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1 /*=========================================================================
2   Program:   vv                     http://www.creatis.insa-lyon.fr/rio/vv
3
4   Authors belong to:
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
8
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.
12
13   It is distributed under dual licence
14
15   - BSD        See included LICENSE.txt file
16   - CeCILL-B   http://www.cecill.info/licences/Licence_CeCILL-B_V1-en.html
17 ===========================================================================**/
18 #ifndef clitkPartitionEnergyWindowDicomGenericFilter_txx
19 #define clitkPartitionEnergyWindowDicomGenericFilter_txx
20
21 /* =================================================
22  * @file   clitkPartitionEnergyWindowDicomGenericFilter.txx
23  * @author
24  * @date
25  *
26  * @brief
27  *
28  ===================================================*/
29
30 #include <sstream>
31 // clitk
32 #include "clitkResampleImageWithOptionsFilter.h"
33 #if GDCM_MAJOR_VERSION >= 2
34 #include "gdcmUIDGenerator.h"
35 #include <gdcmImageHelper.h>
36 #include <gdcmAttribute.h>
37 #include <gdcmReader.h>
38 #include <gdcmWriter.h>
39 #include <gdcmDataElement.h>
40 #include <gdcmTag.h>
41 #else
42 #include "gdcmFile.h"
43 #include "gdcmUtil.h"
44 #endif
45
46 #include "itkImageRegionIterator.h"
47 #include "itkMetaImageIO.h"
48 #include "itkMetaDataDictionary.h"
49
50
51 namespace clitk
52 {
53
54
55 //-----------------------------------------------------------
56 // Constructor
57 //-----------------------------------------------------------
58 template<class args_info_type>
59 PartitionEnergyWindowDicomGenericFilter<args_info_type>::PartitionEnergyWindowDicomGenericFilter()
60 {
61   m_Verbose=false;
62   m_InputFileName="";
63 }
64
65
66 //-----------------------------------------------------------
67 // Update
68 //-----------------------------------------------------------
69 template<class args_info_type>
70 void PartitionEnergyWindowDicomGenericFilter<args_info_type>::Update()
71 {
72   // Read the Dimension and PixelType
73   int Dimension;
74   std::string PixelType;
75   ReadImageDimensionAndPixelType(m_InputFileName, Dimension, PixelType);
76
77
78   // Call UpdateWithDim
79   if(Dimension==2) UpdateWithDim<2>(PixelType);
80   else if(Dimension==3) UpdateWithDim<3>(PixelType);
81   // else if (Dimension==4)UpdateWithDim<4>(PixelType);
82   else {
83     std::cout<<"Error, Only for 2 or 3  Dimensions!!!"<<std::endl ;
84     return;
85   }
86 }
87
88 //-------------------------------------------------------------------
89 // Update with the number of dimensions
90 //-------------------------------------------------------------------
91 template<class args_info_type>
92 template<unsigned int Dimension>
93 void
94 PartitionEnergyWindowDicomGenericFilter<args_info_type>::UpdateWithDim(std::string PixelType)
95 {
96   if (m_Verbose) std::cout << "Image was detected to be "<<Dimension<<"D and "<< PixelType<<"..."<<std::endl;
97
98   if(PixelType == "short") {
99     if (m_Verbose) std::cout << "Launching filter in "<< Dimension <<"D and signed short..." << std::endl;
100     UpdateWithDimAndPixelType<Dimension, signed short>();
101   }
102   else if(PixelType == "unsigned_short"){
103     if (m_Verbose) std::cout  << "Launching filter in "<< Dimension <<"D and unsigned_short..." << std::endl;
104     UpdateWithDimAndPixelType<Dimension, unsigned short>();
105   }
106
107   else if (PixelType == "unsigned_char") {
108     if (m_Verbose) std::cout  << "Launching filter in "<< Dimension <<"D and unsigned_char..." << std::endl;
109     UpdateWithDimAndPixelType<Dimension, unsigned char>();
110   }
111
112   //     else if (PixelType == "char"){
113   //       if (m_Verbose) std::cout  << "Launching filter in "<< Dimension <<"D and signed_char..." << std::endl;
114   //       UpdateWithDimAndPixelType<Dimension, signed char>();
115   //     }
116   else if (PixelType == "double") {
117     if (m_Verbose) std::cout  << "Launching filter in "<< Dimension <<"D and double..." << std::endl;
118     UpdateWithDimAndPixelType<Dimension, double>();
119   }
120   else {
121     if (m_Verbose) std::cout  << "Launching filter in "<< Dimension <<"D and float..." << std::endl;
122     UpdateWithDimAndPixelType<Dimension, float>();
123   }
124 }
125
126 //-------------------------------------------------------------------
127 // Update with the number of dimensions and the pixeltype read from
128 // the dicom files. The MHD files may be resampled to match the
129 // dicom spacing (and number of slices). Rounding errors in resampling
130 // are handled by removing files when generating the output dicom
131 // series.
