void mitk::UnstructuredGridMapper2D::Paint( mitk::BaseRenderer* renderer ) { if ( IsVisible( renderer ) == false ) return ; vtkLinearTransform * vtktransform = GetDataNode()->GetVtkTransform(); vtkLinearTransform * inversetransform = vtktransform->GetLinearInverse(); Geometry2D::ConstPointer worldGeometry = renderer->GetCurrentWorldGeometry2D(); PlaneGeometry::ConstPointer worldPlaneGeometry = dynamic_cast<const PlaneGeometry*>( worldGeometry.GetPointer() ); Point3D point; Vector3D normal; if(worldPlaneGeometry.IsNotNull()) { // set up vtkPlane according to worldGeometry point=worldPlaneGeometry->GetOrigin(); normal=worldPlaneGeometry->GetNormal(); normal.Normalize(); m_Plane->SetTransform((vtkAbstractTransform*)NULL); } else { //@FIXME: does not work correctly. Does m_Plane->SetTransform really transforms a "plane plane" into a "curved plane"? return; AbstractTransformGeometry::ConstPointer worldAbstractGeometry = dynamic_cast<const AbstractTransformGeometry*>(renderer->GetCurrentWorldGeometry2D()); if(worldAbstractGeometry.IsNotNull()) { // set up vtkPlane according to worldGeometry point=const_cast<mitk::BoundingBox*>(worldAbstractGeometry->GetParametricBoundingBox())->GetMinimum(); FillVector3D(normal, 0, 0, 1); m_Plane->SetTransform(worldAbstractGeometry->GetVtkAbstractTransform()->GetInverse()); } else return; } vtkFloatingPointType vp[ 3 ], vnormal[ 3 ]; vnl2vtk(point.Get_vnl_vector(), vp); vnl2vtk(normal.Get_vnl_vector(), vnormal); //normally, we would need to transform the surface and cut the transformed surface with the cutter. //This might be quite slow. Thus, the idea is, to perform an inverse transform of the plane instead. //@todo It probably does not work for scaling operations yet:scaling operations have to be //dealed with after the cut is performed by scaling the contour. inversetransform->TransformPoint( vp, vp ); inversetransform->TransformNormalAtPoint( vp, vnormal, vnormal ); m_Plane->SetOrigin( vp ); m_Plane->SetNormal( vnormal ); // set data into cutter m_Slicer->SetInput( m_VtkPointSet ); // m_Cutter->GenerateCutScalarsOff(); // m_Cutter->SetSortByToSortByCell(); // calculate the cut m_Slicer->Update(); // fetch geometry mitk::DisplayGeometry::Pointer displayGeometry = renderer->GetDisplayGeometry(); assert( displayGeometry ); // float toGL=displayGeometry->GetSizeInDisplayUnits()[1]; //apply color and opacity read from the PropertyList ApplyProperties( renderer ); // traverse the cut contour vtkPolyData * contour = m_Slicer->GetOutput(); vtkPoints *vpoints = contour->GetPoints(); vtkCellArray *vlines = contour->GetLines(); vtkCellArray *vpolys = contour->GetPolys(); vtkPointData *vpointdata = contour->GetPointData(); vtkDataArray* vscalars = vpointdata->GetScalars(); vtkCellData *vcelldata = contour->GetCellData(); vtkDataArray* vcellscalars = vcelldata->GetScalars(); const int numberOfLines = contour->GetNumberOfLines(); const int numberOfPolys = contour->GetNumberOfPolys(); const bool useCellData = m_ScalarMode->GetVtkScalarMode() == VTK_SCALAR_MODE_DEFAULT || m_ScalarMode->GetVtkScalarMode() == VTK_SCALAR_MODE_USE_CELL_DATA; const bool usePointData = m_ScalarMode->GetVtkScalarMode() == VTK_SCALAR_MODE_USE_POINT_DATA; Point3D p; Point2D p2d; vlines->InitTraversal(); vpolys->InitTraversal(); mitk::Color outlineColor = m_Color->GetColor(); glLineWidth((float)m_LineWidth->GetValue()); for (int i = 0;i < numberOfLines;++i ) { vtkIdType *cell(0); vtkIdType cellSize(0); vlines->GetNextCell( cellSize, cell ); float rgba[4] = {outlineColor[0], outlineColor[1], outlineColor[2], 1.0f}; if (m_ScalarVisibility->GetValue() && vcellscalars) { if ( useCellData ) { // color each cell according to cell data double scalar = vcellscalars->GetComponent( i, 0 ); double rgb[3] = { 1.0f, 1.0f, 1.0f }; m_ScalarsToColors->GetColor(scalar, rgb); rgba[0] = (float)rgb[0]; rgba[1] = (float)rgb[1]; rgba[2] = (float)rgb[2]; rgba[3] = (float)m_ScalarsToOpacity->GetValue(scalar); } else if ( usePointData ) { double scalar = vscalars->GetComponent( i, 0 ); double rgb[3] = { 1.0f, 1.0f, 1.0f }; m_ScalarsToColors->GetColor(scalar, rgb); rgba[0] = (float)rgb[0]; rgba[1] = (float)rgb[1]; rgba[2] = (float)rgb[2]; rgba[3] = (float)m_ScalarsToOpacity->GetValue(scalar); } } glColor4fv( rgba ); glBegin ( GL_LINE_LOOP ); for ( int j = 0;j < cellSize;++j ) { vpoints->GetPoint( cell[ j ], vp ); //take transformation via vtktransform into account vtktransform->TransformPoint( vp, vp ); vtk2itk( vp, p ); //convert 3D point (in mm) to 2D point on slice (also in mm) worldGeometry->Map( p, p2d ); //convert point (until now mm and in worldcoordinates) to display coordinates (units ) displayGeometry->WorldToDisplay( p2d, p2d ); //convert display coordinates ( (0,0) is top-left ) in GL coordinates ( (0,0) is bottom-left ) //p2d[1]=toGL-p2d[1]; //add the current vertex to the line glVertex2f( p2d[0], p2d[1] ); } glEnd (); } bool polyOutline = m_Outline->GetValue(); bool scalarVisibility = m_ScalarVisibility->GetValue(); // only draw polygons if there are cell scalars // or the outline property is set to true if ((scalarVisibility && vcellscalars) || polyOutline) { glEnable(GL_BLEND); glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA); glPolygonMode(GL_FRONT_AND_BACK, GL_FILL); // cache the transformed points // a fixed size array is way faster than 'new' // slices through 3d cells usually do not generated // polygons with more than 6 vertices Point2D cachedPoints[10]; for (int i = 0;i < numberOfPolys;++i ) { vtkIdType *cell(0); vtkIdType cellSize(0); vpolys->GetNextCell( cellSize, cell ); float rgba[4] = {1.0f, 1.0f, 1.0f, 0}; if (scalarVisibility && vcellscalars) { if ( useCellData ) { // color each cell according to cell data double scalar = vcellscalars->GetComponent( i, 0 ); double rgb[3] = { 1.0f, 1.0f, 1.0f }; m_ScalarsToColors->GetColor(scalar, rgb); rgba[0] = (float)rgb[0]; rgba[1] = (float)rgb[1]; rgba[2] = (float)rgb[2]; rgba[3] = (float)m_ScalarsToOpacity->GetValue(scalar); } else if ( usePointData ) { double scalar = vscalars->GetComponent( i, 0 ); double rgb[3] = { 1.0f, 1.0f, 1.0f }; m_ScalarsToColors->GetColor(scalar, rgb); rgba[0] = (float)rgb[0]; rgba[1] = (float)rgb[1]; rgba[2] = (float)rgb[2]; rgba[3] = (float)m_ScalarsToOpacity->GetValue(scalar); } } glColor4fv( rgba ); glBegin( GL_POLYGON ); for (int j = 0; j < cellSize; ++j) { vpoints->GetPoint( cell[ j ], vp ); //take transformation via vtktransform into account vtktransform->TransformPoint( vp, vp ); vtk2itk( vp, p ); //convert 3D point (in mm) to 2D point on slice (also in mm) worldGeometry->Map( p, p2d ); //convert point (until now mm and in worldcoordinates) to display coordinates (units ) displayGeometry->WorldToDisplay( p2d, p2d ); //convert display coordinates ( (0,0) is top-left ) in GL coordinates ( (0,0) is bottom-left ) //p2d[1]=toGL-p2d[1]; cachedPoints[j][0] = p2d[0]; cachedPoints[j][1] = p2d[1]; //add the current vertex to the line glVertex2f( p2d[0], p2d[1] ); } glEnd(); if (polyOutline) { glColor4f(outlineColor[0], outlineColor[1], outlineColor[2], 1.0f); glPolygonMode(GL_FRONT_AND_BACK, GL_LINE); glBegin( GL_POLYGON ); //glPolygonOffset(1.0, 1.0); for (int j = 0; j < cellSize; ++j) { //add the current vertex to the line glVertex2f( cachedPoints[j][0], cachedPoints[j][1] ); } glEnd(); } } glDisable(GL_BLEND); } }
void mitk::VectorImageMapper2D::Paint( mitk::BaseRenderer * renderer ) { //std::cout << "2d vector mapping..." << std::endl; bool visible = true; GetDataNode()->GetVisibility(visible, renderer, "visible"); if ( !visible ) return ; mitk::Image::Pointer input = const_cast<mitk::Image*>( this->GetInput() ); if ( input.IsNull() ) return ; mitk::PlaneGeometry::Pointer worldPlaneGeometry2D = dynamic_cast< mitk::PlaneGeometry*>( const_cast<mitk::Geometry2D*>( renderer->GetCurrentWorldGeometry2D() ) ); assert( worldPlaneGeometry2D.IsNotNull() ); vtkImageData* vtkImage = input->GetVtkImageData( this->GetCurrentTimeStep( input, renderer ) ); // // set up the cutter orientation according to the current geometry of // the renderers plane // Point3D point; Vector3D normal; Geometry2D::ConstPointer worldGeometry = renderer->GetCurrentWorldGeometry2D(); PlaneGeometry::ConstPointer worldPlaneGeometry = dynamic_cast<const PlaneGeometry*>( worldGeometry.GetPointer() ); if ( worldPlaneGeometry.IsNotNull() ) { // set up vtkPlane according to worldGeometry point = worldPlaneGeometry->GetOrigin(); normal = worldPlaneGeometry->GetNormal(); normal.Normalize(); m_Plane->SetTransform( (vtkAbstractTransform*)NULL ); } else { itkWarningMacro( << "worldPlaneGeometry is NULL!" ); return ; } double vp[ 3 ], vp_slice[ 3 ], vnormal[ 3 ]; vnl2vtk( point.GetVnlVector(), vp ); vnl2vtk( normal.GetVnlVector(), vnormal ); //std::cout << "Origin: " << vp[0] <<" "<< vp[1] <<" "<< vp[2] << std::endl; //std::cout << "Normal: " << vnormal[0] <<" "<< vnormal[1] <<" "<< vnormal[2] << std::endl; //normally, we would need to transform the surface and cut the transformed surface with the cutter. //This might be quite slow. Thus, the idea is, to perform an inverse transform of the plane instead. //@todo It probably does not work for scaling operations yet:scaling operations have to be //dealed with after the cut is performed by scaling the contour. vtkLinearTransform * vtktransform = GetDataNode() ->GetVtkTransform(); vtkTransform* world2vtk = vtkTransform::New(); world2vtk->Identity(); world2vtk->Concatenate(vtktransform->GetLinearInverse()); double myscale[3]; world2vtk->GetScale(myscale); world2vtk->PostMultiply(); world2vtk->Scale(1/myscale[0],1/myscale[1],1/myscale[2]); world2vtk->TransformPoint( vp, vp ); world2vtk->TransformNormalAtPoint( vp, vnormal, vnormal ); world2vtk->Delete(); // vtk works in axis align coords // thus the normal also must be axis align, since // we do not allow arbitrary cutting through volume // // vnormal should already be axis align, but in order // to get rid of precision effects, we set the two smaller // components to zero here int dims[3]; vtkImage->GetDimensions(dims); double