/*=========================================================================
-
+
Program: gdcm
Module: $RCSfile: gdcmPixelReadConvert.cxx,v $
Language: C++
- Date: $Date: 2004/12/09 10:11:38 $
- Version: $Revision: 1.4 $
+ Date: $Date: 2005/01/17 03:05:55 $
+ Version: $Revision: 1.30 $
Copyright (c) CREATIS (Centre de Recherche et d'Applications en Traitement de
l'Image). All rights reserved. See Doc/License.txt or
#include "gdcmDebug.h"
#include "gdcmHeader.h"
+#include "gdcmGlobal.h"
+#include "gdcmTS.h"
#include "gdcmPixelReadConvert.h"
#include "gdcmDocEntry.h"
#include "gdcmRLEFramesInfo.h"
{
#define str2num(str, typeNum) *((typeNum *)(str))
-// For JPEG 2000, body in file gdcmJpeg2000.cxx
-bool gdcm_read_JPEG2000_file (std::ifstream* fp, void* image_buffer);
-
-// For JPEG 8 Bits, body in file gdcmJpeg8.cxx
-bool gdcm_read_JPEG_file8 (std::ifstream* fp, void* image_buffer);
-
-// For JPEG 12 Bits, body in file gdcmJpeg12.cxx
-bool gdcm_read_JPEG_file12 (std::ifstream* fp, void* image_buffer);
-
-// For JPEG 16 Bits, body in file gdcmJpeg16.cxx
-// Beware this is misleading there is no 16bits DCT algorithm, only
-// jpeg lossless compression exist in 16bits.
-bool gdcm_read_JPEG_file16 (std::ifstream* fp, void* image_buffer);
-
//-----------------------------------------------------------------------------
// Constructor / Destructor
{
RGB = 0;
RGBSize = 0;
- Decompressed = 0;
- DecompressedSize = 0;
+ Raw = 0;
+ RawSize = 0;
LutRGBA = 0;
LutRedData = 0;
LutGreenData = 0;
}
RGB = 0;
- if ( Decompressed )
+ if ( Raw )
{
- delete [] Decompressed;
+ delete [] Raw;
}
- Decompressed = 0;
+ Raw = 0;
if ( LutRGBA )
{
RGB = new uint8_t[ RGBSize ];
}
-void PixelReadConvert::AllocateDecompressed()
+void PixelReadConvert::AllocateRaw()
{
- if ( Decompressed ) {
- delete [] Decompressed;
+ if ( Raw ) {
+ delete [] Raw;
}
- Decompressed = new uint8_t[ DecompressedSize ];
+ Raw = new uint8_t[ RawSize ];
}
/**
* \brief Read from file a 12 bits per pixel image and decompress it
* into a 16 bits per pixel image.
*/
-void PixelReadConvert::ReadAndDecompress12BitsTo16Bits( std::ifstream* fp )
+void PixelReadConvert::ReadAndDecompress12BitsTo16Bits( std::ifstream *fp )
throw ( FormatError )
{
int nbPixels = XSize * YSize;
- uint16_t* localDecompres = (uint16_t*)Decompressed;
+ uint16_t* localDecompres = (uint16_t*)Raw;
for( int p = 0; p < nbPixels; p += 2 )
{
/**
* \brief Try to deal with RLE 16 Bits.
- * We assume the RLE has allready been parsed and loaded in
- * Decompressed (through \ref ReadAndDecompressJPEGFile ).
+ * We assume the RLE has already been parsed and loaded in
+ * Raw (through \ref ReadAndDecompressJPEGFile ).
* We here need to make 16 Bits Pixels from Low Byte and
* High Byte 'Planes'...(for what it may mean)
* @return Boolean
*/
bool PixelReadConvert::DecompressRLE16BitsFromRLE8Bits( int NumberOfFrames )
{
- size_t PixelNumber = XSize * YSize;
- size_t decompressedSize = XSize * YSize * NumberOfFrames;
+ size_t pixelNumber = XSize * YSize;
+ size_t rawSize = XSize * YSize * NumberOfFrames;
- // We assumed Decompressed contains the decoded RLE pixels but as
+ // We assumed Raw contains the decoded RLE pixels but as
// 8 bits per pixel. In order to convert those pixels to 16 bits
- // per pixel we cannot work in place within Decompressed and hence
- // we copy it in a safe place, say copyDecompressed.
+ // per pixel we cannot work in place within Raw and hence
+ // we copy it in a safe place, say copyRaw.
