Mercurial > hg > orthanc
view OrthancServer/FromDcmtkBridge.cpp @ 1873:5e7feeb63d1f
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author | Sebastien Jodogne <s.jodogne@gmail.com> |
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date | Mon, 07 Dec 2015 09:59:59 +0100 |
parents | a7bea843a7bc |
children | 9b458e4484a1 |
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/** * Orthanc - A Lightweight, RESTful DICOM Store * Copyright (C) 2012-2015 Sebastien Jodogne, Medical Physics * Department, University Hospital of Liege, Belgium * * This program is free software: you can redistribute it and/or * modify it under the terms of the GNU General Public License as * published by the Free Software Foundation, either version 3 of the * License, or (at your option) any later version. * * In addition, as a special exception, the copyright holders of this * program give permission to link the code of its release with the * OpenSSL project's "OpenSSL" library (or with modified versions of it * that use the same license as the "OpenSSL" library), and distribute * the linked executables. You must obey the GNU General Public License * in all respects for all of the code used other than "OpenSSL". If you * modify file(s) with this exception, you may extend this exception to * your version of the file(s), but you are not obligated to do so. If * you do not wish to do so, delete this exception statement from your * version. If you delete this exception statement from all source files * in the program, then also delete it here. * * 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 * General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see <http://www.gnu.org/licenses/>. **/ #include "PrecompiledHeadersServer.h" #ifndef NOMINMAX #define NOMINMAX #endif #include "Internals/DicomImageDecoder.h" #include "FromDcmtkBridge.h" #include "ToDcmtkBridge.h" #include "OrthancInitialization.h" #include "../Core/Logging.h" #include "../Core/Toolbox.h" #include "../Core/OrthancException.h" #include "../Core/Images/PngWriter.h" #include "../Core/Uuid.h" #include "../Core/DicomFormat/DicomIntegerPixelAccessor.h" #include <list> #include <limits> #include <boost/lexical_cast.hpp> #include <boost/filesystem.hpp> #include <dcmtk/dcmdata/dcchrstr.h> #include <dcmtk/dcmdata/dcdicent.h> #include <dcmtk/dcmdata/dcdict.h> #include <dcmtk/dcmdata/dcfilefo.h> #include <dcmtk/dcmdata/dcistrmb.h> #include <dcmtk/dcmdata/dcuid.h> #include <dcmtk/dcmdata/dcmetinf.h> #include <dcmtk/dcmdata/dcdeftag.h> #include <dcmtk/dcmdata/dcvrae.h> #include <dcmtk/dcmdata/dcvras.h> #include <dcmtk/dcmdata/dcvrcs.h> #include <dcmtk/dcmdata/dcvrda.h> #include <dcmtk/dcmdata/dcvrds.h> #include <dcmtk/dcmdata/dcvrdt.h> #include <dcmtk/dcmdata/dcvrfd.h> #include <dcmtk/dcmdata/dcvrfl.h> #include <dcmtk/dcmdata/dcvris.h> #include <dcmtk/dcmdata/dcvrlo.h> #include <dcmtk/dcmdata/dcvrlt.h> #include <dcmtk/dcmdata/dcvrpn.h> #include <dcmtk/dcmdata/dcvrsh.h> #include <dcmtk/dcmdata/dcvrsl.h> #include <dcmtk/dcmdata/dcvrss.h> #include <dcmtk/dcmdata/dcvrst.h> #include <dcmtk/dcmdata/dcvrtm.h> #include <dcmtk/dcmdata/dcvrui.h> #include <dcmtk/dcmdata/dcvrul.h> #include <dcmtk/dcmdata/dcvrus.h> #include <dcmtk/dcmdata/dcvrut.h> #include <dcmtk/dcmdata/dcpixel.h> #include <dcmtk/dcmdata/dcpixseq.h> #include <dcmtk/dcmdata/dcpxitem.h> #include <dcmtk/dcmdata/dcvrat.h> #include <dcmtk/dcmnet/dul.h> #include <boost/math/special_functions/round.hpp> #include <boost/algorithm/string/predicate.hpp> #include <dcmtk/dcmdata/dcostrmb.h> namespace Orthanc { static inline uint16_t GetCharValue(char c) { if (c >= '0' && c <= '9') return c - '0'; else if (c >= 'a' && c <= 'f') return c - 'a' + 10; else if (c >= 'A' && c <= 'F') return c - 'A' + 10; else return 0; } static inline uint16_t GetTagValue(const char* c) { return ((GetCharValue(c[0]) << 12) + (GetCharValue(c[1]) << 8) + (GetCharValue(c[2]) << 4) + GetCharValue(c[3])); } #if DCMTK_USE_EMBEDDED_DICTIONARIES == 1 static void LoadEmbeddedDictionary(DcmDataDictionary& dictionary, EmbeddedResources::FileResourceId resource) { Toolbox::TemporaryFile tmp; FILE* fp = fopen(tmp.GetPath().c_str(), "wb"); fwrite(EmbeddedResources::GetFileResourceBuffer(resource), EmbeddedResources::GetFileResourceSize(resource), 1, fp); fclose(fp); if (!dictionary.loadDictionary(tmp.GetPath().c_str())) { throw