/*========================================================================= Program: gdcm Module: $RCSfile: gdcmFileHelper.cxx,v $ Language: C++ Date: $Date: 2005/10/23 15:24:47 $ Version: $Revision: 1.69 $ Copyright (c) CREATIS (Centre de Recherche et d'Applications en Traitement de l'Image). All rights reserved. See Doc/License.txt or http://www.creatis.insa-lyon.fr/Public/Gdcm/License.html for details. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the above copyright notices for more information. =========================================================================*/ #include "gdcmFileHelper.h" #include "gdcmGlobal.h" #include "gdcmTS.h" #include "gdcmDocument.h" #include "gdcmDebug.h" #include "gdcmUtil.h" #include "gdcmSeqEntry.h" #include "gdcmSQItem.h" #include "gdcmDataEntry.h" #include "gdcmFile.h" #include "gdcmPixelReadConvert.h" #include "gdcmPixelWriteConvert.h" #include "gdcmDocEntryArchive.h" #include "gdcmDictSet.h" #include /* // ----------------------------- WARNING ------------------------- These lines will be moved to the document-to-be 'User's Guide' // To read an image, user needs a gdcm::File gdcm::File *f = new gdcm::File(fileName); // or (advanced) : // user may also decide he doesn't want to load some parts of the header gdcm::File *f = new gdcm::File(); f->SetFileName(fileName); f->SetLoadMode(LD_NOSEQ); // or f->SetLoadMode(LD_NOSHADOW); // or f->SetLoadMode(LD_NOSEQ | LD_NOSHADOW); // or f->SetLoadMode(LD_NOSHADOWSEQ); f->Load(); // user can now check some values std::string v = f->GetEntryValue(groupNb,ElementNb); // to get the pixels, user needs a gdcm::FileHelper gdcm::FileHelper *fh = new gdcm::FileHelper(f); // user may ask not to convert Palette to RGB uint8_t *pixels = fh->GetImageDataRaw(); int imageLength = fh->GetImageDataRawSize(); // He can now use the pixels, create a new image, ... uint8_t *userPixels = ... To re-write the image, user re-uses the gdcm::FileHelper fh->SetImageData( userPixels, userPixelsLength); fh->SetTypeToRaw(); // Even if it was possible to convert Palette to RGB // (WriteMode is set) fh->SetWriteTypeToDcmExpl(); // he wants Explicit Value Representation // Little Endian is the default // no other value is allowed (-->SetWriteType(ExplicitVR);) -->WriteType = ExplicitVR; fh->Write(newFileName); // overwrites the file, if any // or : fh->WriteDcmExplVR(newFileName); // ----------------------------- WARNING ------------------------- These lines will be moved to the document-to-be 'Developer's Guide' WriteMode : WMODE_RAW / WMODE_RGB WriteType : ImplicitVR, ExplicitVR, ACR, ACR_LIBIDO fh1->Write(newFileName); SetWriteFileTypeToImplicitVR() / SetWriteFileTypeToExplicitVR(); (modifies TransferSyntax) SetWriteToRaw(); / SetWriteToRGB(); (modifies, when necessary : photochromatic interpretation, samples per pixel, Planar configuration, bits allocated, bits stored, high bit -ACR 24 bits- Pixels element VR, pushes out the LUT ) CheckWriteIntegrity(); (checks user given pixels length) FileInternal->Write(fileName,WriteType) fp = opens file(fileName); ComputeGroup0002Length( ); BitsAllocated 12->16 RemoveEntryNoDestroy(palettes, etc) Document::WriteContent(fp, writetype); RestoreWrite(); (moves back to the File all the archived elements) RestoreWriteFileType(); (pushes back group 0002, with TransferSyntax) */ namespace gdcm { //------------------------------------------------------------------------- // Constructor / Destructor /** * \brief Constructor dedicated to deal with the *pixels* area of a ACR/DICOMV3 * file (gdcm::File only deals with the ... header) * Opens (in read only and when possible) an existing file and checks * for DICOM compliance. Returns NULL on failure. * It will be up to the user to load the pixels into memory * ( GetImageDataSize() + GetImageData() methods) * \note the in-memory representation of all available tags found in * the DICOM header is post-poned to first header information access. * This avoid a double parsing of public part of the header when * one sets an a posteriori shadow dictionary (efficiency can be * seen as a side effect). */ FileHelper::FileHelper( ) { FileInternal = new File( ); SelfHeader = true; Initialize(); } /** * \brief Constructor dedicated to deal with the *pixels* area of a ACR/DICOMV3 * file (File only deals with the ... header) * Opens (in read only and when possible) an existing file and checks * for DICOM compliance. Returns NULL on failure. * It will be up to the user to load the pixels into memory * ( GetImageDataSize() + GetImageData() methods) * \note the in-memory representation of all available tags found in * the DICOM header is post-poned to first header information access. * This avoid a double parsing of public part of the header when * user sets an a posteriori shadow dictionary (efficiency can be * seen as a side effect). * @param header already built Header */ FileHelper::FileHelper(File *header) { FileInternal = header; SelfHeader = false; Initialize(); if ( FileInternal->IsReadable() ) { PixelReadConverter->GrabInformationsFromFile( FileInternal ); } } #ifndef GDCM_LEGACY_REMOVE /* * brief DEPRECATED : use SetFilename() + SetLoadMode() + Load() methods * Constructor dedicated to deal with the *pixels* area of a ACR/DICOMV3 * file (gdcm::File only deals with the ... header) * Opens (in read only and when possible) an existing file and checks * for DICOM compliance. Returns