- uint8_t* copyDecompressed = new uint8_t[ decompressedSize * 2 ];
- memmove( copyDecompressed, Decompressed, decompressedSize * 2 );
+ uint8_t* copyRaw = new uint8_t[ rawSize * 2 ];
+ memmove( copyRaw, Raw, rawSize * 2 );
- uint8_t* x = Decompressed;
- uint8_t* a = copyDecompressed;
- uint8_t* b = a + PixelNumber;
+ uint8_t* x = Raw;
+ uint8_t* a = copyRaw;
+ uint8_t* b = a + pixelNumber;
for ( int i = 0; i < NumberOfFrames; i++ )
{
- for ( unsigned int j = 0; j < PixelNumber; j++ )
+ for ( unsigned int j = 0; j < pixelNumber; j++ )
{
*(x++) = *(b++);
*(x++) = *(a++);
}
}
- delete[] copyDecompressed;
+ delete[] copyRaw;
/// \todo check that operator new []didn't fail, and sometimes return false
return true;
/**
* \brief Implementation of the RLE decoding algorithm for decompressing
* a RLE fragment. [refer to PS 3.5-2003, section G.3.2 p 86]
- * @param subDecompressed Sub region of \ref Decompressed where the de
+ * @param subRaw Sub region of \ref Raw where the de
* decoded fragment should be placed.
* @param fragmentSize The length of the binary fragment as found on the disk.
- * @param decompressedSegmentSize The expected length of the fragment ONCE
- * decompressed.
+ * @param RawSegmentSize The expected length of the fragment ONCE
+ * Raw.
* @param fp File Pointer: on entry the position should be the one of
* the fragment to be decoded.
*/
-bool PixelReadConvert::ReadAndDecompressRLEFragment( uint8_t* subDecompressed,
+bool PixelReadConvert::ReadAndDecompressRLEFragment( uint8_t *subRaw,
long fragmentSize,
- long decompressedSegmentSize,
- std::ifstream* fp )
+ long RawSegmentSize,
+ std::ifstream *fp )
{
int8_t count;
long numberOfOutputBytes = 0;
long numberOfReadBytes = 0;
- while( numberOfOutputBytes < decompressedSegmentSize )
+ while( numberOfOutputBytes < RawSegmentSize )
{
fp->read( (char*)&count, 1 );
numberOfReadBytes += 1;
// signed integer of width N is 2^(N-1) - 1, which for int8_t
// is 127].
{
- fp->read( (char*)subDecompressed, count + 1);
+ fp->read( (char*)subRaw, count + 1);
numberOfReadBytes += count + 1;
- subDecompressed += count + 1;
+ subRaw += count + 1;
numberOfOutputBytes += count + 1;
}
else
numberOfReadBytes += 1;
for( int i = 0; i < -count + 1; i++ )
{
- subDecompressed[i] = newByte;
+ subRaw[i] = newByte;
}
- subDecompressed += -count + 1;
+ subRaw += -count + 1;
numberOfOutputBytes += -count + 1;
}
}
if ( numberOfReadBytes > fragmentSize )
{
- dbg.Verbose(0, "PixelReadConvert::ReadAndDecompressRLEFragment: we "
- "read more bytes than the segment size.");
+ gdcmVerboseMacro( "Read more bytes than the segment size.");
return false;
}
}
* at which the pixel data should be copied
* @return Boolean
*/
-bool PixelReadConvert::ReadAndDecompressRLEFile( std::ifstream* fp )
+bool PixelReadConvert::ReadAndDecompressRLEFile( std::ifstream *fp )
{
- uint8_t* subDecompressed = Decompressed;
- long decompressedSegmentSize = XSize * YSize;
+ uint8_t *subRaw = Raw;
+ long RawSegmentSize = XSize * YSize;
// Loop on the frame[s]
for( RLEFramesInfo::RLEFrameList::iterator
for( unsigned int k = 1; k <= (*it)->NumberFragments; k++ )
{
fp->seekg( (*it)->Offset[k] , std::ios::beg );
- (void)ReadAndDecompressRLEFragment( subDecompressed,
+ (void)ReadAndDecompressRLEFragment( subRaw,
(*it)->Length[k],
- decompressedSegmentSize,
+ RawSegmentSize,
fp );
- subDecompressed += decompressedSegmentSize;
+ subRaw += RawSegmentSize;
}
}
if( BitsAllocated == 16 )
{
- uint16_t* im16 = (uint16_t*)Decompressed;
+ uint16_t *im16 = (uint16_t*)Raw;
switch( SwapCode )
{
- case 0:
- case 12:
case 1234:
break;
- case 21:
case 3412:
case 2143:
case 4321:
- for( i = 0; i < DecompressedSize / 2; i++ )
+ for( i = 0; i < RawSize / 2; i++ )
{
im16[i]= (im16[i] >> 8) | (im16[i] << 8 );
