/*========================================================================= Program: Visualization Toolkit Module: $RCSfile: vtkRectilinearGridGeometryFilter.cxx,v $ Copyright (c) Ken Martin, Will Schroeder, Bill Lorensen All rights reserved. See Copyright.txt or http://www.kitware.com/Copyright.htm for details. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the above copyright notice for more information. =========================================================================*/ #include "vtkRectilinearGridGeometryFilter.h" #include "vtkCellArray.h" #include "vtkCellData.h" #include "vtkInformation.h" #include "vtkInformationVector.h" #include "vtkObjectFactory.h" #include "vtkPointData.h" #include "vtkPoints.h" #include "vtkPolyData.h" #include "vtkRectilinearGrid.h" vtkCxxRevisionMacro(vtkRectilinearGridGeometryFilter, "$Revision: 1.32 $"); vtkStandardNewMacro(vtkRectilinearGridGeometryFilter); // Construct with initial extent (0,100, 0,100, 0,0) (i.e., a k-plane). vtkRectilinearGridGeometryFilter::vtkRectilinearGridGeometryFilter() { this->Extent[0] = 0; this->Extent[1] = VTK_LARGE_INTEGER; this->Extent[2] = 0; this->Extent[3] = VTK_LARGE_INTEGER; this->Extent[4] = 0; this->Extent[5] = VTK_LARGE_INTEGER; } int vtkRectilinearGridGeometryFilter::RequestData( vtkInformation *vtkNotUsed(request), vtkInformationVector **inputVector, vtkInformationVector *outputVector) { // get the info objects vtkInformation *inInfo = inputVector[0]->GetInformationObject(0); vtkInformation *outInfo = outputVector->GetInformationObject(0); // get the input and ouptut vtkRectilinearGrid *input = vtkRectilinearGrid::SafeDownCast( inInfo->Get(vtkDataObject::DATA_OBJECT())); vtkPolyData *output = vtkPolyData::SafeDownCast( outInfo->Get(vtkDataObject::DATA_OBJECT())); int *dims, dimension, dir[3], diff[3]; int i, j, k, extent[6]; vtkIdType idx, startIdx, startCellIdx; vtkIdType ptIds[4]; vtkIdType cellId; vtkPoints *newPts=0; vtkCellArray *newVerts=0; vtkCellArray *newLines=0; vtkCellArray *newPolys=0; vtkIdType totPoints, pos; int offset[3], numPolys; double x[3]; vtkPointData *pd, *outPD; vtkCellData *cd, *outCD; vtkDebugMacro(<< "Extracting rectilinear points geometry"); pd = input->GetPointData(); outPD = output->GetPointData(); outPD->CopyNormalsOff(); cd = input->GetCellData(); outCD = output->GetCellData(); dims = input->GetDimensions(); // // Based on the dimensions of the rectilinear data, // and the extent of the geometry, // compute the combined extent plus the dimensionality of the data // for (dimension=3, i=0; i<3; i++) { extent[2*i] = this->Extent[2*i] < 0 ? 0 : this->Extent[2*i]; extent[2*i] = this->Extent[2*i] >= dims[i] ? dims[i]-1 : this->Extent[2*i]; extent[2*i+1] = this->Extent[2*i+1] >= dims[i] ? dims[i]-1 : this->Extent[2*i+1]; if ( extent[2*i+1] < extent[2*i] ) { extent[2*i+1] = extent[2*i]; } if ( (extent[2*i+1] - extent[2*i]) == 0 ) { dimension--; } } // // Now create polygonal data based on dimension of data // startIdx = extent[0] + extent[2]*dims[0] + extent[4]*dims[0]*dims[1]; // The cell index is a bit more complicated at the boundaries if (dims[0] == 1) { startCellIdx = extent[0]; } else { startCellIdx = (extent[0] < dims[0] - 1) ? extent[0] : extent[0]-1; } if (dims[1] == 1) { startCellIdx += extent[2]*(dims[0]-1); } else { startCellIdx += (extent[2] < dims[1] - 1) ? extent[2]*(dims[0]-1) : (extent[2]-1)*(dims[0]-1); } if (dims[2] == 1) { startCellIdx += extent[4]*(dims[0]-1)*(dims[1]-1); } else { startCellIdx += (extent[4] < dims[2] - 1) ? extent[4]*(dims[0]-1)*(dims[1]-1) : (extent[4]-1)*(dims[0]-1)*(dims[1]-1); } switch (dimension) { default: break; case 0: // --------------------- build point ----------------------- newPts = vtkPoints::New(); newPts->Allocate(1); newVerts = vtkCellArray::New(); newVerts->Allocate(newVerts->EstimateSize(1,1)); outPD->CopyAllocate(pd,1); outCD->CopyAllocate(cd,1); ptIds[0] = newPts->InsertNextPoint(input->GetPoint(startIdx)); outPD->CopyData(pd,startIdx,ptIds[0]); cellId = newVerts->InsertNextCell(1,ptIds); outCD->CopyData(cd,startIdx,cellId); break; case 1: // --------------------- build line ----------------------- for (dir[0]=dir[1]=dir[2]=totPoints=0, i=0; i<3; i++) { if ( (diff[i] = extent[2*i+1] - extent[2*i]) > 0 ) { dir[0] = i; totPoints = diff[i] + 1; break; } } newPts = vtkPoints::New(); newPts->Allocate(totPoints); newLines = vtkCellArray::New(); newLines->Allocate(newLines->EstimateSize(totPoints-1,2)); outPD->CopyAllocate(pd,totPoints); outCD->CopyAllocate(cd,totPoints - 1); // // Load data // if ( dir[0] == 0 ) { offset[0] = 1; } else if (dir[0] == 1) { offset[0] = dims[0]; } else { offset[0] = dims[0]*dims[1]; } for (i=0; iGetPoint(idx, x); ptIds[0] = newPts->InsertNextPoint(x); outPD->CopyData(pd,idx,ptIds[0]); } if ( dir[0] == 0 ) { offset[0] = 1; } else if (dir[0] == 1) { offset[0] = dims[0] - 1; } else { offset[0] = (dims[0] - 1) * (dims[1] - 1); } for (i=0; i<(totPoints-1); i++) { idx = startCellIdx + i*offset[0]; ptIds[0] = i; ptIds[1] = i + 1; cellId = newLines->InsertNextCell(2,ptIds); outCD->CopyData(cd,idx,cellId); } break; case 2: // --------------------- build plane ----------------------- // // Create the data objects // for (dir[0]=dir[1]=dir[2]=idx=0,i=0; i<3; i++) { if ( (diff[i] = extent[2*i+1] - extent[2*i]) != 0 ) { dir[idx++] = i; } else { dir[2] = i; } } totPoints = (diff[dir[0]]+1) * (diff[dir[1]]+1); numPolys = diff[dir[0]] * diff[dir[1]]; newPts = vtkPoints::New(); newPts->Allocate(totPoints); newPolys = vtkCellArray::New(); newPolys->Allocate(newLines->EstimateSize(numPolys,4)); outPD->CopyAllocate(pd,totPoints); outCD->CopyAllocate(cd,numPolys); // // Create polygons // for (i=0; i<2; i++) { if ( dir[i] == 0 ) { offset[i] = 1; } else if ( dir[i] == 1 ) { offset[i] = dims[0]; } else if ( dir[i] == 2 ) { offset[i] = dims[0]*dims[1]; } } // create points whether visible or not. Makes coding easier but generates // extra data. for (pos=startIdx, j=0; j < (diff[dir[1]]+1); j++) { for (i=0; i < (diff[dir[0]]+1); i++) { idx = pos + i*offset[0]; input->GetPoint(idx, x); ptIds[0] = newPts->InsertNextPoint(x); outPD->CopyData(pd,idx,ptIds[0]); } pos += offset[1]; } // create any polygon who has a visible vertex. To turn off a polygon, all // vertices have to be blanked. for (i=0; i<2; i++) { if ( dir[i] == 0 ) { offset[i] = 1; } else if ( dir[i] == 1 ) { offset[i] = (dims[0] - 1); } else if ( dir[i] == 2 ) { offset[i] = (dims[0] - 1) * (dims[1] - 1); } } for (pos=startCellIdx, j=0; j < diff[dir[1]]; j++) { for (i=0; i < diff[dir[0]]; i++) { idx = pos + i*offset[0]; ptIds[0] = i + j*(diff[dir[0]]+1); ptIds[1] = ptIds[0] + 1; ptIds[2] = ptIds[1] + diff[dir[0]] + 1; ptIds[3] = ptIds[2] - 1; cellId = newPolys->InsertNextCell(4,ptIds); outCD->CopyData(cd,idx,cellId); } pos += offset[1]; } break; case 3: // ------------------- grab points in volume -------------- // // Create data objects // for (i=0; i<3; i++) { diff[i] = extent[2*i+1] - extent[2*i]; } totPoints = (diff[0]+1) * (diff[1]+1) * (diff[2]+1); newPts = vtkPoints::New(); newPts->Allocate(totPoints); newVerts = vtkCellArray::New(); newVerts->Allocate(newVerts->EstimateSize(totPoints,1)); outPD->CopyAllocate(pd,totPoints); outCD->CopyAllocate(cd,totPoints); // // Create vertices // offset[0] = dims[0]; offset[1] = dims[0]*dims[1]; for (k=0; k < (diff[2]+1); k++) { for (j=0; j < (diff[1]+1); j++) { pos = startIdx + j*offset[0] + k*offset[1]; for (i=0; i < (diff[0]+1); i++) { input->GetPoint(pos+i, x); ptIds[0] = newPts->InsertNextPoint(x); outPD->CopyData(pd,pos+i,ptIds[0]); cellId = newVerts->InsertNextCell(1,ptIds); outCD->CopyData(cd,pos+i,cellId); } } } break; /* end this case */ } // switch // // Update self and release memory // if (newPts) { output->SetPoints(newPts); newPts->Delete(); } if (newVerts) { output->SetVerts(newVerts); newVerts->Delete(); } if (newLines) { output->SetLines(newLines); newLines->Delete(); } if (newPolys) { output->SetPolys(newPolys); newPolys->Delete(); } return 1; } // Specify (imin,imax, jmin,jmax, kmin,kmax) indices. void vtkRectilinearGridGeometryFilter::SetExtent(int iMin, int iMax, int jMin, int jMax, int kMin, int kMax) { int extent[6]; extent[0] = iMin; extent[1] = iMax; extent[2] = jMin; extent[3] = jMax; extent[4] = kMin; extent[5] = kMax; this->SetExtent(extent); } // Specify (imin,imax, jmin,jmax, kmin,kmax) indices in array form. void vtkRectilinearGridGeometryFilter::SetExtent(int extent[6]) { int i; if ( extent[0] != this->Extent[0] || extent[1] != this->Extent[1] || extent[2] != this->Extent[2] || extent[3] != this->Extent[3] || extent[4] != this->Extent[4] || extent[5] != this->Extent[5] ) { this->Modified(); for (i=0; i<3; i++) { if ( extent[2*i] < 0 ) { extent[2*i] = 0; } if ( extent[2*i+1] < extent[2*i] ) { extent[2*i+1] = extent[2*i]; } this->Extent[2*i] = extent[2*i]; this->Extent[2*i+1] = extent[2*i+1]; } } } int vtkRectilinearGridGeometryFilter::FillInputPortInformation( int, vtkInformation *info) { info->Set(vtkAlgorithm::INPUT_REQUIRED_DATA_TYPE(), "vtkRectilinearGrid"); return 1; } void vtkRectilinearGridGeometryFilter::PrintSelf(ostream& os, vtkIndent indent) { this->Superclass::PrintSelf(os,indent); os << indent << "Extent: \n"; os << indent << " Imin,Imax: (" << this->Extent[0] << ", " << this->Extent[1] << ")\n"; os << indent << " Jmin,Jmax: (" << this->Extent[2] << ", " << this->Extent[3] << ")\n"; os << indent << " Kmin,Kmax: (" << this->Extent[4] << ", " << this->Extent[5] << ")\n"; }