NULL on failure. * It will be up to the user to load the pixels into memory * note the in-memory representation of all available tags found in * the DICOM header is post-poned to first header information access. * This avoid a double parsing of public part of the header when * one sets an a posteriori shadow dictionary (efficiency can be * seen as a side effect). * param filename file to be opened for parsing * deprecated use SetFilename() + Load() methods */ FileHelper::FileHelper(std::string const &filename ) { FileInternal = new File( ); FileInternal->SetFileName( filename ); FileInternal->Load(); SelfHeader = true; Initialize(); if ( FileInternal->IsReadable() ) { PixelReadConverter->GrabInformationsFromFile( FileInternal ); } } #endif /** * \brief canonical destructor * \note If the header (gdcm::File) was created by the FileHelper constructor, * it is destroyed by the FileHelper */ FileHelper::~FileHelper() { if ( PixelReadConverter ) { delete PixelReadConverter; } if ( PixelWriteConverter ) { delete PixelWriteConverter; } if ( Archive ) { delete Archive; } if ( SelfHeader ) { delete FileInternal; } FileInternal = 0; } //----------------------------------------------------------------------------- // Public /** * \brief Sets the LoadMode of the internal gdcm::File as a boolean string. * NO_SEQ, NO_SHADOW, NO_SHADOWSEQ ... (nothing more, right now) * WARNING : before using NO_SHADOW, be sure *all* your files * contain accurate values in the 0x0000 element (if any) * of *each* Shadow Group. The parser will fail if the size is wrong ! * @param loadMode Load mode to be used */ void FileHelper::SetLoadMode(int loadMode) { GetFile()->SetLoadMode( loadMode ); } /** * \brief Sets the LoadMode of the internal gdcm::File * @param fileName name of the file to be open */ void FileHelper::SetFileName(std::string const &fileName) { FileInternal->SetFileName( fileName ); } /** * \brief Loader * @return false if file cannot be open or no swap info was found, * or no tag was found. */ bool FileHelper::Load() { if ( !FileInternal->Load() ) return false; PixelReadConverter->GrabInformationsFromFile( FileInternal ); return true; } /** * \brief Accesses an existing DocEntry (i.e. a Dicom Element) * through it's (group, element) and modifies it's content with * the given value. * @param content new value (string) to substitute with * @param group group number of the Dicom Element to modify * @param elem element number of the Dicom Element to modify * \return false if DocEntry not found */ bool FileHelper::SetEntryString(std::string const &content, uint16_t group, uint16_t elem) { return FileInternal->SetEntryString(content, group, elem); } /** * \brief Accesses an existing DocEntry (i.e. a Dicom Element) * through it's (group, element) and modifies it's content with * the given value. * @param content new value (void* -> uint8_t*) to substitute with * @param lgth new value length * @param group group number of the Dicom Element to modify * @param elem element number of the Dicom Element to modify * \return false if DocEntry not found */ bool FileHelper::SetEntryBinArea(uint8_t *content, int lgth, uint16_t group, uint16_t elem) { return FileInternal->SetEntryBinArea(content, lgth, group, elem); } /** * \brief Modifies the value of a given DocEntry (Dicom entry) * when it exists. Creates it with the given value when unexistant. * @param content (string)value to be set * @param group Group number of the Entry * @param elem Element number of the Entry * \return pointer to the modified/created Dicom entry (NULL when creation * failed). */ DataEntry *FileHelper::InsertEntryString(std::string const &content, uint16_t group, uint16_t elem) { return FileInternal->InsertEntryString(content, group, elem); } /** * \brief Modifies the value of a given DocEntry (Dicom entry) * when it exists. Creates it with the given value when unexistant. * A copy of the binArea is made to be kept in the Document. * @param binArea (binary)value to be set * @param lgth new value length * @param group Group number of the Entry * @param elem Element number of the Entry * \return pointer to the modified/created Dicom entry (NULL when creation * failed). */ DataEntry *FileHelper::InsertEntryBinArea(uint8_t *binArea, int lgth, uint16_t group, uint16_t elem) { return FileInternal->InsertEntryBinArea(binArea, lgth, group, elem); } /** * \brief Modifies the value of a given DocEntry (Dicom entry) * when it exists. Creates it, empty (?!) when unexistant. * @param group Group number of the Entry * @param elem Element number of the Entry * \return pointer to the modified/created Dicom entry (NULL when creation * failed). */ SeqEntry *FileHelper::InsertSeqEntry(uint16_t group, uint16_t elem) { return FileInternal->InsertSeqEntry(group, elem); } /** * \brief Get the size of the image data * If the image can be RGB (with a lut or by default), the size * corresponds to the RGB image * (use GetImageDataRawSize if you want to be sure to get *only* * the size of the pixels) * @return The image size */ size_t FileHelper::GetImageDataSize() { if ( PixelWriteConverter->GetUserData() ) { return PixelWriteConverter->GetUserDataSize(); } return PixelReadConverter->GetRGBSize(); } /** * \brief Get the size of the image data. * If the image could be converted to RGB using a LUT, * this transformation is not taken into account by GetImageDataRawSize * (use GetImageDataSize if you