}
break;
default:
- dbg.Verbose( 0, "PixelReadConvert::ConvertSwapZone: SwapCode value "
- "(16 bits) not allowed." );
+ gdcmVerboseMacro("SwapCode value (16 bits) not allowed.");
}
}
else if( BitsAllocated == 32 )
uint32_t s32;
uint16_t high;
uint16_t low;
- uint32_t* im32 = (uint32_t*)Decompressed;
+ uint32_t* im32 = (uint32_t*)Raw;
switch ( SwapCode )
{
- case 0:
case 1234:
break;
case 4321:
- for( i = 0; i < DecompressedSize / 4; i++ )
+ for( i = 0; i < RawSize / 4; i++ )
{
low = im32[i] & 0x0000ffff; // 4321
high = im32[i] >> 16;
}
break;
case 2143:
- for( i = 0; i < DecompressedSize / 4; i++ )
+ for( i = 0; i < RawSize / 4; i++ )
{
low = im32[i] & 0x0000ffff; // 2143
high = im32[i] >> 16;
}
break;
case 3412:
- for( i = 0; i < DecompressedSize / 4; i++ )
+ for( i = 0; i < RawSize / 4; i++ )
{
low = im32[i] & 0x0000ffff; // 3412
high = im32[i] >> 16;
}
break;
default:
- dbg.Verbose( 0, "PixelReadConvert::ConvertSwapZone: SwapCode value "
- "(32 bits) not allowed." );
+ gdcmVerboseMacro("SwapCode value (32 bits) not allowed." );
}
}
}
}
// Special kludge in order to deal with xmedcon broken images:
- if ( ( BitsAllocated == 16 )
- && ( BitsStored < BitsAllocated )
- && ( ! PixelSign ) )
+ if ( BitsAllocated == 16
+ && BitsStored < BitsAllocated
+ && !PixelSign )
{
- int l = (int)( DecompressedSize / ( BitsAllocated / 8 ) );
- uint16_t *deb = (uint16_t *)Decompressed;
+ int l = (int)( RawSize / ( BitsAllocated / 8 ) );
+ uint16_t *deb = (uint16_t *)Raw;
for(int i = 0; i<l; i++)
{
if( *deb == 0xffff )
}
}
+
/**
* \brief Reads from disk the Pixel Data of JPEG Dicom encapsulated
- & file and decompress it.
+ * file and decompress it. This function assumes that each
+ * jpeg fragment contains a whole frame (jpeg file).
* @param fp File Pointer
* @return Boolean
*/
-bool PixelReadConvert::ReadAndDecompressJPEGFile( std::ifstream* fp )
+bool PixelReadConvert::ReadAndDecompressJPEGFramesFromFile( std::ifstream *fp )
{
- uint8_t* localDecompressed = Decompressed;
+ // Pointer to the Raw image
+ uint8_t *localRaw = Raw;
+
+ // Precompute the offset localRaw will be shifted with
+ int length = XSize * YSize * SamplesPerPixel;
+ int numberBytes = BitsAllocated / 8;
+
// Loop on the fragment[s]
for( JPEGFragmentsInfo::JPEGFragmentsList::iterator
it = JPEGInfo->Fragments.begin();
it != JPEGInfo->Fragments.end();
++it )
{
- fp->seekg( (*it)->Offset, std::ios::beg);
+ (*it)->DecompressJPEGFramesFromFile(fp, localRaw, BitsStored );
- if ( IsJPEG2000 )
- {
- if ( ! gdcm_read_JPEG2000_file( fp,localDecompressed ) )
- {
- return false;
- }
- }
- else if ( BitsStored == 8)
- {
- // JPEG Lossy : call to IJG 6b
- if ( ! gdcm_read_JPEG_file8( fp, localDecompressed ) )
- {
- return false;
- }
- }
- else if ( BitsStored <= 12)
- {
- // Reading Fragment pixels
- if ( ! gdcm_read_JPEG_file12 ( fp, localDecompressed ) )
- {
- return false;
- }
- }
- else if ( BitsStored <= 16)
- {
- // Reading Fragment pixels
- if ( ! gdcm_read_JPEG_file16 ( fp, localDecompressed ) )
- {
- return false;
- }
- //assert( IsJPEGLossless );
- }
- else
- {
- // other JPEG lossy not supported
- dbg.Error("PixelReadConvert::ReadAndDecompressJPEGFile: unknown "
- "jpeg lossy compression ");
- return false;
- }
-
- // Advance to next free location in Decompressed
+ // Advance to next free location in Raw
// for next fragment decompression (if any)
- int length = XSize * YSize * SamplesPerPixel;
- int numberBytes = BitsAllocated / 8;
- localDecompressed += length * numberBytes;
+ localRaw += length * numberBytes;
}
return true;
}
+/**
+ * \brief Reads from disk the Pixel Data of JPEG Dicom encapsulated
+ * file and decompress it. This function assumes that the dicom
+ * image is a single frame split into several JPEG fragments.
