Esempio n. 1
0
BOOL MeshExpUtility::BuildObject(CEditableObject*& exp_obj, LPCSTR m_ExportName)
{
	bool bResult = true;

	if (m_ExportName[0]==0) return false;

	ELog.Msg(mtInformation,"Building object..." );
	char fname[256]; _splitpath( m_ExportName, 0, 0, fname, 0 );
	exp_obj = xr_new<CEditableObject>(fname);	
	exp_obj->SetVersionToCurrent(TRUE,TRUE);

	ExportItemIt it = m_Items.begin();
	for(;it!=m_Items.end();it++){
		CEditableMesh *submesh = xr_new<CEditableMesh>(exp_obj);
		ELog.Msg(mtInformation,"Converting node '%s'...", it->pNode->GetName());
		if( submesh->Convert(it->pNode) ){
			// transform
			Matrix3 mMatrix;
			mMatrix = it->pNode->GetNodeTM(0)*Inverse(it->pNode->GetParentNode()->GetNodeTM(0));

			Point3	r1	= mMatrix.GetRow(0);
			Point3	r2	= mMatrix.GetRow(1);
			Point3	r3	= mMatrix.GetRow(2);
			Point3	r4	= mMatrix.GetRow(3);
			Fmatrix m;	m.identity();
			m.i.set(r1.x, r1.z, r1.y);
			m.j.set(r2.x, r2.z, r2.y);
			m.k.set(r3.x, r3.z, r3.y);
			m.c.set(r4.x, r4.z, r4.y);
			
			submesh->Transform( m );
			// flip faces
			Fvector v; v.crossproduct(m.j, m.k);
			if(v.dotproduct(m.i)<0.f)	submesh->FlipFaces();
			if(m_ObjectFlipFaces)		submesh->FlipFaces();
			submesh->RecomputeBBox();
			// append mesh
			submesh->SetName			(it->pNode->GetName());
			exp_obj->m_Meshes.push_back	(submesh);
		}else{
			ELog.Msg(mtError,"! can't convert", it->pNode->GetName());
			xr_delete(submesh);
			bResult = false;
			break;
		}
	}

	if (bResult){
		exp_obj->UpdateBox		();
		exp_obj->VerifyMeshNames();
		ELog.Msg				(mtInformation,"Object '%s' contains: %d points, %d faces",
								exp_obj->GetName(), exp_obj->GetVertexCount(), exp_obj->GetFaceCount());
	}else{
		xr_delete(exp_obj);
	}
//-------------------------------------------------------------------
	return bResult;
}
Esempio n. 2
0
MStatus CXRayObjectExport::ExportPart(CEditableObject* O, MDagPath& mdagPath, MObject&  mComponent)
{
	MStatus stat = MS::kSuccess;
	MSpace::Space space = MSpace::kWorld;

	MFnMesh fnMesh( mdagPath, &stat );
	if ( MS::kSuccess != stat) {
		fprintf(stderr,"Failure in MFnMesh initialization.\n");
		return MS::kFailure;
	}

	MString mdagPathNodeName = fnMesh.name();

	MFnDagNode dagNode1(mdagPath);
	u32 pc = dagNode1.parentCount();
	for(u32 ip=0;ip<pc;++ip)
	{
		MObject object_parent = dagNode1.parent(ip, &stat);
		if(object_parent.hasFn(MFn::kTransform))
		{
			MFnTransform parent_transform(object_parent,&stat);
	
			if ( MS::kSuccess == stat) 
			{
				mdagPathNodeName = parent_transform.name();
				break;
			}
		}
	}

	MItMeshPolygon meshPoly( mdagPath, mComponent, &stat );
	if ( MS::kSuccess != stat) {
		fprintf(stderr,"Failure in MItMeshPolygon initialization.\n");
		return MS::kFailure;
	}

	MItMeshVertex vtxIter( mdagPath, mComponent, &stat );
	if ( MS::kSuccess != stat) {
		fprintf(stderr,"Failure in MItMeshVertex initialization.\n");
		return MS::kFailure;
	}

