=0; i<count; ++i) { const float* uv = texCoords->getValue(i); lUVDiffuseElement->GetDirectArray().SetAt(i,FbxVector2(uv[0],uv[1])); } } //fill Indexes Array assert(asCCMesh->hasPerTriangleTexCoordIndexes()); if (asCCMesh->hasPerTriangleTexCoordIndexes()) { unsigned triCount = asCCMesh->size(); lUVDiffuseElement->GetIndexArray().SetCount(static_cast<int>(3*triCount)); for (unsigned j=0; j<triCount; ++j) { int t1=0, t2=0, t3=0; asCCMesh->getTriangleTexCoordinatesIndexes(j, t1, t2, t3); lUVDiffuseElement->GetIndexArray().SetAt(j*3+0,t1); lUVDiffuseElement->GetIndexArray().SetAt(j*3+1,t2); lUVDiffuseElement->GetIndexArray().SetAt(j*3+2,t3); } } } //Textures used in this file QMap<QString,QString> texFilenames; //directory to save textures (if any) QFileInfo info(filename); QString textDirName = info.baseName() + QString(".fbm"); QDir baseDir = info.absoluteDir(); QDir texDir = QDir(baseDir.absolutePath() + QString("/") + textDirName); for (size_t i=0; i<matCount; ++i) { ccMaterial::CShared mat = matSet->at(i); FbxSurfacePhong *lMaterial = FbxSurfacePhong::Create(pScene, qPrintable(mat->getName())); const ccColor::Rgbaf& emission = mat->getEmission(); const ccColor::Rgbaf& ambient = mat->getAmbient(); const ccColor::Rgbaf& diffuse = mat->getDiffuseFront(); const ccColor::Rgbaf& specular = mat->getDiffuseFront(); lMaterial->Emissive.Set(FbxDouble3(emission.r,emission.g,emission.b)); lMaterial->Ambient .Set(FbxDouble3( ambient.r, ambient.g, ambient.b)); lMaterial->Diffuse .Set(FbxDouble3( diffuse.r, diffuse.g, diffuse.b)); lMaterial->Specular.Set(FbxDouble3(specular.r,specular.g,specular.b)); lMaterial->Shininess = mat->getShininessFront(); lMaterial->ShadingModel.Set("Phong"); if (hasTextures && mat->hasTexture()) { QString texFilename = mat->getTextureFilename(); //texture has not already been processed if (!texFilenames.contains(texFilename)) { //if necessary, we (try to) create a subfolder to store textures if (!texDir.exists()) { texDir = baseDir; if (texDir.mkdir(textDirName)) { texDir.cd(textDirName); } else { textDirName = QString(); ccLog::Warning("[FBX] Failed to create subfolder '%1' to store texture files (files will be stored next to the .fbx file)"); } } QFileInfo fileInfo(texFilename); QString baseTexName = fileInfo.fileName(); //add extension QString extension = QFileInfo(texFilename).suffix(); if (fileInfo.suffix().isEmpty()) baseTexName += QString(".png"); QString absoluteFilename = texDir.absolutePath() + QString("/") + baseTexName; ccLog::PrintDebug(QString("[FBX] Material '%1' texture: %2").arg(mat->getName()).arg(absoluteFilename)); texFilenames[texFilename] = absoluteFilename; } //mat.texture.save(absoluteFilename); // Set texture properties. FbxFileTexture* lTexture = FbxFileTexture::Create(pScene,"DiffuseTexture"); assert(!texFilenames[texFilename].isEmpty()); lTexture->SetFileName(qPrintable(texFilenames[texFilename])); lTexture->SetTextureUse(FbxTexture::eStandard); lTexture->SetMappingType(FbxTexture::eUV); lTexture->SetMaterialUse(FbxFileTexture::eModelMaterial); lTexture->SetSwapUV(false); lTexture->SetTranslation(0.0, 0.0); lTexture->SetScale(1.0, 1.0); lTexture->SetRotation(0.0, 0.0); lTexture->UVSet.Set(FbxString(gDiffuseElementName)); // Connect texture to the proper UV // don't forget to connect the texture to the corresponding property of the material lMaterial->Diffuse.ConnectSrcObject(lTexture); } int matIndex = lNode->AddMaterial(lMaterial); assert(matIndex == static_cast<int>(i)); } //don't forget to save the texture files { for (QMap<QString,QString>::ConstIterator