1 /*=========================================================================
2 Program: vv http://www.creatis.insa-lyon.fr/rio/vv
5 - University of LYON http://www.universite-lyon.fr/
6 - Léon Bérard cancer center http://www.centreleonberard.fr
7 - CREATIS CNRS laboratory http://www.creatis.insa-lyon.fr
9 This software is distributed WITHOUT ANY WARRANTY; without even
10 the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
11 PURPOSE. See the copyright notices for more information.
13 It is distributed under dual licence
15 - BSD See included LICENSE.txt file
16 - CeCILL-B http://www.cecill.info/licences/Licence_CeCILL-B_V1-en.html
17 ===========================================================================**/
25 #include "clitkCommon.h"
31 #include <itksys/SystemTools.hxx>
34 #include <vtkSmartPointer.h>
35 #include <vtkFloatArray.h>
36 #include <vtkPointData.h>
37 #include <vtkPolyData.h>
38 #include <vtkPolyDataReader.h>
39 #include <vtkOBJReader.h>
40 #include <vtkImageData.h>
41 #include <vtkImageStencil.h>
42 #include <vtkLinearExtrusionFilter.h>
43 #include <vtkPolyDataToImageStencil.h>
44 #include <vtkMarchingCubes.h>
45 #include <vtkMetaImageWriter.h>
52 void vvMesh::AddMesh(vtkPolyData* p)
54 vtkPolyData * mesh=vtkPolyData::New();
56 meshes.push_back(mesh);
59 void vvMesh::ReadFromVTK(const char * filename)
61 std::string extension=itksys::SystemTools::GetFilenameLastExtension(std::string(filename));
62 if (extension == ".vtk" || extension== ".VTK") {
63 assert(GetNumberOfMeshes() == 0); ///We assume the object is empty
64 vtkSmartPointer<vtkPolyDataReader> r=vtkSmartPointer<vtkPolyDataReader>::New();
65 r->SetFileName(filename);
67 assert(r->GetOutput());
68 AddMesh(r->GetOutput());
69 } else if (extension == ".obj" || extension== ".OBJ") {
70 assert(GetNumberOfMeshes() == 0); ///We assume the object is empty
71 vtkSmartPointer<vtkOBJReader> r=vtkSmartPointer<vtkOBJReader>::New();
72 r->SetFileName(filename);
74 assert(r->GetOutput());
75 AddMesh(r->GetOutput());
77 assert (false) ; //shouldn't happen
79 assert(GetNumberOfMeshes() != 0); ///We assume the object is empty
80 structure_name=filename;
83 void vvMesh::RemoveMeshes()
85 for (std::vector<vtkPolyData*>::const_iterator i=meshes.begin(); i!=meshes.end(); i++)
87 meshes.erase(meshes.begin(),meshes.end());
90 void vvMesh::AddMask(vtkImageData* im)
92 assert(im->GetScalarType() == VTK_UNSIGNED_CHAR);
93 vtkImageData* image=vtkImageData::New();
94 image->ShallowCopy(im);
95 masks.push_back(image);
98 void vvMesh::RemoveMasks()
100 for (std::vector<vtkImageData*>::const_iterator i=masks.begin(); i!=masks.end(); i++)
102 masks.erase(masks.begin(),masks.end());
111 void vvMesh::CopyInformation(vvMesh::Pointer input)
116 structure_name=input->structure_name;
117 slice_spacing=input->slice_spacing;
120 void vvMesh::Print() const
122 std::cout << this << " : " << structure_name << std::endl << "RGB: " << r << "," << g << "," << b << std::endl;
123 for (std::vector<vtkPolyData*>::const_iterator i=meshes.begin(); i!=meshes.end(); i++) {
124 std::cout << (*i)->GetNumberOfPoints() << " points, " << (*i)->GetNumberOfCells() << " cells." << std::endl;
125 DDV((*i)->GetBounds(),6);
127 std::cout << "-------------------------" << std::endl << std::endl;
130 void vvMesh::ComputeMasks(vtkImageData* sample,bool extrude)
133 for (std::vector<vtkPolyData*>::iterator i=meshes.begin(); i!=meshes.end(); i++) {
134 vtkPolyData* mesh=*i;
135 double *bounds=mesh->GetBounds();
137 vtkSmartPointer<vtkImageData> binary_image=vtkSmartPointer<vtkImageData>::New();
138 binary_image->SetScalarTypeToUnsignedChar();
139 ///Use the smallest mask in which the mesh fits
140 // Add two voxels on each side to make sure the mesh fits
141 double * samp_origin=sample->GetOrigin();
142 double * spacing=sample->GetSpacing();
