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view OrthancFramework/Sources/DicomFormat/DicomImageInformation.cpp @ 5819:7c2b4fa94633 find-refactoring
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author | Alain Mazy <am@orthanc.team> |
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date | Fri, 27 Sep 2024 14:38:20 +0200 |
parents | f7adfb22e20e |
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/** * Orthanc - A Lightweight, RESTful DICOM Store * Copyright (C) 2012-2016 Sebastien Jodogne, Medical Physics * Department, University Hospital of Liege, Belgium * Copyright (C) 2017-2023 Osimis S.A., Belgium * Copyright (C) 2024-2024 Orthanc Team SRL, Belgium * Copyright (C) 2021-2024 Sebastien Jodogne, ICTEAM UCLouvain, Belgium * * This program is free software: you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public License * as published by the Free Software Foundation, either version 3 of * the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this program. If not, see * <http://www.gnu.org/licenses/>. **/ #include "../PrecompiledHeaders.h" #ifndef NOMINMAX #define NOMINMAX #endif #include "DicomImageInformation.h" #include "../Compatibility.h" #include "../Logging.h" #include "../OrthancException.h" #include "../Toolbox.h" #include <boost/lexical_cast.hpp> #include <limits> #include <cassert> #include <stdio.h> #include <memory> namespace Orthanc { DicomImageInformation::DicomImageInformation(const DicomMap& values) { std::string sopClassUid; if (values.LookupStringValue(sopClassUid, DICOM_TAG_SOP_CLASS_UID, false)) { sopClassUid = Toolbox::StripSpaces(sopClassUid); if (sopClassUid == "1.2.840.10008.5.1.4.1.1.481.3" /* RT-STRUCT */) { LOG(WARNING) << "Orthanc::DicomImageInformation() should not be applied to SOP Class UID: " << sopClassUid; } } uint32_t pixelRepresentation = 0; uint32_t planarConfiguration = 0; try { std::string p; if (values.LookupStringValue(p, DICOM_TAG_PHOTOMETRIC_INTERPRETATION, false)) { Toolbox::ToUpperCase(p); if (p == "RGB") { photometric_ = PhotometricInterpretation_RGB; } else if (p == "MONOCHROME1") { photometric_ = PhotometricInterpretation_Monochrome1; } else if (p == "MONOCHROME2") { photometric_ = PhotometricInterpretation_Monochrome2; } else if (p == "PALETTE COLOR") { photometric_ = PhotometricInterpretation_Palette; } else if (p == "HSV") { photometric_ = PhotometricInterpretation_HSV; } else if (p == "ARGB") { photometric_ = PhotometricInterpretation_ARGB; } else if (p == "CMYK") { photometric_ = PhotometricInterpretation_CMYK; } else if (p == "YBR_FULL") { photometric_ = PhotometricInterpretation_YBRFull; } else if (p == "YBR_FULL_422") { photometric_ = PhotometricInterpretation_YBRFull422; } else if (p == "YBR_PARTIAL_420") { photometric_ = PhotometricInterpretation_YBRPartial420; } else if (p == "YBR_PARTIAL_422") { photometric_ = PhotometricInterpretation_YBRPartial422; } else if (p == "YBR_ICT") { photometric_ = PhotometricInterpretation_YBR_ICT; } else if (p == "YBR_RCT") { photometric_ = PhotometricInterpretation_YBR_RCT; } else { photometric_ = PhotometricInterpretation_Unknown; } } else { photometric_ = PhotometricInterpretation_Unknown; } values.GetValue(DICOM_TAG_COLUMNS).ParseFirstUnsignedInteger(width_); // in some US images, we've seen tag values of "800\0"; that's why we parse the 'first' value values.GetValue(DICOM_TAG_ROWS).ParseFirstUnsignedInteger(height_); if (!values.ParseUnsignedInteger32(bitsAllocated_, DICOM_TAG_BITS_ALLOCATED)) { throw OrthancException(ErrorCode_BadFileFormat); } if (!values.ParseUnsignedInteger32(samplesPerPixel_, DICOM_TAG_SAMPLES_PER_PIXEL)) { samplesPerPixel_ = 1; // Assume 1 color channel } if (!values.ParseUnsignedInteger32(bitsStored_, DICOM_TAG_BITS_STORED)) { bitsStored_ = bitsAllocated_; } if (bitsStored_ > bitsAllocated_) { throw OrthancException(ErrorCode_BadFileFormat); } if (!values.ParseUnsignedInteger32(highBit_, DICOM_TAG_HIGH_BIT)) { highBit_ = bitsStored_ - 1; } if (!values.ParseUnsignedInteger32(pixelRepresentation, DICOM_TAG_PIXEL_REPRESENTATION)) { pixelRepresentation = 0; // Assume unsigned pixels } if (samplesPerPixel_ > 1) { // The "Planar Configuration" is only set when "Samples per Pixels" is greater than 1 // http://dicom.nema.org/medical/dicom/current/output/html/part03.html#sect_C.7.6.3.1.3 if (!values.ParseUnsignedInteger32(planarConfiguration, DICOM_TAG_PLANAR_CONFIGURATION)) { planarConfiguration = 0; // Assume interleaved color channels } } } catch (boost::bad_lexical_cast&) { throw OrthancException(ErrorCode_NotImplemented); } catch (OrthancException&) { throw OrthancException(ErrorCode_NotImplemented); } if (values.HasTag(DICOM_TAG_NUMBER_OF_FRAMES)) { if (!values.ParseUnsignedInteger32(numberOfFrames_, DICOM_TAG_NUMBER_OF_FRAMES)) { throw OrthancException(ErrorCode_NotImplemented); } } else { numberOfFrames_ = 1; } if (bitsAllocated_ != 8 && bitsAllocated_ != 16 && bitsAllocated_ != 24 && bitsAllocated_ != 32 && bitsAllocated_ != 1 /* new in Orthanc 1.10.0 */) { throw OrthancException(ErrorCode_IncompatibleImageFormat, "Image not supported: " + boost::lexical_cast<std::string>(bitsAllocated_) + " bits allocated"); } else if (numberOfFrames_ == 0) { throw OrthancException(ErrorCode_IncompatibleImageFormat, "Image not supported (no frames)"); } else if (planarConfiguration != 0 && planarConfiguration != 1) { throw OrthancException(ErrorCode_IncompatibleImageFormat, "Image not supported: planar configuration is " + boost::lexical_cast<std::string>(planarConfiguration)); } if (samplesPerPixel_ == 0) { throw OrthancException(ErrorCode_IncompatibleImageFormat, "Image not supported: samples per pixel is 0"); } if (bitsStored_ == 1) { // This is the case of DICOM SEG, new in Orthanc 1.10.0 if (bitsAllocated_ != 1) { throw OrthancException(ErrorCode_BadFileFormat); } else if (width_ % 8 != 0) { throw OrthancException(ErrorCode_BadFileFormat, "Bad number of columns for a black-and-white image"); } else { bytesPerValue_ = 0; // Arbitrary initialization } } else { bytesPerValue_ = bitsAllocated_ / 8; } isPlanar_ = (planarConfiguration != 0 ? true : false); isSigned_ = (pixelRepresentation != 0 ? true : false); } DicomImageInformation* DicomImageInformation::Clone() const { std::unique_ptr<DicomImageInformation> target(new DicomImageInformation); target->width_ = width_; target->height_ = height_; target->samplesPerPixel_ = samplesPerPixel_; target->numberOfFrames_ = numberOfFrames_; target->isPlanar_ = isPlanar_; target->isSigned_ = isSigned_; target->bytesPerValue_ = bytesPerValue_; target->bitsAllocated_ = bitsAllocated_; target->bitsStored_ = bitsStored_; target->highBit_ = highBit_; target->photometric_ = photometric_; return target.release(); } unsigned int DicomImageInformation::GetWidth() const { return width_; } unsigned int DicomImageInformation::GetHeight() const { return height_; } unsigned int DicomImageInformation::GetNumberOfFrames() const { return numberOfFrames_; } unsigned int DicomImageInformation::GetChannelCount() const { return samplesPerPixel_; } unsigned int DicomImageInformation::GetBitsStored() const { return bitsStored_; } size_t DicomImageInformation::GetBytesPerValue() const { if (bitsStored_ == 1) { throw OrthancException(ErrorCode_BadSequenceOfCalls, "This call is incompatible with black-and-white images"); } else { assert(bitsAllocated_ >= 8); return bytesPerValue_; } } bool DicomImageInformation::IsSigned() const { return isSigned_; } unsigned int DicomImageInformation::GetBitsAllocated() const { return bitsAllocated_; } unsigned int