it = texFilenames.begin(); it != texFilenames.end(); ++it) { const QImage image = ccMaterial::GetTexture(it.key()); image.mirrored().save(it.value()); } texFilenames.clear(); //don't need this anymore! } // Create 'triangle to material index' mapping { FbxGeometryElementMaterial* lMaterialElement = lMesh->CreateElementMaterial(); lMaterialElement->SetMappingMode(FbxGeometryElement::eByPolygon); lMaterialElement->SetReferenceMode(FbxGeometryElement::eIndexToDirect); } hasMaterial = true; } // colors if (cloud->hasColors()) { FbxGeometryElementVertexColor* lGeometryElementVertexColor = lMesh->CreateElementVertexColor(); lGeometryElementVertexColor->SetMappingMode(FbxGeometryElement::eByControlPoint); lGeometryElementVertexColor->SetReferenceMode(FbxGeometryElement::eDirect); lGeometryElementVertexColor->GetDirectArray().SetCount(vertCount); for (unsigned i=0; i<vertCount; ++i) { const colorType* C = cloud->getPointColor(i); FbxColor col( static_cast<double>(C[0])/ccColor::MAX, static_cast<double>(C[1])/ccColor::MAX, static_cast<double>(C[2])/ccColor::MAX ); lGeometryElementVertexColor->GetDirectArray().SetAt(i,col); } if (!hasMaterial) { //it seems that we have to create a fake material in order for the colors to be displayed (in Unity and FBX Review at least)! FbxSurfacePhong *lMaterial = FbxSurfacePhong::Create(pScene, "ColorMaterial"); lMaterial->Emissive.Set(FbxDouble3(0,0,0)); lMaterial->Ambient.Set(FbxDouble3(0,0,0)); lMaterial->Diffuse.Set(FbxDouble3(1,1,1)); lMaterial->Specular.Set(FbxDouble3(0,0,0)); lMaterial->Shininess = 0; lMaterial->ShadingModel.Set("Phong"); FbxGeometryElementMaterial* lMaterialElement = lMesh->CreateElementMaterial(); lMaterialElement->SetMappingMode(FbxGeometryElement::eAllSame); lMaterialElement->SetReferenceMode(FbxGeometryElement::eDirect); lNode->AddMaterial(lMaterial); } } // Create polygons { for (unsigned j=0; j<faceCount; ++j) { const CCLib::TriangleSummitsIndexes* tsi = mesh->getTriangleIndexes(j); int matIndex = hasMaterial ? asCCMesh->getTriangleMtlIndex(j) : -1; lMesh->BeginPolygon(matIndex); lMesh->AddPolygon(tsi->i1); lMesh->AddPolygon(tsi->i2); lMesh->AddPolygon(tsi->i3); lMesh->EndPolygon(); } } return lNode; }
//=============================================================================================================================== bool FBXLoader::LoadVertexNormal(FbxMesh* mesh, int inCtrlPointIndex, int inVertexCounter, int normalElement, XMFLOAT3& outNormal) { if (mesh->GetElementNormalCount() < 1) { throw std::exception("Invalid Normal Number"); } int directIndex = -1; FbxGeometryElementNormal* vertexNormal = mesh->GetElementNormal(normalElement); switch (vertexNormal->GetMappingMode()) { case FbxGeometryElement::eByControlPoint: { switch (vertexNormal->GetReferenceMode()) { case FbxGeometryElement::eDirect: { directIndex = inCtrlPointIndex; //outNormal.x = static_cast<float>(vertexNormal->GetDirectArray().GetAt(inCtrlPointIndex).mData[0]); //outNormal.y = static_cast<float>(vertexNormal->GetDirectArray().GetAt(inCtrlPointIndex).mData[1]); //outNormal.z = static_cast<float>(vertexNormal->GetDirectArray().GetAt(inCtrlPointIndex).mData[2]); } break; case FbxGeometryElement::eIndexToDirect: { directIndex = vertexNormal->GetIndexArray().GetAt(inCtrlPointIndex); //int index = vertexNormal->GetIndexArray().GetAt(inCtrlPointIndex); //outNormal.x = static_cast<float>(vertexNormal->GetDirectArray().GetAt(index).mData[0]); //outNormal.y = static_cast<float>(vertexNormal->GetDirectArray().GetAt(index).mData[1]); //outNormal.z = static_cast<float>(vertexNormal->GetDirectArray().GetAt(index).mData[2]); } break; default: throw std::exception("Invalid Reference"); } break; } break; case FbxGeometryElement::eByPolygonVertex: { switch (vertexNormal->GetReferenceMode()) { case FbxGeometryElement::eDirect: { directIndex = inVertexCounter; //outNormal.x = static_cast<float>(vertexNormal->GetDirectArray().GetAt(inVertexCounter).mData[0]); //outNormal.y = static_cast<float>(vertexNormal->GetDirectArray().GetAt(inVertexCounter).mData[1]); //outNormal.z = static_cast<float>(vertexNormal->GetDirectArray().GetAt(inVertexCounter).mData[2]); } break; case FbxGeometryElement::eIndexToDirect: { directIndex = vertexNormal->GetIndexArray().GetAt(inVertexCounter); //int index = vertexNormal->GetIndexArray().GetAt(inVertexCounter); //outNormal.x = static_cast<float>(vertexNormal->GetDirectArray().GetAt(index).mData[0]); //outNormal.y = static_cast<float>(vertexNormal->GetDirectArray().GetAt(index).mData[1]); //outNormal.z = static_cast<float>(vertexNormal->GetDirectArray().GetAt(index).mData[2]); } break; default: throw std::exception("Invalid Reference"); } } break; } if (directIndex != -1) { FbxVector4 norm = vertexNormal->GetDirectArray().GetAt(directIndex); outNormal = XMFLOAT3((float)norm.mData[0], (float)norm.mData[1], (float)norm.mData[2]); return true; } return false; }
void ExportFbxMesh(const Value& obj) { string name = obj["Name"].GetString(); FbxNode* pNode = FbxNode::Create(pManager, name.c_str()); FbxMesh* pMesh = FbxMesh::Create(pManager, name.c_str()); pNode->AddNodeAttribute(pMesh); pScene->GetRootNode()->AddChild(pNode); int numVertex = obj["NumVertex"].GetInt(); { pMesh->InitControlPoints(numVertex); FbxVector4* lControlPoints = pMesh->GetControlPoints(); const Value& pos = obj["Position"]; for (int i = 0; i < numVertex; i++) { double x = pos[i * 3 + 0].GetDouble(); x = -x; double y = pos[i * 3 + 1].GetDouble(); double z = pos[i * 3 + 2].GetDouble(); lControlPoints[i] = FbxVector4(x, y, z); } } { FbxGeometryElementNormal* lGeometryElementNormal = pMesh->CreateElementNormal(); lGeometryElementNormal->SetMappingMode(FbxGeometryElement::eByControlPoint); lGeometryElementNormal->SetReferenceMode(FbxGeometryElement::eDirect); FbxLayerElementArrayTemplate<FbxVector4>& array = lGeometryElementNormal->GetDirectArray(); const Value& normal = obj["Normal"]; for (int i = 0; i < numVertex; i++) { double x = normal[i * 3 + 0].GetDouble(); x = -x; double y = normal[i * 3 + 1].GetDouble(); double z = normal[i * 3 + 2].GetDouble(); array.Add(FbxVector4(x, y, z)); } } { FbxGeometryElementUV* lUVDiffuseElement = pMesh->CreateElementUV("DiffuseUV"); FBX_ASSERT(lUVDiffuseElement != NULL); lUVDiffuseElement->SetMappingMode(FbxGeometryElement::eByControlPoint); lUVDiffuseElement->SetReferenceMode(FbxGeometryElement::eDirect); FbxLayerElementArrayTemplate<FbxVector2>& array = lUVDiffuseElement->GetDirectArray(); const Value& v = obj["UV0"]; for (int i = 0; i < numVertex; i++) { double x = v[i * 2 + 0].GetDouble(); double y = v[i * 2 + 1].GetDouble(); array.Add(FbxVector2(x, y)); } } { const Value& color = obj["Color"]; if (!color.IsNull()) { FbxGeometryElementVertexColor* pColorElement = pMesh->CreateElementVertexColor(); FBX_ASSERT(pColorElement != NULL); pColorElement->SetMappingMode(FbxGeometryElement::eByControlPoint); pColorElement->SetReferenceMode(FbxGeometryElement::eDirect); FbxLayerElementArrayTemplate<FbxColor>& array = pColorElement->GetDirectArray(); for (int i = 0; i < numVertex; i++) { double r = color[i * 4 + 0].GetDouble(); double