Exemple #1
0
int main(int argc, char **argv)
{
  if(argc != 3)
    {
      cerr << "Usage: " << argv[0] << " <input volume file> <output volume file>" << endl;
      return 1;
    }

  try
    {
      VolMagickOpStatus status;
      VolMagick::setDefaultMessenger(&status);

      VolMagick::VolumeFileInfo volinfo;

      volinfo.read(argv[1]);

      VolMagick::createVolumeFile(argv[2],
				  volinfo.boundingBox(),
				  volinfo.dimension(),
				  volinfo.voxelTypes(),
				  volinfo.numVariables(),
				  volinfo.numTimesteps(),
				  volinfo.TMin(),volinfo.TMax());

      for(unsigned int var=0; var<volinfo.numVariables(); var++)
	for(unsigned int time=0; time<volinfo.numTimesteps(); time++)
	  {
	    VolMagick::Volume vol;
	    readVolumeFile(vol,argv[1],var,time);
	    for(VolMagick::uint64 i = 0; i < vol.dimension().size(); i++)
	      vol(i, vol.min() + ((vol.max() - vol(i))/(vol.max() - vol.min()))*(vol.max() - vol.min()));
	    vol.desc(volinfo.name(var));
	    writeVolumeFile(vol,argv[2],var,time);
	  }
    }
  catch(VolMagick::Exception &e)
    {
      cerr << e.what() << endl;
    }
  catch(std::exception &e)
    {
      cerr << e.what() << endl;
    }

  return 0;
}
int main(int argc, char **argv)
{
  if(argc < 6)
    {
      std:: cerr << 
	"Usage: " << argv[0] << 

	
	"  <first volume>  <second volume> < threshold> <output volume left> <output volume masked> \n";
	std::cerr<<"second volume (son) is subset of first volume (mother), threshold is in [0,255], output masked is the volume in first volume with > threshold in the second volume. output volume left is the first volume - output volume masked. " << std::endl;

      return 1;
    }

  try
    {
      VolMagick::Volume inputVol;

      VolMagick::Volume inputVol2;

      
      
      VolMagick::readVolumeFile(inputVol,argv[1]); ///first argument is input volume
      
      VolMagick::readVolumeFile(inputVol2, argv[2]); /// second argument is mask volume
      
	  float threshold = atof(argv[3]);


	  VolMagick::Volume  outputLeft;
	  VolMagick::Volume  outputMasked;

      if(!inputVol2.boundingBox().isWithin(inputVol.boundingBox()) )
	  	throw VolMagick::SubVolumeOutOfBounds("The mask volume bounding box must be within the mother volume's bounding box.");



      outputLeft.voxelType(inputVol.voxelType());
      outputLeft.dimension(inputVol.dimension());
      outputLeft.boundingBox(inputVol.boundingBox());
      
      outputMasked.voxelType(inputVol.voxelType());
      outputMasked.dimension(inputVol.dimension());
      outputMasked.boundingBox(inputVol.boundingBox());
    
   

	  float x, y, z;
	  float fvalue;
	  float minvalue = (float)inputVol2.min();
	  float maxvalue = (float)inputVol2.max();

 	  for( int kz = 0; kz<inputVol.ZDim(); kz++)
	  {
	  	for( int jy = 0; jy<inputVol.YDim(); jy++)
	    {
			for( int ix = 0; ix<inputVol.XDim(); ix++)
		   	{
		     	z = inputVol.ZMin() + kz*inputVol.ZSpan();
			 	y = inputVol.YMin() + jy*inputVol.YSpan();
				x = inputVol.XMin() + ix*inputVol.XSpan();
				if((z >= (float)inputVol2.ZMin()) && (z <= (float)inputVol2.ZMax()) && ( y >=(float)inputVol2.YMin()) && (y <= (float)inputVol2.YMax()) &&(x >= (float)inputVol2.XMin()) && (x <= (float)inputVol2.XMax()) )
				{
				  fvalue = 255.0*(inputVol2.interpolate(x,y,z)-minvalue)/(maxvalue-minvalue);
				  if(fvalue > threshold)
				  {
				  	outputMasked(ix,jy,kz, inputVol(ix,jy,kz));
					outputLeft(ix,jy,kz, inputVol.min());
				  }	  
				  else
				  {
				  	outputMasked(ix,jy,kz, inputVol.min());
					outputLeft(ix,jy,kz, inputVol(ix,jy,kz));
				  }
				}
				else
				{
					outputMasked(ix,jy,kz, inputVol.min());
					outputLeft(ix,jy,kz, inputVol(ix,jy,kz));
				}
		     }		   
		  }	
		}



	VolMagick::createVolumeFile(outputLeft, argv[4]);
	VolMagick::createVolumeFile(outputMasked, argv[5]);

  
    std::cout<<"done!"<<std::endl;