wish) * @return The raw image size */ size_t FileHelper::GetImageDataRawSize() { if ( PixelWriteConverter->GetUserData() ) { return PixelWriteConverter->GetUserDataSize(); } return PixelReadConverter->GetRawSize(); } /** * \brief brings pixels into memory : * - Allocates necessary memory, * - Reads the pixels from disk (uncompress if necessary), * - Transforms YBR pixels, if any, into RGB pixels, * - Transforms 3 planes R, G, B, if any, into a single RGB Plane * - Transforms single Grey plane + 3 Palettes into a RGB Plane * - Copies the pixel data (image[s]/volume[s]) to newly allocated zone. * @return Pointer to newly allocated pixel data. * NULL if alloc fails */ uint8_t *FileHelper::GetImageData() { if ( PixelWriteConverter->GetUserData() ) { return PixelWriteConverter->GetUserData(); } if ( ! GetRaw() ) { // If the decompression failed nothing can be done. return 0; } if ( FileInternal->HasLUT() && PixelReadConverter->BuildRGBImage() ) { return PixelReadConverter->GetRGB(); } else { // When no LUT or LUT conversion fails, return the Raw return PixelReadConverter->GetRaw(); } } /** * \brief brings pixels into memory : * - Allocates necessary memory, * - Transforms YBR pixels (if any) into RGB pixels * - Transforms 3 planes R, G, B (if any) into a single RGB Plane * - Copies the pixel data (image[s]/volume[s]) to newly allocated zone. * - DOES NOT transform Grey plane + 3 Palettes into a RGB Plane * @return Pointer to newly allocated pixel data. * NULL if alloc fails */ uint8_t *FileHelper::GetImageDataRaw () { return GetRaw(); } #ifndef GDCM_LEGACY_REMOVE /* * \ brief Useless function, since PixelReadConverter forces us * copy the Pixels anyway. * Reads the pixels from disk (uncompress if necessary), * Transforms YBR pixels, if any, into RGB pixels * Transforms 3 planes R, G, B, if any, into a single RGB Plane * Transforms single Grey plane + 3 Palettes into a RGB Plane * Copies at most MaxSize bytes of pixel data to caller allocated * memory space. * \ warning This function allows people that want to build a volume * from an image stack *not to* have, first to get the image pixels, * and then move them to the volume area. * It's absolutely useless for any VTK user since vtk chooses * to invert the lines of an image, that is the last line comes first * (for some axis related reasons?). Hence he will have * to load the image line by line, starting from the end. * VTK users have to call GetImageData * * @ param destination Address (in caller's memory space) at which the * pixel data should be copied * @ param maxSize Maximum number of bytes to be copied. When MaxSize * is not sufficient to hold the pixel data the copy is not * executed (i.e. no partial copy). * @ return On success, the number of bytes actually copied. Zero on * failure e.g. MaxSize is lower than necessary. */ size_t FileHelper::GetImageDataIntoVector (void *destination, size_t maxSize) { if ( ! GetRaw() ) { // If the decompression failed nothing can be done. return 0; } if ( FileInternal->HasLUT() && PixelReadConverter->BuildRGBImage() ) { if ( PixelReadConverter->GetRGBSize() > maxSize ) { gdcmWarningMacro( "Pixel data bigger than caller's expected MaxSize"); return 0; } memcpy( destination, (void*)PixelReadConverter->GetRGB(), PixelReadConverter->GetRGBSize() ); return PixelReadConverter->GetRGBSize(); } // Either no LUT conversion necessary or LUT conversion failed if ( PixelReadConverter->GetRawSize() > maxSize ) { gdcmWarningMacro( "Pixel data bigger than caller's expected MaxSize"); return 0; } memcpy( destination, (void *)PixelReadConverter->GetRaw(), PixelReadConverter->GetRawSize() ); return PixelReadConverter->GetRawSize(); } #endif /** * \brief Points the internal pointer to the callers inData * image representation, BUT WITHOUT COPYING THE DATA. * 'image' Pixels are presented as C-like 2D arrays : line per line. * 'volume'Pixels are presented as C-like 3D arrays : plane per plane * \warning Since the pixels are not copied, it is the caller's responsability * not to deallocate its data before gdcm uses them (e.g. with * the Write() method ) * @param inData user supplied pixel area (uint8_t* is just for the compiler. * user is allowed to pass any kind of pixelsn since the size is * given in bytes) * @param expectedSize total image size, *in Bytes* */ void FileHelper::SetImageData(uint8_t *inData, size_t expectedSize) { SetUserData(inData, expectedSize); } /** * \brief Set the image data defined by the user * \warning When writting the file, this data are get as default data to write * @param inData user supplied pixel area (uint8_t* is just for the compiler. * user is allowed to pass any kind of pixels since the size is * given in bytes) * @param expectedSize total image size, *in Bytes* */ void FileHelper::SetUserData(uint8_t *inData, size_t expectedSize) { PixelWriteConverter->SetUserData(inData, expectedSize); } /** * \brief Get the image data defined by the user * \warning When writting the file, this data are get as default data to write */ uint8_t *FileHelper::GetUserData() { return PixelWriteConverter->GetUserData(); } /** * \brief Get the image data size defined by the user * \warning When writting the file, this data are get as default data to write */ size_t FileHelper::GetUserDataSize() { return PixelWriteConverter->GetUserDataSize(); } /** * \brief Get the image data from the file. * If a LUT is found, the data are