	// If the shape is instanced then we need to determine which
	// instance this path refers to.
	//
	int instanceNum = 0;
	if (mdagPath.isInstanced())
		instanceNum = mdagPath.instanceNumber();

	// Get a list of all shaders attached to this mesh
	MObjectArray rgShaders;
	MIntArray texMap;
	MStatus status;
	status = fnMesh.getConnectedShaders (instanceNum, rgShaders, texMap);
	if (status == MStatus::kFailure)
	{
		Log("! Unable to load shaders for mesh");
		return (MStatus::kFailure);
	}

	XRShaderDataVec xr_data;
	{
		for ( int i=0; i<(int)rgShaders.length(); i++ ) {
			MObject shader = rgShaders[i];

			xr_data.push_back(SXRShaderData());
			SXRShaderData& D = xr_data.back();

			status = parseShader(shader, D);
			if (status == MStatus::kFailure) {
				status.perror ("Unable to retrieve filename of texture");
				continue;
			}
		}
	}

	CEditableMesh* MESH = new CEditableMesh(O);
	MESH->SetName(mdagPathNodeName.asChar());
	O->AppendMesh(MESH);

	int objectIdx, length;

	// Find i such that objectGroupsTablePtr[i] corresponds to the
	// object node pointed to by mdagPath
	length = objectNodeNamesArray.length();
	{
		for( int i=0; i<length; i++ ) {
			if( objectNodeNamesArray[i] == mdagPathNodeName ) {
				objectIdx = i;
				break;
			}
		}
	}
	// Reserve uv table
	{
		VMapVec& _vmaps	= MESH->m_VMaps;
		_vmaps.resize	(1);
		st_VMap*& VM	= _vmaps.back();
		VM				= new st_VMap("Texture",vmtUV,false);
	}

	// write faces
	{
		using FaceVec = xr_vector<st_Face>;
		using FaceIt = FaceVec::iterator;

		VMapVec& _vmaps			= MESH->m_VMaps;
		SurfFaces& _surf_faces	= MESH->m_SurfFaces;
		VMRefsVec& _vmrefs		= MESH->m_VMRefs;
		
		// temp variables
		FvectorVec	_points;
		FaceVec _faces;
		U32Vec _sgs;

		int f_cnt				= fnMesh.numPolygons();

		_sgs.reserve	(f_cnt);
		_faces.reserve	(f_cnt);
		_vmrefs.reserve	(f_cnt*3);

//		int lastSmoothingGroup = INITIALIZE_SMOOTHING;
		MPointArray rgpt;
		MIntArray rgint;

		PtLookupMap ptMap;
		CSurface* surf	= 0;
		for ( ; !meshPoly.isDone(); meshPoly.next()){
			// Write out the smoothing group that this polygon belongs to
			// We only write out the smoothing group if it is different
			// from the last polygon.
			//
			int compIdx	= meshPoly.index();
			int smoothingGroup = polySmoothingGroups[ compIdx ];
			// for each polygon, first setup the reverse mapping
			// between object-relative vertex indices and face-relative
			// vertex indices
			ptMap.clear();
			for (int i=0; i<(int)meshPoly.polygonVertexCount(); i++)
				ptMap.insert (PtLookupMap::value_type(meshPoly.vertexIndex(i), i) );

			// verify polygon zero area
			if (meshPoly.zeroArea()){
				status = MS::kFailure;
				Log("! polygon have zero area:",meshPoly.index());
				return status;
			}

			// verify polygon zero UV area
/*			if (meshPoly.zeroUVArea()){
				status = MS::kFailure;
				Log("! polygon have zero UV area:",meshPoly.index());
				return status;
			}
*/
			// verify polygon has UV information
			if (!meshPoly.hasUVs (&status)) {
				status = MS::kFailure;
				Log("! polygon is missing UV information:",meshPoly.index());
				return status;
			}

			int cTri;
			// now iterate through each triangle on this polygon and create a triangle object in our list
			status = meshPoly.numTriangles (cTri);	
			if (!status) {
				Log("! can't getting triangle count");
				return status;
			}

			for (int i=0; i < cTri; i++) {

				// for each triangle, first get the triangle data
				rgpt.clear();//triangle vertices
				rgint.clear();//triangle vertex indices 

