Program: gdcm
Module: $RCSfile: exCurveData.cxx,v $
Language: C++
- Date: $Date: 2005/10/16 17:07:05 $
- Version: $Revision: 1.3 $
+ Date: $Date: 2008/03/10 14:30:08 $
+ Version: $Revision: 1.9 $
Copyright (c) CREATIS (Centre de Recherche et d'Applications en Traitement de
l'Image). All rights reserved. See Doc/License.txt or
#include "gdcmCommon.h"
#include "gdcmDebug.h"
#include "gdcmDocEntry.h"
-#include "gdcmBinEntry.h"
+#include "gdcmDataEntry.h"
static const char* TypeOfDataArrays[13][2] = {
{ "TAC" , "time activity curve" },
const char **p = *TypeOfDataArrays;
while(*p != NULL)
{
- if( p[0] == type ) // std::string== operator
+ if( strncmp(p[0], type.c_str(), strlen(p[0])) == 0 ) // std::string== operator
{
// ok we found it:
return p[1];
// ok this is ugly but I need the size outside of the function
return sizeof(DataValueRepresentation);
}
+
+template <int datarep> struct DataRepToType;
+template<> struct DataRepToType<0> { typedef unsigned short Type; };
+template<> struct DataRepToType<1> { typedef signed short Type; };
+template<> struct DataRepToType<2> { typedef float Type; };
+template<> struct DataRepToType<3> { typedef double Type; };
+template<> struct DataRepToType<4> { typedef signed long Type; };
/*
// Example (sorry, we've got no more than this one ...)
* V 5004|0020 [CS] [Type of Data] [PHYSIO]
* V 5004|0022 [LO] [Curve Description] []
* V 5004|0103 [US] [Data Value Representation] [0] x(0)
- * B 5004|3000 [OW] [Curve Data] [gdcm::Binary data loaded;length = 1938]
+ * B 5004|3000 [OW] [Curve Data] [GDCM_NAME_SPACE::Binary data loaded;length = 1938]
*/
int main(int argc, char *argv[])
{
- gdcm::File *f;
+ GDCM_NAME_SPACE::File *f;
std::cout << "------------------------------------------------" << std::endl;
std::cout << "Gets the 'Curve Data' from a full gdcm-readable DICOM " << std::endl;
// Read the input image.
// ============================================================
- f = new gdcm::File( );
+ f = GDCM_NAME_SPACE::File::New( );
- f->SetLoadMode(gdcm::LD_NOSEQ | gdcm::LD_NOSHADOW);
+ f->SetLoadMode(GDCM_NAME_SPACE::LD_NOSEQ | GDCM_NAME_SPACE::LD_NOSHADOW);
f->SetFileName( fileName );
+ f->SetMaxSizeLoadEntry(0xffff);
bool res = f->Load();
- if( gdcm::Debug::GetDebugFlag() )
+ if( GDCM_NAME_SPACE::Debug::GetDebugFlag() )
{
std::cout << "---------------------------------------------" << std::endl;
f->Print();
std::cout << "Sorry, " << fileName <<" not a gdcm-readable "
<< "DICOM / ACR File"
<<std::endl;
- delete f;
+ f->Delete();
return 1;
}
std::cout << " ... is readable " << std::endl;
// Check whether image contains Overlays ACR-NEMA style.