expanded to be RGB */ uint8_t *FileHelper::GetRGBData() { return PixelReadConverter->GetRGB(); } /** * \brief Get the image data size from the file. * If a LUT is found, the data are expanded to be RGB */ size_t FileHelper::GetRGBDataSize() { return PixelReadConverter->GetRGBSize(); } /** * \brief Get the image data from the file. * Even when a LUT is found, the data are not expanded to RGB! */ uint8_t *FileHelper::GetRawData() { return PixelReadConverter->GetRaw(); } /** * \brief Get the image data size from the file. * Even when a LUT is found, the data are not expanded to RGB! */ size_t FileHelper::GetRawDataSize() { return PixelReadConverter->GetRawSize(); } /** * \brief Access to the underlying \ref PixelReadConverter RGBA LUT */ uint8_t* FileHelper::GetLutRGBA() { if ( PixelReadConverter->GetLutRGBA() ==0 ) PixelReadConverter->BuildLUTRGBA(); return PixelReadConverter->GetLutRGBA(); } /** * \brief Access to the underlying \ref PixelReadConverter RGBA LUT Item Number */ int FileHelper::GetLutItemNumber() { return PixelReadConverter->GetLutItemNumber(); } /** * \brief Access to the underlying \ref PixelReadConverter RGBA LUT Item Size */ int FileHelper::GetLutItemSize() { return PixelReadConverter->GetLutItemSize(); } /** * \brief Writes on disk A SINGLE Dicom file * NO test is performed on processor "Endiannity". * It's up to the user to call his Reader properly * @param fileName name of the file to be created * (any already existing file is over written) * @return false if write fails */ bool FileHelper::WriteRawData(std::string const &fileName) { std::ofstream fp1(fileName.c_str(), std::ios::out | std::ios::binary ); if (!fp1) { gdcmWarningMacro( "Fail to open (write) file:" << fileName.c_str()); return false; } if ( PixelWriteConverter->GetUserData() ) { fp1.write( (char *)PixelWriteConverter->GetUserData(), PixelWriteConverter->GetUserDataSize() ); } else if ( PixelReadConverter->GetRGB() ) { fp1.write( (char *)PixelReadConverter->GetRGB(), PixelReadConverter->GetRGBSize()); } else if ( PixelReadConverter->GetRaw() ) { fp1.write( (char *)PixelReadConverter->GetRaw(), PixelReadConverter->GetRawSize()); } else { gdcmErrorMacro( "Nothing written." ); } fp1.close(); return true; } /** * \brief Writes on disk A SINGLE Dicom file, * using the Implicit Value Representation convention * NO test is performed on processor "Endianity". * @param fileName name of the file to be created * (any already existing file is overwritten) * @return false if write fails */ bool FileHelper::WriteDcmImplVR (std::string const &fileName) { SetWriteTypeToDcmImplVR(); return Write(fileName); } /** * \brief Writes on disk A SINGLE Dicom file, * using the Explicit Value Representation convention * NO test is performed on processor "Endiannity". * @param fileName name of the file to be created * (any already existing file is overwritten) * @return false if write fails */ bool FileHelper::WriteDcmExplVR (std::string const &fileName) { SetWriteTypeToDcmExplVR(); return Write(fileName); } /** * \brief Writes on disk A SINGLE Dicom file, * using the ACR-NEMA convention * NO test is performed on processor "Endiannity". * (a l'attention des logiciels cliniques * qui ne prennent en entrée QUE des images ACR ... * \warning if a DICOM_V3 header is supplied, * groups < 0x0008 and shadow groups are ignored * \warning NO TEST is performed on processor "Endiannity". * @param fileName name of the file to be created * (any already existing file is overwritten) * @return false if write fails */ bool FileHelper::WriteAcr (std::string const &fileName) { SetWriteTypeToAcr(); return Write(fileName); } /** * \brief Writes on disk A SINGLE Dicom file, * @param fileName name of the file to be created * (any already existing file is overwritten) * @return false if write fails */ bool FileHelper::Write(std::string const &fileName) { switch(WriteType) { case ImplicitVR: SetWriteFileTypeToImplicitVR(); break; case Unknown: // should never happen; ExplicitVR is the default value case ExplicitVR: SetWriteFileTypeToExplicitVR(); break; case ACR: case ACR_LIBIDO: // NOTHING is done here just for LibIDO. // Just to avoid further trouble if user creates a file ex-nihilo, // wants to write it as an ACR-NEMA file, // and forgets to create any Entry belonging to group 0008 // (shame on him !) // We add Recognition Code (RET) if ( ! FileInternal->GetDataEntry(0x0008, 0x0010) ) FileInternal->InsertEntryString("ACR-NEMA V1.0 ", 0x0008, 0x0010); SetWriteFileTypeToACR(); // SetWriteFileTypeToImplicitVR(); // ACR IS implicit VR ! break; case JPEG: SetWriteFileTypeToJPEG(); std::cerr << "Writting as JPEG" << std::endl; break; } CheckMandatoryElements(); // -------------------------------------------------------------- // Special Patch to allow gdcm to re-write ACR-LibIDO formated images // // if recognition code tells us we dealt with a LibIDO image // we reproduce on disk the switch between lineNumber and columnNumber // just before writting ... /// \todo the best trick would be *change* the recognition code /// but pb expected if user deals with, e.g. COMPLEX images if ( WriteType == ACR_LIBIDO ) { SetWriteToLibido(); } else { SetWriteToNoLibido(); } // ----------------- End of Special Patch ---------------- switch(WriteMode) { case WMODE_RAW : SetWriteToRaw(); // modifies and pushes to the archive, when necessary break; case WMODE_RGB : SetWriteToRGB(); // modifies and