				// triangles that come from object are retrieved in world space
				status = meshPoly.getTriangle (i, rgpt, rgint, MSpace::kWorld);

				if (!status) {
					Log("! can't getting triangle for mesh poly");
					return status;
				}

				if ((rgpt.length() != 3) || (rgint.length() != 3)) {
					Msg("! 3 points not returned for triangle");
					return MS::kFailure;
				}

				// Write out vertex/uv index information
				//
				R_ASSERT2(fnMesh.numUVs()>0,"Can't find uvmaps.");
				_faces.push_back(st_Face());
				_sgs.push_back(smoothingGroup);
				//set_smooth
				set_smoth_flags( _sgs.back(), rgint );

				st_Face& f_it		= _faces.back();
				for ( int vtx=0; vtx<3; vtx++ ) {
					// get face-relative vertex
					PtLookupMap::iterator mapIt;

					int vtLocal, vtUV;
					int vt = rgint[vtx];
					mapIt = ptMap.find(vt);
					Fvector2 uv;
					if (mapIt == ptMap.end()){
						Msg("! Can't find local index.");
						return MS::kFailure;
					}
					vtLocal = (*mapIt).second;

					status = meshPoly.getUVIndex (vtLocal, vtUV, uv.x, uv.y); 
					if (!status) {
						Msg("! error getting UV Index for local vertex '%d' and object vertex '%d'",vtLocal,vt);
						return status;
					}

					// flip v-part 
					uv.y=1.f-uv.y;

					f_it.pv[2-vtx].pindex	= AppendVertex(_points,rgpt[vtx]);
					f_it.pv[2-vtx].vmref	= _vmrefs.size();
					_vmrefs.push_back		(st_VMapPtLst());
					st_VMapPtLst& vm_lst	= _vmrefs.back();
					vm_lst.count			= 1;
					vm_lst.pts				= xr_alloc<st_VMapPt>(vm_lst.count);
					vm_lst.pts[0].vmap_index= 0;
					vm_lst.pts[0].index 	= AppendUV(_vmaps.back(),uv);
				}
				// out face material
				int iTexture	= texMap[meshPoly.index()];
				if (iTexture<0)
					xrDebug::Fatal(DEBUG_INFO,"Can't find material for polygon: %d",meshPoly.index());
				SXRShaderData& D= xr_data[iTexture];

				int compIdx = meshPoly.index();
				surf		= MESH->Parent()->CreateSurface(getMaterialName(mdagPath, compIdx, objectIdx),D);
				if (!surf)	return MStatus::kFailure;	
				_surf_faces[surf].push_back(_faces.size()-1);
			}
		}
		{
			// copy from temp
			MESH->m_VertCount	= _points.size();
			MESH->m_FaceCount	= _faces.size();
			MESH->m_Vertices	= xr_alloc<Fvector>(MESH->m_VertCount);
			Memory.mem_copy		(MESH->m_Vertices,&*_points.begin(),MESH->m_VertCount*sizeof(Fvector));
			MESH->m_Faces		= xr_alloc<st_Face>(MESH->m_FaceCount);
			Memory.mem_copy		(MESH->m_Faces,&*_faces.begin(),MESH->m_FaceCount*sizeof(st_Face));
			MESH->m_SmoothGroups = xr_alloc<u32>(MESH->m_FaceCount);
			Memory.mem_copy		(MESH->m_SmoothGroups,&*_sgs.begin(),MESH->m_FaceCount*sizeof(u32));

			MESH->RecomputeBBox	();
		}
		if ((MESH->GetVertexCount()<4)||(MESH->GetFaceCount()<2))
		{
			Log		("! Invalid mesh: '%s'. Faces<2 or Verts<4",*MESH->Name());
			return MS::kFailure;
		}
	}
	return stat;
}