MINC/SoftwareDevelopment/EZMINC/Tutorial

 #include "minc_1_rw.h"
 using namespace minc;
 //...
 try
 {
  minc_1_reader rdr;
  rdr.open(input_minc_file);
 } catch (const minc::generic_error & err) {
  std::cerr << "Got an error at:" << err.file () << ":" << err.line () << std::endl;
  std::cerr << err.msg()<<std::endl;
 }

Minc file is a complex structure, many parameters have to be setup properly to produce meaningful file, the easies way is to copy them from another minc file:

 minc_1_writer wrt;
 wrt.open(output_minc_file,example_minc_file);

Or, if another file is already open: syntaxhighlight lang="text"

wrt.open(output_minc_file,rdr);

</syntaxhighlight>

Or, if only the dimensions need to be preserved (create a file with voxels of type float, and 2D slices): syntaxhighlight lang="text"

wrt.open(output_minc_file,rdr.info(),2,NC_FLOAT);

</syntaxhighlight>

• Determining number of dimensions: rdr.dim_no()
• calculating the matrix size, resolution :

syntaxhighlight lang="text"

std::cout<<"Dimensions:"<<std::endl
<< " Vector:"<<rdr.ndim(0)<<std::endl
<< " X:"<<rdr.ndim(1)<<" step:"<<rdr.nspacing(1)<<" start:"<<rdr.nstart(1)<<std::endl
<< " Y:"<<rdr.ndim(2)<<" step:"<<rdr.nspacing(2)<<" start:"<<rdr.nstart(2)<<std::endl
<< " Z:"<<rdr.ndim(3)<<" step:"<<rdr.nspacing(3)<<" start:"<<rdr.nstart(3)<<std::endl
<< " Time:"<<rdr.ndim(4)<<" step:"<<rdr.nspacing(4)<<" start:"<<rdr.nstart(4)<<std::endl;

</syntaxhighlight> Note that these are physical parameters, which don't depend on the way how information is stored in a minc file

• Output direction cosine matrix

 for(int i=0;i<3;i++)
 {
 if(rdr.have_dir_cos(i))
  for(int j=0;j<3;j++)
    std::cout<<rdr.ndir_cos(i,j)<<" ";
  std::cout<<std::endl;
 }

• Read a minc file history

 std::cout<<"Minc history:"<<rdr.history().c_str()<<std::endl;

• Read a string attribute

 std::cout<<"Subject name:"<<rdr.att_value_string("patient","full_name").c_str()<<std::endl;

• Read a double attribute

syntaxhighlight lang="text"

std::cout<<"Echo time:"<<rdr.att_value_double("acquisition","echo_time")[0]<<std::endl;

</syntaxhighlight> Note: reading double attribute returns std::vector<double> by value

Imaging data is stored as a multidimensional array of values a given type. Array is organized in slices (could be just one slice for the whole file), values stored inside the minc file may be normalized, see MINC/Reference for complete details. EZMINC was developed to hide the complexity of the data representation from programmer , but to allow complete control over how data is stored, if it is needed. There are several ways to read imaging information from a file using EZMINC library:

• The easiest, the whole volume is copied into a multidimensional array in memory. Usually this is the most convenient method:
  • Reading a volume representing real values (interpret them as float)

syntaxhighlight lang="text"

#include <minc_1_simple.h>
#include <minc_1_simple_rw.h>
using namespace minc;
//....
simple_volume<float> src;
minc_1_reader rdr;
rdr1.open(input_file);
load_simple_volume<float>(rdr,src);
std::cout<<"Voxel at voxel coordinates (1,2,3) is "<<src.get(1,2,3)<<std::endl;
//using safe_get to make sure that we don't read beyond the allocated space
std::cout<<"Voxel at world coordinates (1,2,3) is "<<src.safe_get(src.world_to_voxel(IDX<double>(1.0,2.0,3.0)))<<std::endl;

</syntaxhighlight>

• • Reading a volume with a binary mask (or discrete labels)

 #include <minc_io_simple_volume.h>
 #include <minc_1_simple.h>
 #include <minc_1_simple_rw.h>
 using namespace minc;
 //....
 simple_volume<unsigned char> src;
 minc_1_reader rdr;
 rdr1.open(input_file);
 load_simple_volume<unsigned char>(rdr,src);
 std::cout<<"Labels at (1,2,3) is "<<(int)src.get(1,2,3)<<std::endl;