pushes to the archive, when necessary break; } bool check = CheckWriteIntegrity(); // verifies length if (WriteType == JPEG ) check = true; if (check) { check = FileInternal->Write(fileName,WriteType); } RestoreWrite(); RestoreWriteFileType(); RestoreWriteMandatory(); // -------------------------------------------------------------- // Special Patch to allow gdcm to re-write ACR-LibIDO formated images // // ...and we restore the header to be Dicom Compliant again // just after writting RestoreWriteOfLibido(); // ----------------- End of Special Patch ---------------- return check; } //----------------------------------------------------------------------------- // Protected /** * \brief Checks the write integrity * * The tests made are : * - verify the size of the image to write with the possible write * when the user set an image data * @return true if check is successfull */ bool FileHelper::CheckWriteIntegrity() { if ( PixelWriteConverter->GetUserData() ) { int numberBitsAllocated = FileInternal->GetBitsAllocated(); if ( numberBitsAllocated == 0 || numberBitsAllocated == 12 ) { gdcmWarningMacro( "numberBitsAllocated changed from " << numberBitsAllocated << " to 16 " << " for consistency purpose" ); numberBitsAllocated = 16; } size_t decSize = FileInternal->GetXSize() * FileInternal->GetYSize() * FileInternal->GetZSize() * FileInternal->GetSamplesPerPixel() * ( numberBitsAllocated / 8 ); size_t rgbSize = decSize; if ( FileInternal->HasLUT() ) rgbSize = decSize * 3; switch(WriteMode) { case WMODE_RAW : if ( decSize!=PixelWriteConverter->GetUserDataSize() ) { gdcmWarningMacro( "Data size (Raw) is incorrect. Should be " << decSize << " / Found :" << PixelWriteConverter->GetUserDataSize() ); return false; } break; case WMODE_RGB : if ( rgbSize!=PixelWriteConverter->GetUserDataSize() ) { gdcmWarningMacro( "Data size (RGB) is incorrect. Should be " << decSize << " / Found " << PixelWriteConverter->GetUserDataSize() ); return false; } break; } } return true; } /** * \brief Updates the File to write RAW data (as opposed to RGB data) * (modifies, when necessary, photochromatic interpretation, * bits allocated, Pixels element VR) */ void FileHelper::SetWriteToRaw() { if ( FileInternal->GetNumberOfScalarComponents() == 3 && !FileInternal->HasLUT() ) { SetWriteToRGB(); } else { DataEntry *photInt = CopyDataEntry(0x0028,0x0004); if (FileInternal->HasLUT() ) { photInt->SetString("PALETTE COLOR "); } else { photInt->SetString("MONOCHROME2 "); } PixelWriteConverter->SetReadData(PixelReadConverter->GetRaw(), PixelReadConverter->GetRawSize()); std::string vr = "OB"; if ( FileInternal->GetBitsAllocated()>8 ) vr = "OW"; if ( FileInternal->GetBitsAllocated()==24 ) // For RGB ACR files vr = "OB"; DataEntry *pixel = CopyDataEntry(GetFile()->GetGrPixel(),GetFile()->GetNumPixel(),vr); pixel->SetFlag(DataEntry::FLAG_PIXELDATA); pixel->SetBinArea(PixelWriteConverter->GetData(),false); pixel->SetLength(PixelWriteConverter->GetDataSize()); Archive->Push(photInt); Archive->Push(pixel); } } /** * \brief Updates the File to write RGB data (as opposed to RAW data) * (modifies, when necessary, photochromatic interpretation, * samples per pixel, Planar configuration, * bits allocated, bits stored, high bit -ACR 24 bits- * Pixels element VR, pushes out the LUT, ) */ void FileHelper::SetWriteToRGB() { if ( FileInternal->GetNumberOfScalarComponents()==3 ) { PixelReadConverter->BuildRGBImage(); DataEntry *spp = CopyDataEntry(0x0028,0x0002); spp->SetString("3 "); DataEntry *planConfig = CopyDataEntry(0x0028,0x0006); planConfig->SetString("0 "); DataEntry *photInt = CopyDataEntry(0x0028,0x0004); photInt->SetString("RGB "); if ( PixelReadConverter->GetRGB() ) { PixelWriteConverter->SetReadData(PixelReadConverter->GetRGB(), PixelReadConverter->GetRGBSize()); } else // Raw data { PixelWriteConverter->SetReadData(PixelReadConverter->GetRaw(), PixelReadConverter->GetRawSize()); } std::string vr = "OB"; if ( FileInternal->GetBitsAllocated()>8 ) vr = "OW"; if ( FileInternal->GetBitsAllocated()==24 ) // For RGB ACR files vr = "OB"; DataEntry *pixel = CopyDataEntry(GetFile()->GetGrPixel(),GetFile()->GetNumPixel(),vr); pixel->SetFlag(DataEntry::FLAG_PIXELDATA); pixel->SetBinArea(PixelWriteConverter->GetData(),false); pixel->SetLength(PixelWriteConverter->GetDataSize()); Archive->Push(spp); Archive->Push(planConfig); Archive->Push(photInt); Archive->Push(pixel); // Remove any LUT Archive->Push(0x0028,0x1101); Archive->Push(0x0028,0x1102); Archive->Push(0x0028,0x1103); Archive->Push(0x0028,0x1201); Archive->Push(0x0028,0x1202); Archive->Push(0x0028,0x1203); // push out Palette Color Lookup Table UID, if any Archive->Push(0x0028,0x1199); // For old '24 Bits' ACR-NEMA // Thus, we have a RGB image and the bits allocated = 24 and // samples per pixels = 1 (in the read file) if ( FileInternal->GetBitsAllocated()==24 ) { DataEntry *bitsAlloc = CopyDataEntry(0x0028,0x0100); bitsAlloc->SetString("8 "); DataEntry *bitsStored = CopyDataEntry(0x0028,0x0101); bitsStored->SetString("8 "); DataEntry *highBit = CopyDataEntry(0x0028,0x0102); highBit->SetString("7 "); Archive->Push(bitsAlloc); Archive->Push(bitsStored); Archive->Push(highBit); } } else { SetWriteToRaw(); } } /** * \brief Restore the File write mode */ void FileHelper::RestoreWrite() { Archive->Restore(0x0028,0x0002); Archive->Restore(0x0028,0x0004); Archive->Restore(0x0028,0x0006); Archive->Restore(GetFile()->GetGrPixel(),GetFile()->GetNumPixel()); // For