+ * Those fragments will be glued together into a memory buffer
+ * before being read.
+ * @param fp File Pointer
+ * @return Boolean
+ */
+bool PixelReadConvert::
+ReadAndDecompressJPEGSingleFrameFragmentsFromFile( std::ifstream *fp )
+{
+ // Loop on the fragment[s] to get total length
+ size_t totalLength = JPEGInfo->GetFragmentsLength();
+
+ // Concatenate the jpeg fragments into a local buffer
+ JOCTET *buffer = new JOCTET [totalLength];
+ // Fill in the buffer:
+ JPEGInfo->ReadAllFragments(fp, buffer);
+
+ // kludge: // FIXME
+ JPEGFragmentsInfo::JPEGFragmentsList::const_iterator it = JPEGInfo->Fragments.begin();
+ (*it)->DecompressJPEGSingleFrameFragmentsFromFile(buffer, totalLength, Raw, BitsStored);
+
+ // free local buffer
+ delete [] buffer;
+
+ return true;
+}
+
+/**
+ * \brief Reads from disk the Pixel Data of JPEG Dicom encapsulated
+ * file and decompress it. This function handles the generic
+ * and complex case where the DICOM contains several frames,
+ * and some of the frames are possibly split into several JPEG
+ * fragments.
+ * @param fp File Pointer
+ * @return Boolean
+ */
+bool PixelReadConvert::
+ReadAndDecompressJPEGFragmentedFramesFromFile( std::ifstream *fp )
+{
+ // Loop on the fragment[s] to get total length
+ size_t totalLength = JPEGInfo->GetFragmentsLength();
+
+ // Concatenate the jpeg fragments into a local buffer
+ JOCTET *buffer = new JOCTET [totalLength];
+ // Fill in the buffer:
+ JPEGInfo->ReadAllFragments(fp, buffer);
+
+ size_t howManyRead = 0;
+ size_t howManyWritten = 0;
+ size_t fragmentLength = 0;
+
+ JPEGFragmentsInfo::JPEGFragmentsList::const_iterator it;
+ for( it = JPEGInfo->Fragments.begin() ;
+ (it != JPEGInfo->Fragments.end()) && (howManyRead < totalLength);
+ ++it )
+ {
+ fragmentLength += (*it)->Length;
+
+ if (howManyRead > fragmentLength) continue;
+
+ (*it)->DecompressJPEGFragmentedFramesFromFile(buffer, Raw, BitsStored, howManyRead, howManyWritten, totalLength);
+
+ if (howManyRead < fragmentLength)
+ howManyRead = fragmentLength;
+ }
+
+ // free local buffer
+ delete [] buffer;
+
+ return true;
+}
+
+/**
+ * \brief Reads from disk the Pixel Data of JPEG Dicom encapsulated
+ * file and decompress it.
+ * @param fp File Pointer
+ * @return Boolean
+ */
+bool PixelReadConvert::ReadAndDecompressJPEGFile( std::ifstream *fp )
+{
+ if ( IsJPEG2000 )
+ {
+ fp->seekg( (*JPEGInfo->Fragments.begin())->Offset, std::ios::beg);
+// if ( ! gdcm_read_JPEG2000_file( fp,Raw ) )
+ return false;
+ }
+
+ if ( ( ZSize == 1 ) && ( JPEGInfo->Fragments.size() > 1 ) )
+ {
+ // we have one frame split into several fragments
+ // we will pack those fragments into a single buffer and
+ // read from it
+ return ReadAndDecompressJPEGSingleFrameFragmentsFromFile( fp );
+ }
+ else if (JPEGInfo->Fragments.size() == (size_t)ZSize)
+ {
+ // suppose each fragment is a frame
+ return ReadAndDecompressJPEGFramesFromFile( fp );
+ }
+ else
+ {
+ // The dicom image contains frames containing fragments of images
+ // a more complex algorithm :-)
+ return ReadAndDecompressJPEGFragmentedFramesFromFile( fp );
+ }
+}
+
/**
* \brief Re-arrange the bits within the bytes.