g = color[i * 4 + 1].GetDouble(); double b = color[i * 4 + 2].GetDouble(); double a = color[i * 4 + 3].GetDouble(); array.Add(FbxColor(r, g, b, a)); } } } { const Value& Indeices = obj["Indeices"]; for (uint32_t subMesh = 0; subMesh < Indeices.Size(); subMesh++) { const Value& index0 = Indeices[subMesh]; int numIndex = index0.Size(); printf("index %d\n", numIndex); for (int i = 0; i < numIndex / 3; i++) { pMesh->BeginPolygon(-1, -1, subMesh); int index[3] = { index0[i * 3 + 0].GetInt(), index0[i * 3 + 1].GetInt(), index0[i * 3 + 2].GetInt(), }; pMesh->AddPolygon(index[0]); pMesh->AddPolygon(index[2]); pMesh->AddPolygon(index[1]); pMesh->EndPolygon(); } } } ////////////////////////////////////////////////////////////////////////// // export skin const Value& boneIndex = obj["BoneIndex"]; if (!boneIndex.IsNull()) { if (fbxBones.empty()) { printf("no bones, can not export skin"); return; } const Value& boneWeight = obj["BoneWeight"]; vector<FbxCluster*> clusters(fbxBones.size(), NULL); for (uint32_t i = 0; i < fbxBones.size(); i++) { FbxCluster* pCluster = FbxCluster::Create(pScene, ""); pCluster->SetLink(fbxBones[i]); pCluster->SetLinkMode(FbxCluster::eTotalOne); clusters[i] = pCluster; } for (int i = 0; i < numVertex; i++) { for (int j = 0; j < 4; j++) { int bone = boneIndex[i * 4 + j].GetInt(); double weight = boneWeight[i * 4 + j].GetDouble(); clusters[bone]->AddControlPointIndex(i, weight); } } FbxSkin* lSkin = FbxSkin::Create(pScene, ""); FbxScene* p = pNode->GetScene(); FbxAMatrix modelMatrix = pNode->EvaluateGlobalTransform(); for (uint32_t i = 0; i < clusters.size(); i++) { clusters[i]->SetTransformMatrix(modelMatrix); FbxAMatrix boneMatrix = fbxBones[i]->EvaluateGlobalTransform(); clusters[i]->SetTransformLinkMatrix(boneMatrix); lSkin->AddCluster(clusters[i]); } pMesh->AddDeformer(lSkin); } }
//-------------------------------------------------------------------------- void SaveMesh(FbxNode* pNode, const VeDirectoryPtr& spDest) noexcept { Mesh kMesh; FbxMesh* pMesh = (FbxMesh*)pNode->GetNodeAttribute(); kMesh.m_kName = pNode->GetName(); kMesh.m_stFaces = pMesh->GetPolygonCount(); kMesh.m_stVerts = kMesh.m_stFaces * 3; kMesh.m_kIndices.resize(kMesh.m_stVerts); kMesh.m_kPosition.resize(kMesh.m_stVerts); kMesh.m_kNormals.resize(pMesh->GetElementNormalCount()); for (auto& v : kMesh.m_kNormals) { v.resize(kMesh.m_stVerts); } kMesh.m_kTexcoords.resize(pMesh->GetElementUVCount()); for (auto& v : kMesh.m_kTexcoords) { v.resize(kMesh.m_stVerts); } kMesh.m_kColors.resize(pMesh->GetElementVertexColorCount()); for (auto& v : kMesh.m_kColors) { v.resize(kMesh.m_stVerts); } int element_mat = -1; for (int i(0); i < pMesh->GetElementMaterialCount(); ++i) { FbxGeometryElementMaterial* lMaterialElement = pMesh->GetElementMaterial(i); if (lMaterialElement->GetMappingMode() == FbxGeometryElement::eByPolygon) { element_mat = i; break; } } if (element_mat >= 0) { kMesh.m_kAttributes.resize(kMesh.m_stFaces); } FbxVector4* lControlPoints = pMesh->GetControlPoints(); for (int i(0); i < (int)(kMesh.m_stFaces); ++i) { int lPolygonSize = pMesh->GetPolygonSize(i); VE_ASSERT_ALWAYS(lPolygonSize == 3); for (int j(0); j < lPolygonSize; ++j) { uint32_t u32Index = i * 3 + j; kMesh.m_kIndices[u32Index] = u32Index; int lControlPointIndex = pMesh->GetPolygonVertex(i, j); auto& pos = kMesh.m_kPosition[u32Index]; pos.x = (float)lControlPoints[lControlPointIndex][0]; pos.y = (float)lControlPoints[lControlPointIndex][1]; pos.z = (float)lControlPoints[lControlPointIndex][2]; for (int k(0); k < (int)(kMesh.m_kColors.size()); ++k) { FbxColor