old ACR-NEMA (24 bits problem) Archive->Restore(0x0028,0x0100); Archive->Restore(0x0028,0x0101); Archive->Restore(0x0028,0x0102); // For the LUT Archive->Restore(0x0028,0x1101); Archive->Restore(0x0028,0x1102); Archive->Restore(0x0028,0x1103); Archive->Restore(0x0028,0x1201); Archive->Restore(0x0028,0x1202); Archive->Restore(0x0028,0x1203); // For the Palette Color Lookup Table UID Archive->Restore(0x0028,0x1203); // group 0002 may be pushed out for ACR-NEMA writting purposes Archive->Restore(0x0002,0x0000); Archive->Restore(0x0002,0x0001); Archive->Restore(0x0002,0x0002); Archive->Restore(0x0002,0x0003); Archive->Restore(0x0002,0x0010); Archive->Restore(0x0002,0x0012); Archive->Restore(0x0002,0x0013); Archive->Restore(0x0002,0x0016); Archive->Restore(0x0002,0x0100); Archive->Restore(0x0002,0x0102); } /** * \brief Pushes out the whole group 0002 * FIXME : better, set a flag to tell the writer not to write it ... * FIXME : method should probably have an other name ! * SetWriteFileTypeToACR is NOT opposed to * SetWriteFileTypeToExplicitVR and SetWriteFileTypeToImplicitVR */ void FileHelper::SetWriteFileTypeToACR() { Archive->Push(0x0002,0x0000); Archive->Push(0x0002,0x0001); Archive->Push(0x0002,0x0002); Archive->Push(0x0002,0x0003); Archive->Push(0x0002,0x0010); Archive->Push(0x0002,0x0012); Archive->Push(0x0002,0x0013); Archive->Push(0x0002,0x0016); Archive->Push(0x0002,0x0100); Archive->Push(0x0002,0x0102); } /** * \brief Sets in the File the TransferSyntax to 'Explicit VR Little Endian" */ void FileHelper::SetWriteFileTypeToJPEG() { std::string ts = Util::DicomString( Global::GetTS()->GetSpecialTransferSyntax(TS::JPEGBaselineProcess1) ); DataEntry *tss = CopyDataEntry(0x0002,0x0010); tss->SetString(ts); Archive->Push(tss); } void FileHelper::SetWriteFileTypeToExplicitVR() { std::string ts = Util::DicomString( Global::GetTS()->GetSpecialTransferSyntax(TS::ExplicitVRLittleEndian) ); DataEntry *tss = CopyDataEntry(0x0002,0x0010); tss->SetString(ts); Archive->Push(tss); } /** * \brief Sets in the File the TransferSyntax to 'Implicit VR Little Endian" */ void FileHelper::SetWriteFileTypeToImplicitVR() { std::string ts = Util::DicomString( Global::GetTS()->GetSpecialTransferSyntax(TS::ImplicitVRLittleEndian) ); DataEntry *tss = CopyDataEntry(0x0002,0x0010); tss->SetString(ts); Archive->Push(tss); } /** * \brief Restore in the File the initial group 0002 */ void FileHelper::RestoreWriteFileType() { } /** * \brief Set the Write not to Libido format */ void FileHelper::SetWriteToLibido() { DataEntry *oldRow = FileInternal->GetDataEntry(0x0028, 0x0010); DataEntry *oldCol = FileInternal->GetDataEntry(0x0028, 0x0011); if ( oldRow && oldCol ) { std::string rows, columns; DataEntry *newRow=new DataEntry(oldRow->GetDictEntry()); DataEntry *newCol=new DataEntry(oldCol->GetDictEntry()); newRow->Copy(oldCol); newCol->Copy(oldRow); newRow->SetString(oldCol->GetString()); newCol->SetString(oldRow->GetString()); Archive->Push(newRow); Archive->Push(newCol); } DataEntry *libidoCode = CopyDataEntry(0x0008,0x0010); libidoCode->SetString("ACRNEMA_LIBIDO_1.1"); Archive->Push(libidoCode); } /** * \brief Set the Write not to No Libido format */ void FileHelper::SetWriteToNoLibido() { DataEntry *recCode = FileInternal->GetDataEntry(0x0008,0x0010); if ( recCode ) { if ( recCode->GetString() == "ACRNEMA_LIBIDO_1.1" ) { DataEntry *libidoCode = CopyDataEntry(0x0008,0x0010); libidoCode->SetString(""); Archive->Push(libidoCode); } } } /** * \brief Restore the Write format */ void FileHelper::RestoreWriteOfLibido() { Archive->Restore(0x0028,0x0010); Archive->Restore(0x0028,0x0011); Archive->Restore(0x0008,0x0010); // Restore 'LibIDO-special' entries, if any Archive->Restore(0x0028,0x0015); Archive->Restore(0x0028,0x0016); Archive->Restore(0x0028,0x0017); Archive->Restore(0x0028,0x00199); } /** * \brief Duplicates a DataEntry or creates it. * @param group Group number of the Entry * @param elem Element number of the Entry * @param vr Value Representation of the Entry * FIXME : what is it used for? * \return pointer to the new Bin Entry (NULL when creation failed). */ DataEntry *FileHelper::CopyDataEntry(uint16_t group, uint16_t elem, const TagName &vr) { DocEntry *oldE = FileInternal->GetDocEntry(group, elem); DataEntry *newE; if ( oldE && vr != GDCM_VRUNKNOWN ) if ( oldE->GetVR() != vr ) oldE = NULL; if ( oldE ) { newE = new DataEntry(oldE->GetDictEntry()); newE->Copy(oldE); } else { newE = GetFile()->NewDataEntry(group, elem, vr); } return newE; } /** * \brief This method is called automatically, just before writting * in order to produce a 'True Dicom V3' image * We cannot know *how* the user made the File (reading an old ACR-NEMA * file or a not very clean DICOM file ...) * * Just before writting : * - we check the Entries * - we create the mandatory entries if they are missing * - we modify the values if necessary * - we push the sensitive entries to the Archive * The writing process will restore the entries as they where before * entering FileHelper::CheckMandatoryElements, so the user will always * see the entries just as he left them. * * \todo : - warn the user if we had to add some entries : * even if a mandatory entry is missing, we add it, with a default value * (we don't want to give up the writting process if user forgot to * specify Lena's Patient ID, for instance ...) * - read the