    }

  catch(VolMagick::Exception &e)
    {
      std:: cerr << e.what() << std::endl;
    }
  catch(std::exception &e)
    {
      std::cerr << e.what() << std::endl;
    }

  return 0;
}
Exemple #3
0
int main(int argc, char **argv)
{
  if(argc < 4)
    {
      std:: cerr << 
	"Usage: " << argv[0] << 

	
	"  first volume - second volume = output volume, step  \n";

      return 1;
    }

  try
    {
      VolMagick::Volume inputVol;

      VolMagick::Volume inputVol2;
      
      VolMagick::Volume outputVol;

      VolMagick::readVolumeFile(inputVol,argv[1]); ///first argument is input volume
      
      VolMagick::readVolumeFile(inputVol2, argv[2]); /// second argument is mask volume
      

      VolMagick::VolumeFileInfo volinfo1;
      volinfo1.read(argv[1]);
      std::cout << volinfo1.filename() << ":" <<std::endl;

      VolMagick::VolumeFileInfo volinfo2;
      volinfo2.read(argv[2]);

      std::cout << volinfo2.filename() << ":" <<std::endl;
      
      std::cout<<"minVol1 , maxVol1: "<<volinfo1.min()<<" "<<volinfo1.max()<<std::endl;;

      std::cout<<"minVol2 , maxVol2: "<<volinfo2.min()<<" "<<volinfo2.max()<<std::endl;

      
      
      outputVol.voxelType(inputVol.voxelType());
      outputVol.dimension(inputVol.dimension());
      outputVol.boundingBox(inputVol.boundingBox());
      
      
      std::cout<<"voxeltype "<<inputVol.voxelType()<<std::endl;
      	
	  int step = 1;
      if(argc==5) step= atoi(argv[argc-1]);

	  outputVol= inputVol;

      
      for( int kz = 0; kz<inputVol2.ZDim(); kz++)
	{
	    for( int jy = 0; jy<inputVol2.YDim(); jy++)
	      for( int ix = 0; ix<inputVol2.XDim(); ix++)
		{
		  if(inputVol2(ix, jy, kz)> inputVol2.min()) 
		  {
		  	for(int k=kz-step; k<=kz+step; k++)
				for(int j=jy-step; j<= jy+step; j++)
					for(int i=ix-step; i<= ix+step; i++)
					{
					  if(i*j*k >=0 && i< inputVol2.XDim()-1  && j <inputVol2.YDim()-1 && k < inputVol2.ZDim()-1)
		  				outputVol(i, j, k, inputVol.min());
					}
		  }
			  
		}
	}	
      

      VolMagick::createVolumeFile(outputVol, argv[3]);





    }

  catch(VolMagick::Exception &e)
    {
      std:: cerr << e.what() << std::endl;
    }
  catch(std::exception &e)
    {
      std::cerr << e.what() << std::endl;
    }

  return 0;
}
Exemple #4
0
int main(int argc, char **argv)
{
  if(argc < 2)
    {
      cerr << "Usage: " << argv[0] << " <volume file>" << endl;
      return 1;
    }

  try
    {
      VolMagick::VolumeFileInfo volinfo;
      VolMagick::VolumeCache volcache;
      VolMagickOpStatus status;

      VolMagick::setDefaultMessenger(&status);

#if 0
      VolMagick::Volume sphereVol;
      
      sphereVol.dimension(VolMagick::Dimension(128,128,128));//256,256,256));
      sphereVol.voxelType(VolMagick::UChar);

      double center_x = sphereVol.XDim()/2.0;
      double center_y = sphereVol.YDim()/2.0;      
      double center_z = sphereVol.ZDim()/2.0;
      double distance;

      for(unsigned int k=0; k<sphereVol.ZDim(); k++)
	for(unsigned int j=0; j<sphereVol.YDim(); j++)
	  for(unsigned int i=0; i<sphereVol.XDim(); i++)
	    {
	      distance = sqrt(double((i-center_x)*(i-center_x)+
				     (j-center_y)*(j-center_y)+
				     (k-center_z)*(k-center_z)));
	      //sphereVol(i,j,k, distance);
		
	      if((distance > 15.0) && (distance < 20.0))
		sphereVol(i,j,k, 20);//20.0+10*(distance-15.0)/(20.0-15.0));
	      if((distance >= 20.0) && (distance < 25.0))
		sphereVol(i,j,k, 30);//50.0+10*(distance-50.0)/(55.0-50.0));
	    }

      VolMagick::writeVolumeFile(sphereVol, argv[1]);