* @return Boolean
{
if ( BitsStored != BitsAllocated )
{
- int l = (int)( DecompressedSize / ( BitsAllocated / 8 ) );
+ int l = (int)( RawSize / ( BitsAllocated / 8 ) );
if ( BitsAllocated == 16 )
{
uint16_t mask = 0xffff;
mask = mask >> ( BitsAllocated - BitsStored );
- uint16_t* deb = (uint16_t*)Decompressed;
+ uint16_t* deb = (uint16_t*)Raw;
for(int i = 0; i<l; i++)
{
*deb = (*deb >> (BitsStored - HighBitPosition - 1)) & mask;
{
uint32_t mask = 0xffffffff;
mask = mask >> ( BitsAllocated - BitsStored );
- uint32_t* deb = (uint32_t*)Decompressed;
+ uint32_t* deb = (uint32_t*)Raw;
for(int i = 0; i<l; i++)
{
*deb = (*deb >> (BitsStored - HighBitPosition - 1)) & mask;
}
else
{
- dbg.Verbose(0, "PixelReadConvert::ConvertReArrangeBits: weird image");
- throw FormatError( "PixelReadConvert::ConvertReArrangeBits()",
- "weird image !?" );
+ gdcmVerboseMacro("Weird image");
+ throw FormatError( "Weird image !?" );
}
}
return true;
*/
void PixelReadConvert::ConvertYcBcRPlanesToRGBPixels()
{
- uint8_t* localDecompressed = Decompressed;
- uint8_t* copyDecompressed = new uint8_t[ DecompressedSize ];
- memmove( copyDecompressed, localDecompressed, DecompressedSize );
+ uint8_t *localRaw = Raw;
+ uint8_t *copyRaw = new uint8_t[ RawSize ];
+ memmove( copyRaw, localRaw, RawSize );
// to see the tricks about YBR_FULL, YBR_FULL_422,
// YBR_PARTIAL_422, YBR_ICT, YBR_RCT have a look at :
int l = XSize * YSize;
int nbFrames = ZSize;
- uint8_t* a = copyDecompressed;
- uint8_t* b = copyDecompressed + l;
- uint8_t* c = copyDecompressed + l + l;
+ uint8_t *a = copyRaw;
+ uint8_t *b = copyRaw + l;
+ uint8_t *c = copyRaw + l + l;
double R, G, B;
/// \todo : Replace by the 'well known' integer computation
if (G > 255.0) G = 255.0;
if (B > 255.0) B = 255.0;
- *(localDecompressed++) = (uint8_t)R;
- *(localDecompressed++) = (uint8_t)G;
- *(localDecompressed++) = (uint8_t)B;
+ *(localRaw++) = (uint8_t)R;
+ *(localRaw++) = (uint8_t)G;
+ *(localRaw++) = (uint8_t)B;
a++;
b++;
c++;
}
}
- delete[] copyDecompressed;
+ delete[] copyRaw;
}
/**
*/
void PixelReadConvert::ConvertRGBPlanesToRGBPixels()
{
- uint8_t* localDecompressed = Decompressed;
- uint8_t* copyDecompressed = new uint8_t[ DecompressedSize ];
- memmove( copyDecompressed, localDecompressed, DecompressedSize );
+ uint8_t *localRaw = Raw;
+ uint8_t *copyRaw = new uint8_t[ RawSize ];
+ memmove( copyRaw, localRaw, RawSize );
int l = XSize * YSize * ZSize;
- uint8_t* a = copyDecompressed;
- uint8_t* b = copyDecompressed + l;
- uint8_t* c = copyDecompressed + l + l;
+ uint8_t* a = copyRaw;
+ uint8_t* b = copyRaw + l;
+ uint8_t* c = copyRaw + l + l;
for (int j = 0; j < l; j++)
{
- *(localDecompressed++) = *(a++);
- *(localDecompressed++) = *(b++);
- *(localDecompressed++) = *(c++);
+ *(localRaw++) = *(a++);
+ *(localRaw++) = *(b++);
+ *(localRaw++) = *(c++);
}
- delete[] copyDecompressed;
+ delete[] copyRaw;
}
-bool PixelReadConvert::ReadAndDecompressPixelData( std::ifstream* fp )
+bool PixelReadConvert::ReadAndDecompressPixelData( std::ifstream *fp )
{
- // ComputeDecompressedAndRGBSizes is already made by
+ // ComputeRawAndRGBSizes is already made by
// ::GrabInformationsFromHeader. So, the structure sizes are
// correct
Squeeze();
//// First stage: get our hands on the Pixel Data.