132 //-------------------------------------------------------------------
133 template<class args_info_type>
134 template <unsigned int Dimension, class  PixelType>
135 void
136 PartitionEnergyWindowDicomGenericFilter<args_info_type>::UpdateWithDimAndPixelType()
137 {
138
139 #if GDCM_MAJOR_VERSION == 2
140   // ImageTypes
141   typedef itk::Image<PixelType, Dimension> InputImageType;
142   typedef itk::Image<PixelType, Dimension> OutputImageType;
143   typedef itk::ImageSeriesReader< InputImageType >     ReaderType;
144   typedef itk::ImageSeriesWriter< InputImageType, InputImageType >     WriterType;
145   typedef itk::GDCMImageIO ImageIOType;
146   typedef typename InputImageType::RegionType RegionType;
147   typedef typename RegionType::SizeType SizeType;
148
149
150   // Read Dicom model file
151   typename ReaderType::Pointer reader = ReaderType::New();
152   ImageIOType::Pointer gdcmIO = ImageIOType::New();
153   gdcmIO->LoadPrivateTagsOn();
154   gdcmIO->KeepOriginalUIDOn();
155   reader->SetImageIO( gdcmIO );
156   typename ReaderType::FileNamesContainer fileNamesInput;
157   fileNamesInput.push_back(m_ArgsInfo.input_arg);
158   reader->SetFileNames( fileNamesInput );
159   try {
160     reader->Update();
161   } catch (itk::ExceptionObject &excp) {
162     std::cerr << "Error: Exception thrown while reading the DICOM model file !!" << std::endl;
163     std::cerr << excp << std::endl;
164   }
165   typename InputImageType::Pointer input = reader->GetOutput();
166
167   typename ReaderType::DictionaryRawPointer inputDict = (*(reader->GetMetaDataDictionaryArray()))[0];
168   typename ReaderType::DictionaryArrayType outputArray;
169   typename ReaderType::DictionaryRawPointer outputDict = new typename ReaderType::DictionaryType;
170   CopyDictionary (*inputDict, *outputDict);
171   itk::EncapsulateMetaData<std::string>(*outputDict, "0054|0011", NumberToString(1));
172   outputArray.push_back(outputDict);
173
174
175   //Read the number of slices and energy window, rotation
176   int nbSlice = input->GetLargestPossibleRegion().GetSize()[2];
177   gdcm::Reader hreader;
178   hreader.SetFileName(m_ArgsInfo.input_arg);
179   hreader.Read();
180   gdcm::DataSet& dsInput = hreader.GetFile().GetDataSet();
181   gdcm::Attribute<0x54,0x11> series_number_att;
182   series_number_att.SetFromDataSet(dsInput);
183   int nbEnergyWindow = series_number_att.GetValue();
184
185   const gdcm::DataElement &seqRotation = dsInput.GetDataElement(gdcm::Tag(0x54, 0x52));
186   gdcm::SmartPointer<gdcm::SequenceOfItems> sqiRotation = seqRotation.GetValueAsSQ();
187   gdcm::Item &itemRotation = sqiRotation->GetItem(1);
188   const gdcm::DataElement &deRotation = itemRotation.GetDataElement(gdcm::Tag(0x54, 0x53));
189   unsigned short SamplesPerPixelRotation = *((unsigned short *) deRotation.GetByteValue()->GetPointer());
190   std::stringstream s_SamplesPerPixelRotation;
191   s_SamplesPerPixelRotation << SamplesPerPixelRotation;
192   std::string p_StrRotation = s_SamplesPerPixelRotation.str();