c; FbxGeometryElementVertexColor* leVtxc = pMesh->GetElementVertexColor(k); switch (leVtxc->GetMappingMode()) { default: break; case FbxGeometryElement::eByControlPoint: switch (leVtxc->GetReferenceMode()) { case FbxGeometryElement::eDirect: c = leVtxc->GetDirectArray().GetAt(lControlPointIndex); break; case FbxGeometryElement::eIndexToDirect: { int id = leVtxc->GetIndexArray().GetAt(lControlPointIndex); c = leVtxc->GetDirectArray().GetAt(id); } break; default: break; // other reference modes not shown here! } break; case FbxGeometryElement::eByPolygonVertex: { switch (leVtxc->GetReferenceMode()) { case FbxGeometryElement::eDirect: c = leVtxc->GetDirectArray().GetAt(u32Index); break; case FbxGeometryElement::eIndexToDirect: { int id = leVtxc->GetIndexArray().GetAt(u32Index); c = leVtxc->GetDirectArray().GetAt(id); } break; default: break; // other reference modes not shown here! } } break; case FbxGeometryElement::eByPolygon: // doesn't make much sense for UVs case FbxGeometryElement::eAllSame: // doesn't make much sense for UVs case FbxGeometryElement::eNone: // doesn't make much sense for UVs break; } auto& color = kMesh.m_kColors[k][u32Index]; color.x = (float)c[0]; color.y = (float)c[1]; color.z = (float)c[2]; color.w = (float)c[3]; } for (int k(0); k < (int)(kMesh.m_kTexcoords.size()); ++k) { FbxVector2 uv; FbxGeometryElementUV* leUV = pMesh->GetElementUV(k); switch (leUV->GetMappingMode()) { default: break; case FbxGeometryElement::eByControlPoint: switch (leUV->GetReferenceMode()) { case FbxGeometryElement::eDirect: uv = leUV->GetDirectArray().GetAt(lControlPointIndex); break; case FbxGeometryElement::eIndexToDirect: { int id = leUV->GetIndexArray().GetAt(lControlPointIndex); uv = leUV->GetDirectArray().GetAt(id); } break; default: break; // other reference modes not shown here! } break; case FbxGeometryElement::eByPolygonVertex: { int lTextureUVIndex = pMesh->GetTextureUVIndex(i, j); switch (leUV->GetReferenceMode()) { case FbxGeometryElement::eDirect: case FbxGeometryElement::eIndexToDirect: { uv = leUV->GetDirectArray().GetAt(lTextureUVIndex); } break; default: break; // other reference modes not shown here! } } break; case FbxGeometryElement::eByPolygon: // doesn't make much sense for UVs case FbxGeometryElement::eAllSame: // doesn't make much sense for UVs case FbxGeometryElement::eNone: // doesn't make much sense for UVs break; } auto& texcoord = kMesh.m_kTexcoords[k][u32Index]; texcoord.x = (float)uv[0]; texcoord.y = (float)uv[1]; } for (int k(0); k < (int)(kMesh.m_kNormals.size()); ++k) { FbxVector4 n; FbxGeometryElementNormal* leNormal = pMesh->GetElementNormal(k); if (leNormal->GetMappingMode() == FbxGeometryElement::eByPolygonVertex) { switch (leNormal->GetReferenceMode()) { case FbxGeometryElement::eDirect: n = leNormal->GetDirectArray().GetAt(u32Index); break; case FbxGeometryElement::eIndexToDirect: { int id = leNormal->GetIndexArray().GetAt(u32Index); n = leNormal->GetDirectArray().GetAt(id); } break; default: break; // other reference modes not shown here! } } auto& normal = kMesh.m_kNormals[k][u32Index]; normal.x = (float)n[0]; normal.y = (float)n[1]; normal.z = (float)n[2]; } if (element_mat >= 0) { FbxGeometryElementMaterial* lMaterialElement = pMesh->GetElementMaterial(element_mat); FbxSurfaceMaterial* lMaterial = NULL; int lMatId = -1; lMaterial = pMesh->GetNode()->GetMaterial(lMaterialElement->GetIndexArray().GetAt(i)); lMatId = lMaterialElement->GetIndexArray().GetAt(i); kMesh.m_kAttributes[i] = lMatId; } } } kMesh.Process(); kMesh.Save(spDest); }