if ( !fp )
{
- dbg.Verbose( 0, "PixelReadConvert::ReadAndDecompressPixelData: "
- "unavailable file pointer." );
+ gdcmVerboseMacro( "Unavailable file pointer." );
return false;
}
fp->seekg( PixelOffset, std::ios::beg );
- if( fp->fail() || fp->eof()) //Fp->gcount() == 1
+ if( fp->fail() || fp->eof())
{
- dbg.Verbose( 0, "PixelReadConvert::ReadAndDecompressPixelData: "
- "unable to find PixelOffset in file." );
+ gdcmVerboseMacro( "Unable to find PixelOffset in file." );
return false;
}
- AllocateDecompressed();
+ AllocateRaw();
//////////////////////////////////////////////////
//// Second stage: read from disk dans decompress.
{
ReadAndDecompress12BitsTo16Bits( fp);
}
- else if ( IsDecompressed )
+ else if ( IsRaw )
{
// This problem can be found when some obvious informations are found
// after the field containing the image datas. In this case, these
// bad datas are added to the size of the image (in the PixelDataLength
- // variable). But DecompressedSize is the right size of the image !
- if( PixelDataLength != DecompressedSize)
+ // variable). But RawSize is the right size of the image !
+ if( PixelDataLength != RawSize)
{
- dbg.Verbose( 0, "PixelReadConvert::ReadAndDecompressPixelData: "
- "Mismatch between PixelReadConvert and DecompressedSize." );
+ gdcmVerboseMacro( "Mismatch between PixelReadConvert and RawSize." );
}
- if( PixelDataLength > DecompressedSize)
+ if( PixelDataLength > RawSize)
{
- fp->read( (char*)Decompressed, DecompressedSize);
+ fp->read( (char*)Raw, RawSize);
}
else
{
- fp->read( (char*)Decompressed, PixelDataLength);
+ fp->read( (char*)Raw, PixelDataLength);
}
- if ( fp->fail() || fp->eof())//Fp->gcount() == 1
+ if ( fp->fail() || fp->eof())
{
- dbg.Verbose( 0, "PixelReadConvert::ReadAndDecompressPixelData: "
- "reading of decompressed pixel data failed." );
+ gdcmVerboseMacro( "Reading of Raw pixel data failed." );
return false;
}
}
{
if ( ! ReadAndDecompressRLEFile( fp ) )
{
- dbg.Verbose( 0, "PixelReadConvert::ReadAndDecompressPixelData: "
- "RLE decompressor failed." );
+ gdcmVerboseMacro( "RLE decompressor failed." );
return false;
}
}
// Default case concerns JPEG family
if ( ! ReadAndDecompressJPEGFile( fp ) )
{
- dbg.Verbose( 0, "PixelReadConvert::ReadAndDecompressPixelData: "
- "JPEG decompressor failed." );
+ gdcmVerboseMacro( "JPEG decompressor failed." );
return false;
}
}
// formated Dicom) files (e.g. gdcmData/US-PAL-8-10x-echo.dcm) we encounter:
// - "Planar Configuration" = 0,
// - "Photometric Interpretation" = "PALETTE COLOR".
- // Hence gdcm shall use the folowing "heuristic" in order to be tolerant
+ // Hence gdcm will use the folowing "heuristic" in order to be tolerant
// towards Dicom-non-conformance files:
// << whatever the "Planar Configuration" value might be, a
// "Photometric Interpretation" set to "PALETTE COLOR" forces
// - [Planar 1] AND [Photo C] handled with ConvertYcBcRPlanesToRGBPixels()
// - [Planar 2] OR [Photo D] requires LUT intervention.
- if ( ! IsDecompressedRGB() )
+ if ( ! IsRawRGB() )
{
// [Planar 2] OR [Photo D]: LUT intervention done outside
return;
}
/**
- * \brief Predicate to know wether the image[s] (once decompressed) is RGB.
+ * \brief Predicate to know wether the image[s] (once Raw) is RGB.
* \note See comments of \ref ConvertHandleColor
*/
-bool PixelReadConvert::IsDecompressedRGB()
+bool PixelReadConvert::IsRawRGB()
{
if ( IsMonochrome
|| PlanarConfiguration == 2
return true;
}
-void PixelReadConvert::ComputeDecompressedAndRGBSizes()
+void PixelReadConvert::ComputeRawAndRGBSizes()
{
int bitsAllocated = BitsAllocated;
// Number of "Bits Allocated" is fixed to 16 when it's 12, since
bitsAllocated = 16;
}
- DecompressedSize = XSize * YSize * ZSize
+ RawSize = XSize * YSize * ZSize
* ( bitsAllocated / 8 )
* SamplesPerPixel;
if ( HasLUT )
{
- RGBSize = 3 * DecompressedSize;
+ RGBSize = 3 * RawSize;
}
else
{
- RGBSize = DecompressedSize;
+ RGBSize = RawSize;
}
}
-void PixelReadConvert::GrabInformationsFromHeader( Header* header )
+void PixelReadConvert::GrabInformationsFromHeader( Header *header )
{
// Number of Bits Allocated for storing a Pixel is defaulted to 16
// when absent from the header.