#endif

#if 0
      volinfo.read(argv[1]);
      cout << volinfo.filename() << ":" <<endl;
      cout << "Num Variables: " << volinfo.numVariables() << endl;
      cout << "Num Timesteps: " << volinfo.numTimesteps() << endl;
      cout << "Dimension: " << volinfo.XDim() << "x" << volinfo.YDim() << "x" << volinfo.ZDim() << endl;
      cout << "Bounding box: ";
      cout << "(" << volinfo.boundingBox().minx << "," << volinfo.boundingBox().miny << "," << volinfo.boundingBox().minz << ") ";
      cout << "(" << volinfo.boundingBox().maxx << "," << volinfo.boundingBox().maxy << "," << volinfo.boundingBox().maxz << ") ";
      cout << endl;
      double volmin = volinfo.min(), volmax = volinfo.max();
      cout << "Min voxel value: " << volmin << endl;
      cout << "Max voxel value: " << volmax << endl;
      cout << "Voxel type: " << volinfo.voxelTypeStr() << endl;
      cout << "Volume name: " << volinfo.name() << endl << endl;
#endif

      /*
      vol.dimension(VolMagick::Dimension(128,128,128));
      vol.voxelType(VolMagick::Float);
      for(unsigned int i=0; i<128; i++)
	for(unsigned int j=0; j<128; j++)
	  for(unsigned int k=0; k<128; k++)
	    vol(i,j,k,double(i)/128.0);
      */
     
#if 0 
      if(argc > 2)
	{
	  VolMagick::Volume vol;

	  readVolumeFile(vol,argv[1]);
	  vol.min(volinfo.min());
	  vol.max(volinfo.max());
	  //vol.map(0.0,255.0);
	  //vol.voxelType(VolMagick::UChar);
	  vol.resize(VolMagick::Dimension(512,512,512));
	  writeVolumeFile(vol,argv[2]);

	}
#endif

#if 0
      if(argc > 2)
	{
	  double realmin, realmax;
	  VolMagick::Volume vol;
	  std::vector<VolMagick::VolumeFileInfo> volinfos(argc-2);
	  volinfos[0].read(argv[1]);
	  realmin = volinfos[0].min();
	  realmax = volinfos[0].max();
	  for(unsigned int i=0; i<argc-2; i++)
	    {
	      volinfos[i].read(argv[i+1]);
	      if(realmin > volinfos[i].min()) realmin = volinfos[i].min();
	      if(realmax < volinfos[i].max()) realmax = volinfos[i].max();
	    }
	  
	  cout << "Realmin: " << realmin << endl;
	  cout << "Realmax: " << realmax << endl;

	  createVolumeFile(argv[argc-1],
			   volinfo.boundingBox(),
			   volinfo.dimension(),
			   std::vector<VolMagick::VoxelType>(1, VolMagick::UChar),
			   1, argc-2,
			   0.0, double(argc-3));

	  for(unsigned int i=0; i<argc-2; i++)
	    {
	      readVolumeFile(vol,argv[i+1]);
	      //so the mapping is correct across all timesteps, we must set the real min and max across time
	      vol.min(realmin);
	      vol.max(realmax);
	      vol.map(0.0,255.0);
	      vol.voxelType(VolMagick::UChar);
	      writeVolumeFile(vol,argv[argc-1],0,i);
	    }
	}
#endif

      //vector test
#if 0
      std::vector<VolMagick::Volume> vols(4);
      {
	char filename[256];

	cout << "Testing RawV!" << endl;
	vols[0].voxelType(VolMagick::UChar);
	vols[0].desc("red");
	vols[0].fill(130.0);
	vols[1].voxelType(VolMagick::UChar);
	vols[1].desc("green");
	vols[1].fill(20.0);
	vols[2].voxelType(VolMagick::UChar);
	vols[2].desc("blue");
	vols[2].fill(200.0);
	
	vols[3].voxelType(VolMagick::Float);
	vols[3].desc("alpha");
	for(unsigned int k=0; k<vols[3].ZDim(); k++)
	  for(unsigned int j=0; j<vols[3].YDim(); j++)
	    for(unsigned int i=0; i<vols[3].XDim(); i++)
	      vols[3](i,j,k,
		      sqrt(float((i - (vols[3].XDim()/2.0))*(i - (vols[3].XDim()/2.0)) + 
				 (j - (vols[3].YDim()/2.0))*(j - (vols[3].YDim()/2.0)) + 
				 (k - (vols[3].ZDim()/2.0))*(k - (vols[3].ZDim()/2.0)))));
	
	VolMagick::writeVolumeFile(vols,"test.rawv");
      }
#endif
      //cout << "std::streamoff size: " << sizeof(std::streamoff) << endl;

      //ifstream test("flkajlff");
    }
  catch(VolMagick::Exception &e)
    {
      cerr << e.what() << endl;
    }
  catch(std::exception &e)
    {
      cerr << e.what() << endl;
    }

  return 0;
}
Exemple #5
0
int main(int argc, char **argv)
{
    if(argc < 3)
    {
        cerr << "Usage: " << argv[0] << " <volume file> <volume file>" << endl;
        return 1;
    }

    try
    {
        VolMagickOpStatus status;