whole PS 3.3 Part of DICOM (890 pages) * and write a *full* checker (probably one method per Modality ...) * Any contribution is welcome. * - write a user callable full checker, to allow post reading * and/or pre writting image consistency check. */ void FileHelper::CheckMandatoryElements() { std::string sop = Util::CreateUniqueUID(); // just to remember : 'official' 0002 group if ( WriteType != ACR && WriteType != ACR_LIBIDO ) { // Group 000002 (Meta Elements) already pushed out //0002 0000 UL 1 Meta Group Length //0002 0001 OB 1 File Meta Information Version //0002 0002 UI 1 Media Stored SOP Class UID //0002 0003 UI 1 Media Stored SOP Instance UID //0002 0010 UI 1 Transfer Syntax UID //0002 0012 UI 1 Implementation Class UID //0002 0013 SH 1 Implementation Version Name //0002 0016 AE 1 Source Application Entity Title //0002 0100 UI 1 Private Information Creator //0002 0102 OB 1 Private Information // Create them if not found // Always modify the value // Push the entries to the archive. CopyMandatoryEntry(0x0002,0x0000,"0"); DataEntry *e_0002_0001 = CopyDataEntry(0x0002,0x0001, "OB"); e_0002_0001->SetBinArea((uint8_t*)Util::GetFileMetaInformationVersion(), false); e_0002_0001->SetLength(2); Archive->Push(e_0002_0001); // Potentialy post-processed image --> [Secondary Capture Image Storage] // 'Media Storage SOP Class UID' CopyMandatoryEntry(0x0002,0x0002,"1.2.840.10008.5.1.4.1.1.7"); // 'Media Storage SOP Instance UID' CopyMandatoryEntry(0x0002,0x0003,sop); // 'Implementation Class UID' CopyMandatoryEntry(0x0002,0x0012,Util::CreateUniqueUID()); // 'Implementation Version Name' std::string version = "GDCM "; version += Util::GetVersion(); CopyMandatoryEntry(0x0002,0x0013,version); } // Push out 'LibIDO-special' entries, if any Archive->Push(0x0028,0x0015); Archive->Push(0x0028,0x0016); Archive->Push(0x0028,0x0017); Archive->Push(0x0028,0x00199); // Deal with the pb of (Bits Stored = 12) // - we're gonna write the image as Bits Stored = 16 if ( FileInternal->GetEntryString(0x0028,0x0100) == "12") { CopyMandatoryEntry(0x0028,0x0100,"16"); } // Check if user wasn't drunk ;-) std::ostringstream s; // check 'Bits Allocated' vs decent values int nbBitsAllocated = FileInternal->GetBitsAllocated(); if ( nbBitsAllocated == 0 || nbBitsAllocated > 32) { CopyMandatoryEntry(0x0028,0x0100,"16"); gdcmWarningMacro("(0028,0100) changed from " << nbBitsAllocated << " to 16 for consistency purpose"); nbBitsAllocated = 16; } // check 'Bits Stored' vs 'Bits Allocated' int nbBitsStored = FileInternal->GetBitsStored(); if ( nbBitsStored == 0 || nbBitsStored > nbBitsAllocated ) { s.str(""); s << nbBitsAllocated; CopyMandatoryEntry(0x0028,0x0101,s.str()); gdcmWarningMacro("(0028,0101) changed from " << nbBitsStored << " to " << nbBitsAllocated << " for consistency purpose" ); nbBitsStored = nbBitsAllocated; } // check 'Hight Bit Position' vs 'Bits Allocated' and 'Bits Stored' int highBitPosition = FileInternal->GetHighBitPosition(); if ( highBitPosition == 0 || highBitPosition > nbBitsAllocated-1 || highBitPosition < nbBitsStored-1 ) { s.str(""); s << nbBitsStored - 1; CopyMandatoryEntry(0x0028,0x0102,s.str()); gdcmWarningMacro("(0028,0102) changed from " << highBitPosition << " to " << nbBitsAllocated-1 << " for consistency purpose"); } // --- Check UID-related Entries --- // If 'SOP Class UID' exists ('true DICOM' image) // we create the 'Source Image Sequence' SeqEntry // to hold informations about the Source Image DataEntry *e_0008_0016 = FileInternal->GetDataEntry(0x0008, 0x0016); if ( e_0008_0016 ) { // Create 'Source Image Sequence' SeqEntry SeqEntry *sis = new SeqEntry ( Global::GetDicts()->GetDefaultPubDict()->GetEntry(0x0008, 0x2112) ); SQItem *sqi = new SQItem(1); // (we assume 'SOP Instance UID' exists too) // create 'Referenced SOP Class UID' DataEntry *e_0008_1150 = new DataEntry( Global::GetDicts()->GetDefaultPubDict()->GetEntry(0x0008, 0x1150) ); e_0008_1150->SetString( e_0008_0016->GetString()); sqi->AddEntry(e_0008_1150); // create 'Referenced SOP Instance UID' DataEntry *e_0008_0018 = FileInternal->GetDataEntry(0x0008, 0x0018); DataEntry *e_0008_1155 = new DataEntry( Global::GetDicts()->GetDefaultPubDict()->GetEntry(0x0008, 0x1155) ); e_0008_1155->SetString( e_0008_0018->GetString()); sqi->AddEntry(e_0008_1155); sis->AddSQItem(sqi,1); // temporarily replaces any previous 'Source Image Sequence' Archive->Push(sis); // 'Image Type' (The written image is no longer an 'ORIGINAL' one) CopyMandatoryEntry(0x0008,0x0008,"DERIVED\\PRIMARY"); } // At the end, not to overwrite the original ones, // needed by 'Referenced SOP Instance UID', 'Referenced SOP Class UID' // 'SOP Instance UID' CopyMandatoryEntry(0x0008,0x0018,sop); // whether a 'SOP Class UID' already exists or not in the original image // the gdcm written image *is* a [Secondary Capture Image Storage] ! // 'SOP Class UID' : [Secondary Capture Image Storage] CopyMandatoryEntry(0x0008,0x0016,"1.2.840.10008.5.1.4.1.1.7"); // ---- The user will never have to take any action on the following ----. // new value for 'SOP Instance UID' //SetMandatoryEntry(0x0008,0x0018,Util::CreateUniqueUID()); // Instance Creation Date CopyMandatoryEntry(0x0008,0x0012,Util::GetCurrentDate().c_str()); // Instance Creation Time CopyMandatoryEntry(0x0008,0x0013,Util::GetCurrentTime().c_str()); // ----- Add Mandatory Entries if missing --- // Entries whose type is 1 are mandatory, with a