193   int nbRotation = (int)atof(p_StrRotation.c_str());
194
195   int nbSlicePerEnergy = nbSlice / nbEnergyWindow;
196   if (nbSlicePerEnergy*nbEnergyWindow != nbSlice)
197     std::cerr << "Error: The number of slices is not correct !!" << std::endl;
198
199   for (unsigned int energy = 0; energy < nbEnergyWindow; ++energy) {
200     
201     //Create the output
202     typename InputImageType::Pointer energyImage = InputImageType::New();
203     energyImage->SetRegions(input->GetLargestPossibleRegion());
204     typename InputImageType::IndexType startIndex;
205     startIndex[0] = 0;
206     startIndex[1] = 0;
207     startIndex[2] = 0;//energy*nbSlicePerEnergy;
208     typename InputImageType::SizeType regionSize;
209     regionSize[0] = input->GetLargestPossibleRegion().GetSize()[0];
210     regionSize[1] = input->GetLargestPossibleRegion().GetSize()[1];
211     regionSize[2] = nbSlicePerEnergy;
212     typename InputImageType::RegionType region;
213     region.SetSize(regionSize);
214     region.SetIndex(startIndex);
215     energyImage->SetRegions(region);
216     energyImage->Allocate();
217
218     //Create the iterator on the output
219     itk::ImageRegionIterator<InputImageType> imageOutputIterator(energyImage,energyImage->GetLargestPossibleRegion());
220
221     //Create the iterator on the region of the input
222     typename InputImageType::IndexType startIndexIterator;
223     startIndexIterator[0] = 0;
224     startIndexIterator[1] = 0;
225     startIndexIterator[2] = energy*nbSlicePerEnergy;
226     typename InputImageType::RegionType regionIterator;
227     regionIterator.SetSize(regionSize);
228     regionIterator.SetIndex(startIndexIterator);
229     itk::ImageRegionIterator<InputImageType> imageInputIterator(input,regionIterator);
230
231     //Copy the requested region
232     while(!imageInputIterator.IsAtEnd())
233     {
234       imageOutputIterator.Set(imageInputIterator.Get());
235
236       ++imageInputIterator;
237       ++imageOutputIterator;
238     }
239
240     // Output directory and filenames
241     typename WriterType::Pointer writer = WriterType::New();
242     writer->SetInput( energyImage );
243     writer->SetImageIO( gdcmIO );
244     typename ReaderType::FileNamesContainer fileNamesOutput;
245     std::string extension = NumberToString(energy) + ".dcm";
246     std::string filename_out = m_ArgsInfo.output_arg + extension;
247     fileNamesOutput.push_back(filename_out);
248     writer->SetFileNames( fileNamesOutput );
249     writer->SetMetaDataDictionaryArray(&outputArray);
250
251     // Write
252     try {
253       if (m_ArgsInfo.verbose_flag)
254         std::cout << writer << std::endl;
255       writer->Update();
256     } catch( itk::ExceptionObject & excp ) {
257       std::cerr << "Error: Exception thrown while writing the series!!" << std::endl;
258       std::cerr << excp << std::endl;
259     }
260
261     //Write sequence dicom tag with gdcm
262     gdcm::Reader reader;
263     reader.SetFileName( filename_out.c_str() );
264     reader.Read();