DicomImageInformation::GetHighBit() const { return highBit_; } bool DicomImageInformation::IsPlanar() const { return isPlanar_; } unsigned int DicomImageInformation::GetShift() const { return highBit_ + 1 - bitsStored_; } PhotometricInterpretation DicomImageInformation::GetPhotometricInterpretation() const { return photometric_; } bool DicomImageInformation::ExtractPixelFormat(PixelFormat& format, bool ignorePhotometricInterpretation) const { if (photometric_ == PhotometricInterpretation_Palette) { if (GetBitsStored() == 8 && GetChannelCount() == 1 && !IsSigned()) { format = PixelFormat_RGB24; return true; } if (GetBitsStored() == 16 && GetChannelCount() == 1 && !IsSigned()) { format = PixelFormat_RGB48; return true; } } if (ignorePhotometricInterpretation || photometric_ == PhotometricInterpretation_Monochrome1 || photometric_ == PhotometricInterpretation_Monochrome2) { if (GetBitsStored() == 8 && GetChannelCount() == 1 && !IsSigned()) { format = PixelFormat_Grayscale8; return true; } if (GetBitsAllocated() == 16 && GetChannelCount() == 1 && !IsSigned()) { format = PixelFormat_Grayscale16; return true; } if (GetBitsAllocated() == 16 && GetChannelCount() == 1 && IsSigned()) { format = PixelFormat_SignedGrayscale16; return true; } if (GetBitsAllocated() == 32 && GetChannelCount() == 1 && !IsSigned()) { format = PixelFormat_Grayscale32; return true; } if (GetBitsStored() == 1 && GetChannelCount() == 1 && !IsSigned()) { // This is the case of DICOM SEG, new in Orthanc 1.10.0 format = PixelFormat_Grayscale8; return true; } } if (GetBitsStored() == 8 && GetChannelCount() == 3 && !IsSigned() && (ignorePhotometricInterpretation || photometric_ == PhotometricInterpretation_RGB)) { format = PixelFormat_RGB24; return true; } if (GetBitsStored() == 16 && GetChannelCount() == 3 && !IsSigned() && (ignorePhotometricInterpretation || photometric_ == PhotometricInterpretation_RGB)) { format = PixelFormat_RGB48; return true; } return false; } size_t DicomImageInformation::GetFrameSize() const { if (bitsStored_ == 1) { assert(GetWidth() % 8 == 0); if (GetChannelCount() == 1) { return GetHeight() * GetWidth() / 8; } else { throw OrthancException(ErrorCode_IncompatibleImageFormat, "Image not supported (multi-channel black-and-image image)"); } } else { return (GetHeight() * GetWidth() * GetBytesPerValue() * GetChannelCount()); } } unsigned int DicomImageInformation::GetUsefulTagLength() { return 256; } ValueRepresentation DicomImageInformation::GuessPixelDataValueRepresentation(const DicomTransferSyntax& transferSyntax, unsigned int bitsAllocated) { /** * This approach is validated in "Tests/GuessPixelDataVR.py": * https://orthanc.uclouvain.be/hg/orthanc-tests/file/default/Tests/GuessPixelDataVR.py **/ if (transferSyntax == DicomTransferSyntax_LittleEndianExplicit || transferSyntax == DicomTransferSyntax_BigEndianExplicit) { /** * Same rules apply to Little Endian Explicit and Big Endian * Explicit (now retired). The VR of the pixel data directly * depends upon the "Bits Allocated (0028,0100)" tag: * https://dicom.nema.org/medical/dicom/current/output/chtml/part05/sect_A.2.html * https://dicom.nema.org/medical/dicom/2016b/output/chtml/part05/sect_A.3.html **/ if (bitsAllocated > 8) { return ValueRepresentation_OtherWord; } else { return ValueRepresentation_OtherByte; } } else if (transferSyntax == DicomTransferSyntax_LittleEndianImplicit) { // Assume "OW" for DICOM Implicit VR Little Endian Transfer Syntax // https://dicom.nema.org/medical/dicom/current/output/chtml/part05/chapter_A.html#sect_A.1 return ValueRepresentation_OtherWord; } else { // Assume "OB" for all the compressed transfer syntaxes // https://dicom.nema.org/medical/dicom/current/output/chtml/part05/sect_A.4.html return ValueRepresentation_OtherByte; } } }