143 binary_image->SetSpacing(spacing);
145 /// Put the origin on a voxel to avoid small skips
146 binary_image->SetOrigin(floor((bounds[0]-samp_origin[0])/spacing[0]-2)*spacing[0]+samp_origin[0],
147 floor((bounds[2]-samp_origin[1])/spacing[1]-2)*spacing[1]+samp_origin[1],
148 floor((bounds[4]-samp_origin[2])/spacing[2]-2)*spacing[2]+samp_origin[2]);
149 double * origin=binary_image->GetOrigin();
150 binary_image->SetExtent(0,ceil((bounds[1]-origin[0])/spacing[0]+4),
151 0,ceil((bounds[3]-origin[1])/spacing[1]+4),
152 0,ceil((bounds[5]-origin[2])/spacing[2])+4);
153 binary_image->AllocateScalars();
154 memset(binary_image->GetScalarPointer(),0,binary_image->GetDimensions()[0]*binary_image->GetDimensions()[1]*binary_image->GetDimensions()[2]*sizeof(unsigned char));
157 vtkSmartPointer<vtkPolyDataToImageStencil> sts=vtkSmartPointer<vtkPolyDataToImageStencil>::New();
158 //The following line is extremely important
159 //http://www.nabble.com/Bug-in-vtkPolyDataToImageStencil--td23368312.html#a23370933
160 sts->SetTolerance(0);
161 sts->SetInformationInput(binary_image);
164 vtkSmartPointer<vtkLinearExtrusionFilter> extrude=vtkSmartPointer<vtkLinearExtrusionFilter>::New();
165 extrude->SetInput(mesh);
166 ///We extrude in the -slice_spacing direction to respect the FOCAL convention
167 extrude->SetVector(0, 0, -slice_spacing);
168 sts->SetInput(extrude->GetOutput());
172 vtkSmartPointer<vtkImageStencil> stencil=vtkSmartPointer<vtkImageStencil>::New();
173 stencil->SetStencil(sts->GetOutput());
174 stencil->SetInput(binary_image);
176 this->AddMask(stencil->GetOutput());
179 vtkSmartPointer<vtkMetaImageWriter> w = vtkSmartPointer<vtkMetaImageWriter>::New();
180 w->SetInput(stencil->GetOutput());
181 w->SetFileName("binary.mhd");
187 void vvMesh::ComputeMeshes()
189 this->RemoveMeshes();
190 for (std::vector<vtkImageData*>::iterator i=masks.begin(); i!=masks.end(); i++) {
191 vtkSmartPointer<vtkMarchingCubes> marching = vtkSmartPointer<vtkMarchingCubes>::New();
192 marching->SetInput(*i);
193 marching->SetValue(0,0.5);
195 this->AddMesh(marching->GetOutput());
199 void vvMesh::propagateContour(vvImage::Pointer vf)
201 assert(this->GetNumberOfMeshes() == 1);
202 std::vector<vtkImageData*> sgrids=vf->GetVTKImages();
203 vtkSmartPointer<vtkPolyData> reference_mesh = vtkSmartPointer<vtkPolyData>::New();
204 reference_mesh->ShallowCopy(this->GetMesh(0));
205 this->RemoveMeshes();
207 for (std::vector<vtkImageData*>::iterator i=sgrids.begin();
208 i!=sgrids.end(); i++) {
209 vtkPolyData* new_mesh=vtkPolyData::New();
210 new_mesh->DeepCopy(reference_mesh);
211 double Ox=vf->GetOrigin()[0];
212 double Oy=vf->GetOrigin()[1];
213 double Oz=vf->GetOrigin()[2];
214 double Sx=vf->GetSpacing()[0];
215 double Sy=vf->GetSpacing()[1];
216 double Sz=vf->GetSpacing()[2];
217 int *dims=vf->GetVTKImages()[0]->GetDimensions();
218 assert((*i)->GetScalarType() == VTK_FLOAT); //vfs are assumed to be of float type
219 assert((*i)->GetNumberOfScalarComponents() == 3);
220 float * vector_data=reinterpret_cast<float*>((*i)->GetScalarPointer());
221 for (int j=0; j<new_mesh->GetNumberOfPoints(); j++) {
222 double* old=new_mesh->GetPoint(j);
223 int ix=(old[0]-Ox)/Sx;
224 int iy=(old[1]-Oy)/Sy;
225 int iz=(old[2]-Oz)/Sz;
226 float* vector=vector_data+(ix+iy*vf->GetSize()[0]+iz*vf->GetSize()[0]*vf->GetSize()[1])*3;
227 if (ix>=0 && ix < dims[0]
228 && iy>=0 && iy < dims[1]
229 && iz>=0 && iz < dims[2])
230 new_mesh->GetPoints()->SetPoint(j,old[0]+vector[0],old[1]+vector[1],old[2]+vector[2]);
232 this->AddMesh(new_mesh);
234 if (GetNumberOfMasks()) { //If the input mesh has a mask, use it to compute the warped meshes' masks
235 vtkSmartPointer<vtkImageData> ref_mask = vtkSmartPointer<vtkImageData>::New();
236 ref_mask->ShallowCopy(GetMask(0));
237 this->ComputeMasks(ref_mask);