        VolMagick::setDefaultMessenger(&status);

#if 0
        double realmin, realmax;
        VolMagick::Volume vol;
        std::vector<VolMagick::VolumeFileInfo> volinfos(argc-2);
        volinfos[0].read(argv[1]);
        realmin = volinfos[0].min();
        realmax = volinfos[0].max();
        for(unsigned int i=0; i<argc-2; i++)
        {
            volinfos[i].read(argv[i+1]);
            if(realmin > volinfos[i].min()) realmin = volinfos[i].min();
            if(realmax < volinfos[i].max()) realmax = volinfos[i].max();
        }

        cout << "Realmin: " << realmin << endl;
        cout << "Realmax: " << realmax << endl;

        createVolumeFile(argv[argc-1],
                         volinfos[0].boundingBox(),
                         volinfos[0].dimension(),
                         std::vector<VolMagick::VoxelType>(1, VolMagick::UChar),
                         1, argc-2,
                         0.0, double(argc-3));

        for(unsigned int i=0; i<argc-2; i++)
        {
            readVolumeFile(vol,argv[i+1]);
            //so the mapping is correct across all timesteps, we must set the real min and max across time
            vol.min(realmin);
            vol.max(realmax);
            vol.map(0.0,255.0);
            vol.voxelType(VolMagick::UChar);
            writeVolumeFile(vol,argv[argc-1],0,i);
        }
#endif

        const double errThresh = 0.01;

        VolMagick::Volume vols[2];
        VolMagick::readVolumeFile(vols[0],argv[1]);
        VolMagick::readVolumeFile(vols[1],argv[2]);

        if(vols[0].dimension() != vols[1].dimension()) throw VolMagick::VolumePropertiesMismatch("Volumes differ in dimension");
        if(vols[0].boundingBox() != vols[1].boundingBox()) throw VolMagick::VolumePropertiesMismatch("Volumes differ in bounding box");
        if(fabs(vols[0].min() - vols[1].min()) > errThresh) throw VolMagick::VolumePropertiesMismatch("Minimum voxel values differ");
        if(fabs(vols[0].max() - vols[1].max()) > errThresh) throw VolMagick::VolumePropertiesMismatch("Maximum voxel values differ");

        for(VolMagick::uint64 i = 0; i<vols[0].dimension().size(); i++)
            if(fabs(vols[0](i) - vols[1](i)) > errThresh) throw VolMagick::VolumePropertiesMismatch("Voxel values differ");

    }
    catch(VolMagick::Exception &e)
    {
        cerr << e.what() << endl;
    }
    catch(std::exception &e)
    {
        cerr << e.what() << endl;
    }

    return 0;
}
int main(int argc, char **argv)
{
  if(argc < 5)
    {
      std:: cerr << 
	"Usage: " << argv[0] << 

"  inputfile NewMin NewMax outputFile \n";
      return 1;
    }

  try
    {
      VolMagick::Volume inputVol;

      VolMagick::Volume inputVol2;
      
      VolMagick::Volume outputVol;

      VolMagick::readVolumeFile(inputVol,argv[1]); ///first argument is input volume
      
      

  //    VolMagick::VolumeFileInfo volinfo1;
  //    volinfo1.read(argv[1]);
  //    std::cout << volinfo1.filename() << ":" <<std::endl;

      
      outputVol.voxelType(inputVol.voxelType());
      outputVol.dimension(inputVol.dimension());
      outputVol.boundingBox(inputVol.boundingBox());
      
      
      std::cout<<"voxeltype: "<<inputVol.voxelType()<<std::endl;
      std::cout<<"InputVol min, max: " << inputVol.min() << ", " << inputVol.max() << std::endl;

     float newMin = atof(argv[2]);
     float newMax = atof(argv[3]); 
      
      for( int kz = 0; kz<inputVol.ZDim(); kz++)
	{
	  std::cout<<kz<<"..";
	    for( int jy = 0; jy<inputVol.YDim(); jy++)
	      for( int ix = 0; ix<inputVol.XDim(); ix++)
		{
		  
		  outputVol(ix,jy,kz, newMin + (inputVol(ix,jy,kz)-inputVol.min())*newMax/(inputVol.max()-inputVol.min())  );
		  
		}
	}	
      

      VolMagick::createVolumeFile(argv[argc-1], outputVol);

  //    VolMagick::writeVolumeFile(outputVol, argv[argc-1]);



     std::cout<< std::endl;

    }

  catch(VolMagick::Exception &e)
    {
      std:: cerr << e.what() << std::endl;
    }
  catch(std::exception &e)
    {
      std::cerr << e.what() << std::endl;
    }

  return 0;
}