mandatory value // Entries whose type is 1c are mandatory-inside-a-Sequence, // with a mandatory value // Entries whose type is 2 are mandatory, with an optional value // Entries whose type is 2c are mandatory-inside-a-Sequence, // with an optional value // Entries whose type is 3 are optional // 'Study Instance UID' // Keep the value if exists // The user is allowed to create his own Study, // keeping the same 'Study Instance UID' for various images // The user may add images to a 'Manufacturer Study', // adding new series to an already existing Study CheckMandatoryEntry(0x0020,0x000d,Util::CreateUniqueUID()); // 'Serie Instance UID' // Keep the value if exists // The user is allowed to create his own Series, // keeping the same 'Serie Instance UID' for various images // The user shouldn't add any image to a 'Manufacturer Serie' // but there is no way no to allowed him to do that CheckMandatoryEntry(0x0020,0x000e,Util::CreateUniqueUID()); // Modality : if missing we set it to 'OTher' CheckMandatoryEntry(0x0008,0x0060,"OT"); // Manufacturer : if missing we set it to 'GDCM Factory' CheckMandatoryEntry(0x0008,0x0070,"GDCM Factory"); // Institution Name : if missing we set it to 'GDCM Hospital' CheckMandatoryEntry(0x0008,0x0080,"GDCM Hospital"); // Patient's Name : if missing, we set it to 'GDCM^Patient' CheckMandatoryEntry(0x0010,0x0010,"GDCM^Patient"); // Patient's Birth Date : 'type 2' entry -> must exist, value not mandatory CheckMandatoryEntry(0x0010,0x0030,""); // Patient's Sex :'type 2' entry -> must exist, value not mandatory CheckMandatoryEntry(0x0010,0x0040,""); // Referring Physician's Name :'type 2' entry -> must exist, value not mandatory CheckMandatoryEntry(0x0008,0x0090,""); // Pixel Spacing : defaulted to 1.0\1.0 CheckMandatoryEntry(0x0028,0x0030,"1.0\\1.0"); // Remove some inconstencies (probably some more will be added) // if (0028 0008)Number of Frames exists // Push out (0020 0052),Frame of Reference UID // (only meaningfull within a Serie) DataEntry *e_0028_0008 = FileInternal->GetDataEntry(0x0028, 0x0008); if ( !e_0028_0008 ) { Archive->Push(0x0020, 0X0052); } } void FileHelper::CheckMandatoryEntry(uint16_t group,uint16_t elem,std::string value) { DataEntry *entry = FileInternal->GetDataEntry(group,elem); if ( !entry ) { entry = new DataEntry(Global::GetDicts()->GetDefaultPubDict()->GetEntry(group,elem)); entry->SetString(value); Archive->Push(entry); } } void FileHelper::SetMandatoryEntry(uint16_t group,uint16_t elem,std::string value) { DataEntry *entry = new DataEntry(Global::GetDicts()->GetDefaultPubDict()->GetEntry(group,elem)); entry->SetString(value); Archive->Push(entry); } void FileHelper::CopyMandatoryEntry(uint16_t group,uint16_t elem,std::string value) { DataEntry *entry = CopyDataEntry(group,elem); entry->SetString(value); Archive->Push(entry); } /** * \brief Restore in the File the initial group 0002 */ void FileHelper::RestoreWriteMandatory() { // group 0002 may be pushed out for ACR-NEMA writting purposes Archive->Restore(0x0002,0x0000); Archive->Restore(0x0002,0x0001); Archive->Restore(0x0002,0x0002); Archive->Restore(0x0002,0x0003); Archive->Restore(0x0002,0x0010); Archive->Restore(0x0002,0x0012); Archive->Restore(0x0002,0x0013); Archive->Restore(0x0002,0x0016); Archive->Restore(0x0002,0x0100); Archive->Restore(0x0002,0x0102); Archive->Restore(0x0008,0x0012); Archive->Restore(0x0008,0x0013); Archive->Restore(0x0008,0x0016); Archive->Restore(0x0008,0x0018); Archive->Restore(0x0008,0x0060); Archive->Restore(0x0008,0x0070); Archive->Restore(0x0008,0x0080); Archive->Restore(0x0008,0x0090); Archive->Restore(0x0008,0x2112); Archive->Restore(0x0010,0x0010); Archive->Restore(0x0010,0x0030); Archive->Restore(0x0010,0x0040); Archive->Restore(0x0020,0x000d); Archive->Restore(0x0020,0x000e); } //----------------------------------------------------------------------------- // Private /** * \brief Factorization for various forms of constructors. */ void FileHelper::Initialize() { UserFunction = 0; WriteMode = WMODE_RAW; WriteType = ExplicitVR; PixelReadConverter = new PixelReadConvert; PixelWriteConverter = new PixelWriteConvert; Archive = new DocEntryArchive( FileInternal ); } /** * \brief Reads/[decompresses] the pixels, * *without* making RGB from Palette Colors * @return the pixels area, whatever its type * (uint8_t is just for prototyping : feel free to Cast it) */ uint8_t *FileHelper::GetRaw() { PixelReadConverter->SetUserFunction( UserFunction ); uint8_t *raw = PixelReadConverter->GetRaw(); if ( ! raw ) { // The Raw image migth not be loaded yet: std::ifstream *fp = FileInternal->OpenFile(); PixelReadConverter->ReadAndDecompressPixelData( fp ); if ( fp ) FileInternal->CloseFile(); raw = PixelReadConverter->GetRaw(); if ( ! raw ) { gdcmWarningMacro( "Read/decompress of pixel data apparently went wrong."); return 0; } } return raw; } //----------------------------------------------------------------------------- /** * \brief Prints the common part of DataEntry, SeqEntry * @param os ostream we want to print in * @param indent (unused) */ void FileHelper::Print(std::ostream &os, std::string const &) { FileInternal->SetPrintLevel(PrintLevel); FileInternal->Print(os); if ( FileInternal->IsReadable() ) { PixelReadConverter->SetPrintLevel(PrintLevel); PixelReadConverter->Print(os); } } //----------------------------------------------------------------------------- } // end namespace gdcm