265     gdcm::File &fileOutput = reader.GetFile();
266     gdcm::DataSet &dsOutput = fileOutput.GetDataSet();
267     const unsigned int ptr_len = 42;
268     char *ptr = new char[ptr_len];
269     memset(ptr,0,ptr_len);
270     //Write rotation tag
271     // Create a Sequence
272     gdcm::SmartPointer<gdcm::SequenceOfItems> rotationSq = new gdcm::SequenceOfItems();
273     rotationSq->SetLengthToUndefined();
274     // Create a dataelement
275     gdcm::DataElement rotationDE( gdcm::Tag(0x54, 0x53) );
276     rotationDE.SetVR( gdcm::VR::US );
277     char essai = (char)nbRotation;
278     char *p_essai = &essai;
279     rotationDE.SetByteValue(p_essai, 1);
280     // Create an item
281     gdcm::Item rotationIt;
282     rotationIt.SetVLToUndefined();
283     gdcm::DataSet &rotationDS = rotationIt.GetNestedDataSet();
284     rotationDS.Insert(rotationDE);
285     rotationSq->AddItem(rotationIt);
286     // Insert sequence into data set
287     gdcm::DataElement rotationDEParent( gdcm::Tag(0x54, 0x52) );
288     rotationDEParent.SetVR(gdcm::VR::SQ);
289     rotationDEParent.SetValue(*rotationSq);
290     rotationDEParent.SetVLToUndefined();
291     //Write energy
292     gdcm::DataElement energyDEParent( gdcm::Tag(0x54, 0x12) );
293     energyDEParent.SetVR(gdcm::VR::SQ);
294     // Create a Sequence
295     gdcm::SmartPointer<gdcm::SequenceOfItems> energySq = new gdcm::SequenceOfItems();
296     energySq->SetLengthToUndefined();
297
298     //Read the caracteristics of this energy window : the name and the thresholds up and down
299     const gdcm::DataElement &seqWindow = dsInput.GetDataElement(gdcm::Tag(0x54, 0x12));
300     gdcm::SmartPointer<gdcm::SequenceOfItems> sqiWindow = seqWindow.GetValueAsSQ();
301     gdcm::Item &itemWindow = sqiWindow->GetItem(energy+1);
302     const gdcm::DataElement &deNameWindow = itemWindow.GetDataElement(gdcm::Tag(0x54, 0x18));
303     std::string nameWindow( deNameWindow.GetByteValue()->GetPointer(), deNameWindow.GetByteValue()->GetLength() );
304
305     const gdcm::DataElement &deThresholds = itemWindow.GetDataElement(gdcm::Tag(0x54, 0x13));
306     gdcm::SmartPointer<gdcm::SequenceOfItems> sqiThresholds = deThresholds.GetValueAsSQ();
307     for (unsigned int nbWindow=1; nbWindow <= sqiThresholds->GetNumberOfItems() ; ++nbWindow) {
308       gdcm::Item &itemThresholds = sqiThresholds->GetItem(nbWindow);
309       const gdcm::DataElement &deThresholdDown = itemThresholds.GetDataElement(gdcm::Tag(0x54, 0x14));
310       std::string p_StrThresholdDown( deThresholdDown.GetByteValue()->GetPointer(), deThresholdDown.GetByteValue()->GetLength() );
311       double thresholdDown = (double)atof(p_StrThresholdDown.c_str());
312       const gdcm::DataElement &deThresholdUp = itemThresholds.GetDataElement(gdcm::Tag(0x54, 0x15));
313       std::string p_StrThresholdUp( deThresholdUp.GetByteValue()->GetPointer(), deThresholdUp.GetByteValue()->GetLength() );
314       double thresholdUp = (double)atof(p_StrThresholdUp.c_str());
315
316       //Now write it !