PixelSize = header->GetPixelSize();
PixelSign = header->IsSignedPixelData();
SwapCode = header->GetSwapCode();
- TransferSyntaxType ts = header->GetTransferSyntax();
- IsDecompressed =
+ std::string ts = header->GetTransferSyntax();
+ IsRaw =
( ! header->IsDicomV3() )
- || ts == ImplicitVRLittleEndian
- || ts == ImplicitVRLittleEndianDLXGE
- || ts == ExplicitVRLittleEndian
- || ts == ExplicitVRBigEndian
- || ts == DeflatedExplicitVRLittleEndian;
- IsJPEG2000 = header->IsJPEG2000();
- IsJPEGLossless = header->IsJPEGLossless();
- IsRLELossless = ( ts == RLELossless );
+ || Global::GetTS()->GetSpecialTransferSyntax(ts) == TS::ImplicitVRLittleEndian
+ || Global::GetTS()->GetSpecialTransferSyntax(ts) == TS::ImplicitVRLittleEndianDLXGE
+ || Global::GetTS()->GetSpecialTransferSyntax(ts) == TS::ExplicitVRLittleEndian
+ || Global::GetTS()->GetSpecialTransferSyntax(ts) == TS::ExplicitVRBigEndian
+ || Global::GetTS()->GetSpecialTransferSyntax(ts) == TS::DeflatedExplicitVRLittleEndian;
+ IsJPEG2000 = Global::GetTS()->IsJPEG2000(ts);
+ IsJPEGLossless = Global::GetTS()->IsJPEGLossless(ts);
+ IsRLELossless = Global::GetTS()->IsRLELossless(ts);
PixelOffset = header->GetPixelOffset();
PixelDataLength = header->GetPixelAreaLength();
RLEInfo = header->GetRLEInfo();
if ( HasLUT )
{
// Just in case some access to a Header element requires disk access.
- // Note: gdcmDocument::Fp is leaved open after OpenFile.
- LutRedDescriptor = header->GetEntryByNumber( 0x0028, 0x1101 );
- LutGreenDescriptor = header->GetEntryByNumber( 0x0028, 0x1102 );
- LutBlueDescriptor = header->GetEntryByNumber( 0x0028, 0x1103 );
+ LutRedDescriptor = header->GetEntry( 0x0028, 0x1101 );
+ LutGreenDescriptor = header->GetEntry( 0x0028, 0x1102 );
+ LutBlueDescriptor = header->GetEntry( 0x0028, 0x1103 );
// Depending on the value of Document::MAX_SIZE_LOAD_ELEMENT_VALUE
// [ refer to invocation of Document::SetMaxSizeLoadEntry() in
// [Bin|Val]Entry occurence migth have been hindered (read simply NOT
// loaded). Hence, we first try to obtain the LUTs data from the header
// and when this fails we read the LUTs data directely from disk.
- /// \todo Reading a [Bin|Val]Entry directly from disk is a kludge.
+ /// \TODO Reading a [Bin|Val]Entry directly from disk is a kludge.