• • Reading a 4D volume

 simple_4d_volume<float> vol;
 load_4d_volume<float>(rdr,vol);
 std::cout<<"Voxel at voxel coordinates (1,2,3) slice 0 is "<<src.get(1,2,3,0)<<std::endl;

• reading the whole minc file as a single continuous buffer, organized with vector_dimension the fastest varying (if present), X,Y,Z, and time the slowest varyuing (if present)

 #include <minc_1_rw.h>
 #include <minc_1_simple.h>
 using namespace minc;
 //...
 minc_1_reader rdr;
 rdr.open(input_file);
 rdr.setup_read_float(); //we have to setup the file to a proper data type
 
 size_t size=1;
 for(i=0;i<rdr.dim_no();i++)
    size*=rdr.dim(i).length;
  
 float* array=new float[size];
 
 load_standard_volume<float>(rdr,array);

• reading the whole minc file voxel-by-voxel, in the order that data is stored inside file. This method is really usefull when working with big number of input files, and storing them all together in memory is problematic

 #include <minc_1_rw.h>
 #include <minc_1_simple.h>
 using namespace minc;
 //...
 minc_1_reader rdr;
 rdr.open(input_file);
 rdr.setup_read_float(); //we have to setup the file to a proper data type
 minc_input_iterator<float> in(rdr);
 
 double avg=0;
 int cnt=0;
 for(in.begin();!in.last();in.next())
 {
    avg+=in.value()
    cnt++;
 }
 std::cout<<"Average value="<<avg/cnt<<std::endl;

• lowest-level interface, reading the minc file slice-by-slice in the order that data is stored

 #include <minc_1_rw.h>
 using namespace minc;
 //...
 minc_1_reader rdr;
 rdr.open(input_file);
 rdr.setup_read_float(); //we have to setup the file to a proper data type

 float* slice_buffer=new float[rdr.slice_len()];

 for(rdr.begin();!rdr.last();rdr.next_slice())//minc_1_reader is actually an iterator!
 {
    rdr.read(slice_buffer);
    //do something usefull with the data
 }

• copying history NOTE: if using first for of minc_1_writer::open history will be copied automatically

 wrt.copy_headers(rdr);

• Appending new line into MINC history

 wrt.append_history("minc_test was used to produce this file\n");

• Write a string attribute

wrt.insert("patient","full_name","John Doe");

• Writing a double attribute

wrt.insert("acquisition","echo_time",0.120); //echo time was 120ms

• Writing an array of double values

std::vector<double> bvalues(64);
//...
wrt.insert("acquisition","bvalues",bvalues);

• Copying all headers from another minc file

wrt.copy_headers(rdr);

• Simplest interface, using simple_volume or simple_4d_volume

 simple_volume<float> output_vol;
 //...
 minc_1_writer wrt;
 wrt.open(output_minc,rdr);
 save_simple_volume<float>(wrt,output_vol);

 simple_4d_volume<float> output_vol;
 //...
 minc_1_writer wrt;
 wrt.open(output_minc,rdr);
 save_4d_volume(wrt,vol);

• Writing image from a continuous array

 float *output_vol=new float[size];
 //...
 minc_1_writer wrt;
 wrt.open(output_minc,rdr);
 wrt.setup_write_float(); //have to setup the data type
 save_standard_volume<float>(wrt,output_vol);

• Using output iterator

    //adding a value c to all voxels
    minc_1_reader rdr;
    rdr.open(input_minc);
    rdr.setup_read_float();
    
    minc_1_writer wrt;
    wrt.open(output_minc,rdr);
    wrt.setup_write_float();
     
    minc_input_iterator<float> in(rdr);
    minc_output_iterator<float> out(wrt);
    for(in.begin(),out.begin();!in.last();in.next(),out.next())
    {
      out.value(in.value()+c);
    }

• lowest-level, writing image slice-by-slice

 #include <minc_1_rw.h>
 using namespace minc;
 //...
 minc_1_reader rdr;
 rdr.open(input_file);
 rdr.setup_read_float(); //we have to setup the file to a proper data type

 minc_1_writer wrt;
 wrt.open(output_minc,rdr);
 wrt.setup_write_float();

 float* slice_buffer=new float[rdr.slice_len()];

 for(rdr.begin(),wrt.begin();!rdr.last();rdr.next_slice(),wrt.next_slice())
 {
    rdr.read(slice_buffer);
    //do something usefull with the data
    wrt.write(slice_buffer);
 }