// ============================================================
- //* B 5004|3000 [OW] [Curve Data] [gdcm::Binary data loaded;length = 1938]
- std::string curve_data_str = f->GetEntryValue(0x5004, 0x3000);
- if (curve_data_str == gdcm::GDCM_UNFOUND)
+ const uint16_t curvedatagroup = 0x5000;
+ //* B 5004|3000 [OW] [Curve Data] [GDCM_NAME_SPACE::Binary data loaded;length = 1938]
+ std::string curve_data_str = f->GetEntryString(curvedatagroup, 0x3000);
+ if (curve_data_str == GDCM_NAME_SPACE::GDCM_UNFOUND)
{
std::cout << " Image doesn't contain any Curve Data" << std::endl;
- delete f;
+ f->Delete();
return 1;
}
std::cout << " File is read! " << std::endl;
// ============================================================
std::istringstream convert;
//* V 5004|0005 [US] [Curve Dimensions] [1] x(1)
- std::string curve_dim_str = f->GetEntryValue(0x5004,0x0005);
+ std::string curve_dim_str = f->GetEntryString(curvedatagroup,0x0005);
unsigned short curve_dim;
convert.str(curve_dim_str);
convert >> curve_dim;
std::cout << "Curve Dimensions: " << curve_dim << std::endl;
//* V 5004|0010 [US] [Number of Points] [969] x(3c9)
- std::string num_points_str = f->GetEntryValue(0x5004,0x0010);
+ std::string num_points_str = f->GetEntryString(curvedatagroup,0x0010);
unsigned short num_points;
convert.clear(); //important
convert.str(num_points_str);
convert >> num_points;
std::cout << "Number of Points: " << num_points << std::endl;
//* V 5004|0020 [CS] [Type of Data] [PHYSIO]
- std::string data_type = f->GetEntryValue(0x5004,0x0020);
+ std::string data_type = f->GetEntryString(curvedatagroup,0x0020);
std::cout << "Type of Data: " << data_type << std::endl;
- std::cout << " this is thus a : " << ConvertTypeOfData(data_type) << std::endl;
+ const char *datatype = ConvertTypeOfData(data_type);
+ std::cout << " this is thus a : " << (datatype ? datatype : "") << std::endl;
//* V 5004|0022 [LO] [Curve Description] []
- std::string curve_desc = f->GetEntryValue(0x5004,0x0022);
+ std::string curve_desc = f->GetEntryString(curvedatagroup,0x0022);
std::cout << "Curve Description: " << curve_desc << std::endl;
//* V 5004|0103 [US] [Data Value Representation] [0] x(0)
- std::string data_rep_str = f->GetEntryValue(0x5004,0x0103);
+ std::string data_rep_str = f->GetEntryString(curvedatagroup,0x0103);
unsigned short data_rep;
convert.clear(); //important
convert.str(data_rep_str);
convert >> data_rep;
- gdcm::DocEntry *pCurveDataDoc = f->GetDocEntry(0x5004, 0x3000);
- gdcm::BinEntry *pCurveData = dynamic_cast<gdcm::BinEntry*>(pCurveDataDoc);
+ GDCM_NAME_SPACE::DocEntry *pCurveDataDoc = f->GetDocEntry(curvedatagroup, 0x3000);
+ GDCM_NAME_SPACE::DataEntry *pCurveData = dynamic_cast<GDCM_NAME_SPACE::DataEntry *>(pCurveDataDoc);
uint8_t *curve_data = pCurveData->GetBinArea();
// From Part3, C.10.2.1.2 Data value representation (p668)
size_t sz;
+ int sizeofdatarep = 0;
switch( data_rep)
- {
- case 0:
- sz = PrintCurveData((unsigned short*)(curve_data), num_points);
- break;
- case 1:
- sz = PrintCurveData((signed short*)(curve_data), num_points);
- break;
- case 2:
- sz = PrintCurveData((float*)(curve_data), num_points);
- break;
- case 3:
- sz = PrintCurveData((double*)(curve_data), num_points);
- break;
- case 4:
- sz = PrintCurveData((signed long*)(curve_data), num_points);
- break;
- default:
- std::cerr << "Error don't know the type: " << data_rep_str << std::endl;
- delete f;
- return 1;
- }
+ {
+ case 0:
+ sz = PrintCurveData((DataRepToType<0>::Type*)(curve_data), num_points);
+ sizeofdatarep = sizeof( DataRepToType<0>::Type );
+ break;
+ case 1:
+ sz = PrintCurveData((DataRepToType<1>::Type*)(curve_data), num_points);
+ sizeofdatarep = sizeof( DataRepToType<1>::Type );
+ break;
+ case 2:
+ sz = PrintCurveData((DataRepToType<2>::Type*)(curve_data), num_points);
+ sizeofdatarep = sizeof( DataRepToType<2>::Type );
+ break;
+ case 3:
+ sz = PrintCurveData((DataRepToType<3>::Type*)(curve_data), num_points);
+ sizeofdatarep = sizeof( DataRepToType<3>::Type );
+ break;
+ case 4:
+ sz = PrintCurveData((DataRepToType<4>::Type*)(curve_data), num_points);
+ sizeofdatarep = sizeof( DataRepToType<4>::Type );
+ break;
+ default:
+ std::cerr << "Error don't know the type: " << data_rep_str << std::endl;
+ f->Delete();
+ return 1;
+ }
// Just to make sure that values read are consistant and we won't read out of bound data:
- assert( sz*num_points == pCurveData->GetLength());
+ //assert( sz*num_points*sizeofdatarep == pCurveData->GetLength());
// Write out the data as a file:
//std::ofstream o("/tmp/curve_data.raw");
//o.write((char*)curve_data, num_points*sz);
//o.close();
- delete f;
+ f->Delete();
return 0;
}