/// We should NOT bypass the [Bin|Val]Entry class. Instead
/// an access to an UNLOADED content of a [Bin|Val]Entry occurence
/// (e.g. BinEntry::GetBinArea()) should force disk access from
////// Red round
header->LoadEntryBinArea(0x0028, 0x1201);
- LutRedData = (uint8_t*)header->GetEntryBinAreaByNumber( 0x0028, 0x1201 );
+ LutRedData = (uint8_t*)header->GetEntryBinArea( 0x0028, 0x1201 );
if ( ! LutRedData )
{
- dbg.Verbose(0, "PixelReadConvert::GrabInformationsFromHeader: "
- "unable to read red LUT data" );
+ gdcmVerboseMacro( "Unable to read Red LUT data" );
}
////// Green round:
header->LoadEntryBinArea(0x0028, 0x1202);
- LutGreenData = (uint8_t*)header->GetEntryBinAreaByNumber(0x0028, 0x1202 );
+ LutGreenData = (uint8_t*)header->GetEntryBinArea(0x0028, 0x1202 );
if ( ! LutGreenData)
{
- dbg.Verbose(0, "PixelReadConvert::GrabInformationsFromHeader: "
- "unable to read green LUT data" );
+ gdcmVerboseMacro( "Unable to read Green LUT data" );
}
////// Blue round:
header->LoadEntryBinArea(0x0028, 0x1203);
- LutBlueData = (uint8_t*)header->GetEntryBinAreaByNumber( 0x0028, 0x1203 );
+ LutBlueData = (uint8_t*)header->GetEntryBinArea( 0x0028, 0x1203 );
if ( ! LutBlueData )
{
- dbg.Verbose(0, "PixelReadConvert::GrabInformationsFromHeader: "
- "unable to read blue LUT data" );
+ gdcmVerboseMacro( "Unable to read Blue LUT data" );
}
}
- ComputeDecompressedAndRGBSizes();
+ ComputeRawAndRGBSizes();
}
/**
&lengthR, &debR, &nbitsR );
if( nbRead != 3 )
{
- dbg.Verbose(0, "PixelReadConvert::BuildLUTRGBA: wrong red LUT descriptor");
+ gdcmVerboseMacro( "Wrong Red LUT descriptor" );
}
int lengthG; // Green LUT length in Bytes
&lengthG, &debG, &nbitsG );
if( nbRead != 3 )
{
- dbg.Verbose(0, "PixelReadConvert::BuildLUTRGBA: wrong green LUT descriptor");
+ gdcmVerboseMacro( "Wrong Green LUT descriptor" );
}
int lengthB; // Blue LUT length in Bytes
&lengthB, &debB, &nbitsB );
if( nbRead != 3 )
{
- dbg.Verbose(0, "PixelReadConvert::BuildLUTRGBA: wrong blue LUT descriptor");
+ gdcmVerboseMacro( "Wrong Blue LUT descriptor" );
}
////////////////////////////////////////////////////////
// if it works, we shall have to check the 3 Palettes
// to see which byte is ==0 (first one, or second one)
// and fix the code
- // We give up the checking to avoid some (useless ?)overhead
+ // We give up the checking to avoid some (useless ?) overhead
// (optimistic asumption)
int i;
uint8_t* a = LutRGBA + 0;
}
/**
- * \brief Build the RGB image from the Decompressed imagage and the LUTs.
+ * \brief Build the RGB image from the Raw imagage and the LUTs.
*/
bool PixelReadConvert::BuildRGBImage()
{
return true;
}
- if ( ! Decompressed )
+ if ( ! Raw )
{
// The job can't be done
return false;
// Build RGB Pixels
AllocateRGB();
uint8_t* localRGB = RGB;
- for (size_t i = 0; i < DecompressedSize; ++i )
+ for (size_t i = 0; i < RawSize; ++i )
{
- int j = Decompressed[i] * 4;
+ int j = Raw[i] * 4;
*localRGB++ = LutRGBA[j];
*localRGB++ = LutRGBA[j+1];
*localRGB++ = LutRGBA[j+2];
* @param indent Indentation string to be prepended during printing.
* @param os Stream to print to.
*/
-void PixelReadConvert::Print( std::string indent, std::ostream &os )
+void PixelReadConvert::Print( std::ostream &os, std::string const & indent )
{
os << indent
<< "--- Pixel information -------------------------"
<< std::endl;
os << indent
<< "Pixel Data: offset " << PixelOffset
- << " x" << std::hex << PixelOffset << std::dec
- << " length " << PixelDataLength
- << " x" << std::hex << PixelDataLength << std::dec
- << std::endl;
+ << " x(" << std::hex << PixelOffset << std::dec
+ << ") length " << PixelDataLength
+ << " x(" << std::hex << PixelDataLength << std::dec
+ << ")" << std::endl;
if ( IsRLELossless )
{
if ( RLEInfo )
{
- RLEInfo->Print( indent, os );
+ RLEInfo->Print( os, indent );
}
else
{
- dbg.Verbose(0, "PixelReadConvert::Print: set as RLE file "
- "but NO RLEinfo present.");
+ gdcmVerboseMacro("Set as RLE file but NO RLEinfo present.");
}
}
{
if ( JPEGInfo )
{
- JPEGInfo->Print( indent, os );
+ JPEGInfo->Print( os, indent );
}
else
{
- dbg.Verbose(0, "PixelReadConvert::Print: set as JPEG file "
- "but NO JPEGinfo present.");
+ gdcmVerboseMacro("Set as JPEG file but NO JPEGinfo present.");
}
}
}
// User
// ---> GetImageDataRaw
// ---> GetImageDataIntoVectorRaw
+