spac[3]; vtkImage->GetSpacing(spac); vp_slice[0] = vp[0]; vp_slice[1] = vp[1]; vp_slice[2] = vp[2]; if(fabs(vnormal[0]) > fabs(vnormal[1]) && fabs(vnormal[0]) > fabs(vnormal[2]) ) { if(fabs(vp_slice[0]/spac[0]) < 0.4) vp_slice[0] = 0.4*spac[0]; if(fabs(vp_slice[0]/spac[0]) > (dims[0]-1)-0.4) vp_slice[0] = ((dims[0]-1)-0.4)*spac[0]; vnormal[1] = 0; vnormal[2] = 0; } if(fabs(vnormal[1]) > fabs(vnormal[0]) && fabs(vnormal[1]) > fabs(vnormal[2]) ) { if(fabs(vp_slice[1]/spac[1]) < 0.4) vp_slice[1] = 0.4*spac[1]; if(fabs(vp_slice[1]/spac[1]) > (dims[1]-1)-0.4) vp_slice[1] = ((dims[1]-1)-0.4)*spac[1]; vnormal[0] = 0; vnormal[2] = 0; } if(fabs(vnormal[2]) > fabs(vnormal[1]) && fabs(vnormal[2]) > fabs(vnormal[0]) ) { if(fabs(vp_slice[2]/spac[2]) < 0.4) vp_slice[2] = 0.4*spac[2]; if(fabs(vp_slice[2]/spac[2]) > (dims[2]-1)-0.4) vp_slice[2] = ((dims[2]-1)-0.4)*spac[2]; vnormal[0] = 0; vnormal[1] = 0; } m_Plane->SetOrigin( vp_slice ); m_Plane->SetNormal( vnormal ); vtkPolyData* cuttedPlane; if(!( (dims[0] == 1 && vnormal[0] != 0) || (dims[1] == 1 && vnormal[1] != 0) || (dims[2] == 1 && vnormal[2] != 0) )) { m_Cutter->SetCutFunction( m_Plane ); m_Cutter->SetInputData( vtkImage ); m_Cutter->GenerateCutScalarsOff();//! m_Cutter->Update(); cuttedPlane = m_Cutter->GetOutput(); } else { // cutting of a 2D-Volume does not work, // so we have to build up our own polydata object cuttedPlane = vtkPolyData::New(); vtkPoints* points = vtkPoints::New(); points->SetNumberOfPoints(vtkImage->GetNumberOfPoints()); for(int i=0; i<vtkImage->GetNumberOfPoints(); i++) points->SetPoint(i, vtkImage->GetPoint(i)); cuttedPlane->SetPoints(points); vtkFloatArray* pointdata = vtkFloatArray::New(); int comps = vtkImage->GetPointData()->GetScalars()->GetNumberOfComponents(); pointdata->SetNumberOfComponents(comps); int tuples = vtkImage->GetPointData()->GetScalars()->GetNumberOfTuples(); pointdata->SetNumberOfTuples(tuples); for(int i=0; i<tuples; i++) pointdata->SetTuple(i,vtkImage->GetPointData()->GetScalars()->GetTuple(i)); pointdata->SetName( "vector" ); cuttedPlane->GetPointData()->AddArray(pointdata); } if ( cuttedPlane->GetNumberOfPoints() != 0) { // // make sure, that we have point data with more than 1 component (as vectors) // vtkPointData * pointData = cuttedPlane->GetPointData(); if ( pointData == NULL ) { itkWarningMacro( << "no point data associated with cutters result!" ); return ; }
void mitk::PolyDataGLMapper2D::Paint( mitk::BaseRenderer * renderer ) { if ( IsVisible( renderer ) == false ) return ; // ok, das ist aus GenerateData kopiert mitk::BaseData::Pointer input = const_cast<mitk::BaseData*>( GetData() ); assert( input ); input->Update(); vtkPolyData * vtkpolydata = this->GetVtkPolyData(); assert( vtkpolydata ); vtkLinearTransform * vtktransform = GetDataNode() ->GetVtkTransform(); if (vtktransform) { vtkLinearTransform * inversetransform = vtktransform->GetLinearInverse(); Geometry2D::ConstPointer worldGeometry = renderer->GetCurrentWorldGeometry2D(); PlaneGeometry::ConstPointer worldPlaneGeometry = dynamic_cast<const PlaneGeometry*>( worldGeometry.GetPointer() ); if ( vtkpolydata != NULL ) { Point3D point; Vector3D normal; if(worldPlaneGeometry.IsNotNull()) { // set up vtkPlane according to worldGeometry point=worldPlaneGeometry->GetOrigin(); normal=worldPlaneGeometry->GetNormal(); normal.Normalize(); m_Plane->SetTransform((vtkAbstractTransform*)NULL); } else { //@FIXME: does not work correctly. Does m_Plane->SetTransform really transforms a "plane plane" into a "curved plane"? return; AbstractTransformGeometry::ConstPointer worldAbstractGeometry = dynamic_cast<const AbstractTransformGeometry*>(renderer->GetCurrentWorldGeometry2D()); if(worldAbstractGeometry.IsNotNull()) { // set up vtkPlane according to worldGeometry point=const_cast<mitk::BoundingBox*>(worldAbstractGeometry->GetParametricBoundingBox())->GetMinimum(); FillVector3D(normal, 0, 0, 1); m_Plane->SetTransform(worldAbstractGeometry->GetVtkAbstractTransform()->GetInverse()); } else return; } vtkFloatingPointType vp[ 3 ], vnormal[ 3 ]; vnl2vtk(point.Get_vnl_vector(), vp); vnl2vtk(normal.Get_vnl_vector(), vnormal); //normally, we would need to transform the surface and cut the transformed surface with the cutter. //This might be quite slow. Thus, the idea is, to perform an inverse transform of the plane instead. //@todo It probably does not work for scaling operations yet:scaling operations have to be //dealed with after the cut is performed by scaling the contour. inversetransform->TransformPoint( vp, vp ); inversetransform->TransformNormalAtPoint( vp, vnormal, vnormal ); m_Plane->SetOrigin( vp ); m_Plane->SetNormal( vnormal ); // set data into cutter m_Cutter->SetInput( vtkpolydata ); // m_Cutter->GenerateCutScalarsOff(); // m_Cutter->SetSortByToSortByCell(); // calculate the cut m_Cutter->Update(); // fetch geometry mitk::DisplayGeometry::Pointer displayGeometry = renderer->GetDisplayGeometry(); assert( displayGeometry ); // float toGL=displayGeometry->GetSizeInDisplayUnits()[1]; //apply color and opacity read from the PropertyList ApplyProperties( renderer ); // traverse the cut contour vtkPolyData * contour = m_Cutter->GetOutput(); vtkPoints *vpoints = contour->GetPoints(); vtkCellArray *vpolys = contour->GetLines(); vtkPointData *vpointdata = contour->GetPointData(); vtkDataArray* vscalars = vpointdata->GetScalars(); vtkCellData *vcelldata = contour->GetCellData(); vtkDataArray* vcellscalars = vcelldata->GetScalars(); int i, numberOfCells = vpolys->GetNumberOfCells(); Point3D p; Point2D p2d, last, first; vpolys->InitTraversal(); vtkScalarsToColors* lut = GetVtkLUT(); assert ( lut != NULL ); for ( i = 0;i < numberOfCells;++i ) { vtkIdType *cell(NULL); vtkIdType cellSize(0); vpolys->GetNextCell( cellSize, cell ); if ( m_ColorByCellData ) { // color each cell according to cell data vtkFloatingPointType* color = lut->GetColor( vcellscalars->GetComponent( i, 0 ) ); glColor3f( color[ 0 ], color[ 1 ], color[ 2 ] ); } if ( m_ColorByPointData ) { vtkFloatingPointType* color = lut->GetColor( vscalars->GetComponent( cell[0], 0 ) ); glColor3f( color[ 0 ], color[ 1 ], color[ 2 ] ); } glBegin ( GL_LINE_LOOP ); for ( int j = 0;j < cellSize;++j ) { vpoints->GetPoint( cell[ j ], vp ); //take transformation via vtktransform into account vtktransform->TransformPoint( vp, vp ); vtk2itk( vp, p ); //convert 3D point (in mm) to 2D point on slice (also in mm) worldGeometry->Map( p, p2d ); //convert point (until now mm and in worldcoordinates) to display coordinates (units ) displayGeometry->WorldToDisplay( p2d, p2d ); //convert display coordinates ( (0,0) is top-left ) in GL coordinates ( (0,0) is bottom-left ) //p2d[1]=toGL-p2d[1]; //add the current vertex to the line glVertex2f( p2d[0], p2d[1] ); } glEnd (); } } } }