317       gdcm::SmartPointer<gdcm::SequenceOfItems> energyThresholdSq = new gdcm::SequenceOfItems();
318       energyThresholdSq->SetLengthToUndefined();
319       // Create a dataelement
320       gdcm::DataElement energyThresholdDE( gdcm::Tag(0x54, 0x14) );
321       gdcm::DataElement energyUpholdDE( gdcm::Tag(0x54, 0x15) );
322       energyThresholdDE.SetVR( gdcm::VR::DS );
323       energyUpholdDE.SetVR( gdcm::VR::DS );
324       energyThresholdDE.SetByteValue(NumberToString(thresholdDown).c_str(), (uint32_t)strlen(NumberToString(thresholdDown).c_str()));
325       energyUpholdDE.SetByteValue(NumberToString(thresholdUp).c_str(), (uint32_t)strlen(NumberToString(thresholdUp).c_str()));
326       // Create an item
327       gdcm::Item energyThresholdIt;
328       energyThresholdIt.SetVLToUndefined();
329       gdcm::DataSet &energyThresholdDS = energyThresholdIt.GetNestedDataSet();
330       energyThresholdDS.Insert(energyThresholdDE);
331       energyThresholdDS.Insert(energyUpholdDE);
332       energyThresholdSq->AddItem(energyThresholdIt);
333       // Insert sequence into data set
334       gdcm::DataElement energyThresholdDEParent( gdcm::Tag(0x54, 0x13) );
335       energyThresholdDEParent.SetVR(gdcm::VR::SQ);
336       energyThresholdDEParent.SetValue(*energyThresholdSq);
337       energyThresholdDEParent.SetVLToUndefined();
338       // Create a dataelement
339       gdcm::DataElement energyNameDE( gdcm::Tag(0x54, 0x18) );
340       energyNameDE.SetVR( gdcm::VR::SH );
341       energyNameDE.SetByteValue(nameWindow.c_str(), (uint32_t)strlen(nameWindow.c_str()));
342       // Create an item
343       gdcm::Item energyIt;
344       energyIt.SetVLToUndefined();
345       gdcm::DataSet &energyDS = energyIt.GetNestedDataSet();
346       energyDS.Insert(energyNameDE);
347       energyDS.Insert(energyThresholdDEParent);
348       energySq->AddItem(energyIt);
349     }
350     // Insert sequence into data set
351     energyDEParent.SetValue(*energySq);
352     energyDEParent.SetVLToUndefined();
353     dsOutput.Insert(energyDEParent);
354     dsOutput.Insert(rotationDEParent);
355     gdcm::Writer w;
356     w.SetFile( fileOutput );
357     w.SetFileName( filename_out.c_str() );
358     w.Write();
359   }
360 #else
361   std::cout << "Use GDCM2" << std::endl;
362 #endif
363 }
364 //---------------------------------------------------------------------------
365
366
367 //---------------------------------------------------------------------------
368 void CopyDictionary (itk::MetaDataDictionary &fromDict, itk::MetaDataDictionary &toDict)
369 {
370   typedef itk::MetaDataDictionary DictionaryType;
371
372   DictionaryType::ConstIterator itr = fromDict.Begin();
373   DictionaryType::ConstIterator end = fromDict.End();
374   typedef itk::MetaDataObject< std::string > MetaDataStringType;
375
376   while( itr != end )
377     {
378     itk::MetaDataObjectBase::Pointer  entry = itr->second;
379
380     MetaDataStringType::Pointer entryvalue =
381       dynamic_cast<MetaDataStringType *>( entry.GetPointer() ) ;
382     if( entryvalue )
383       {
384       std::string tagkey   = itr->first;
385       std::string tagvalue = entryvalue->GetMetaDataObjectValue();
386       itk::EncapsulateMetaData<std::string>(toDict, tagkey, tagvalue);
387       }
388     ++itr;
389     }
390 }
391 //---------------------------------------------------------------------------
392
393
394 //---------------------------------------------------------------------------
395 template <typename T> std::string NumberToString ( T Number )
396 {
397    std::ostringstream ss;
398    ss << Number;
399    return ss.str();
400 }
401 //---------------------------------------------------------------------------
402
403 }//end clitk
404
405 #endif //#define clitkPartitionEnergyWindowDicomGenericFilter_txx
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