OrthancException(ErrorCode_InternalError); } } #else static void LoadExternalDictionary(DcmDataDictionary& dictionary, const std::string& directory, const std::string& filename) { boost::filesystem::path p = directory; p = p / filename; LOG(WARNING) << "Loading the external DICOM dictionary " << p; if (!dictionary.loadDictionary(p.string().c_str())) { throw OrthancException(ErrorCode_InternalError); } } #endif namespace { class DictionaryLocker { private: DcmDataDictionary& dictionary_; public: DictionaryLocker() : dictionary_(dcmDataDict.wrlock()) { } ~DictionaryLocker() { dcmDataDict.unlock(); } DcmDataDictionary& operator*() { return dictionary_; } DcmDataDictionary* operator->() { return &dictionary_; } }; } void FromDcmtkBridge::InitializeDictionary() { /* Disable "gethostbyaddr" (which results in memory leaks) and use raw IP addresses */ dcmDisableGethostbyaddr.set(OFTrue); { DictionaryLocker locker; locker->clear(); #if DCMTK_USE_EMBEDDED_DICTIONARIES == 1 LOG(WARNING) << "Loading the embedded dictionaries"; /** * Do not load DICONDE dictionary, it breaks the other tags. The * command "strace storescu 2>&1 |grep dic" shows that DICONDE * dictionary is not loaded by storescu. **/ //LoadEmbeddedDictionary(*locker, EmbeddedResources::DICTIONARY_DICONDE); LoadEmbeddedDictionary(*locker, EmbeddedResources::DICTIONARY_DICOM); LoadEmbeddedDictionary(*locker, EmbeddedResources::DICTIONARY_PRIVATE); #elif defined(__linux) || defined(__FreeBSD_kernel__) std::string path = DCMTK_DICTIONARY_DIR; const char* env = std::getenv(DCM_DICT_ENVIRONMENT_VARIABLE); if (env != NULL) { path = std::string(env); } LoadExternalDictionary(*locker, path, "dicom.dic"); LoadExternalDictionary(*locker, path, "private.dic"); #else #error Support your platform here #endif } /* make sure data dictionary is loaded */ if (!dcmDataDict.isDictionaryLoaded()) { LOG(ERROR) << "No DICOM dictionary loaded, check environment variable: " << DCM_DICT_ENVIRONMENT_VARIABLE; throw OrthancException(ErrorCode_InternalError); } { // Test the dictionary with a simple DICOM tag DcmTag key(0x0010, 0x1030); // This is PatientWeight if (key.getEVR() != EVR_DS) { LOG(ERROR) << "The DICOM dictionary has not been correctly read"; throw OrthancException(ErrorCode_InternalError); } } } void FromDcmtkBridge::RegisterDictionaryTag(const DicomTag& tag, const DcmEVR& vr, const std::string& name, unsigned int minMultiplicity, unsigned int maxMultiplicity) { if (minMultiplicity < 1) { throw OrthancException(ErrorCode_ParameterOutOfRange); } bool arbitrary = false; if (maxMultiplicity == 0) { maxMultiplicity = DcmVariableVM; arbitrary = true; } else if (maxMultiplicity < minMultiplicity) { throw OrthancException(ErrorCode_ParameterOutOfRange); } LOG(INFO) << "Registering tag in dictionary: " << tag << " " << (DcmVR(vr).getValidVRName()) << " " << name << " (multiplicity: " << minMultiplicity << "-" << (arbitrary ? "n" : boost::lexical_cast<std::string>(maxMultiplicity)) << ")"; std::auto_ptr<DcmDictEntry> entry(new DcmDictEntry(tag.GetGroup(), tag.GetElement(), vr, name.c_str(), static_cast<int>(minMultiplicity), static_cast<int>(maxMultiplicity), NULL /* version */, OFTrue /* doCopyString */, NULL /* private creator */)); entry->setGroupRangeRestriction(DcmDictRange_Unspecified); entry->setElementRangeRestriction(DcmDictRange_Unspecified); { DictionaryLocker locker; locker->addEntry(entry.release()); } } Encoding FromDcmtkBridge::DetectEncoding(DcmDataset& dataset) { // By default, Latin1 encoding is assumed std::string s = Configuration::GetGlobalStringParameter("DefaultEncoding", "Latin1"); Encoding encoding = s.empty() ? Encoding_Latin1 : StringToEncoding(s.c_str()); OFString tmp; if (dataset.findAndGetOFString(DCM_SpecificCharacterSet, tmp).good()) { std::string characterSet = Toolbox::StripSpaces(std::string(tmp.c_str())); if (characterSet.empty()) { // Empty specific character set tag: Use the default encoding } else if (GetDicomEncoding(encoding, characterSet.c_str())) { // The specific character set is supported by the Orthanc core } else { LOG(WARNING) << "Value of Specific Character Set (0008,0005) is not supported: " << characterSet << ", fallback to ASCII (remove all special characters)"; encoding = Encoding_Ascii; } } else { // No specific character set tag: Use the default encoding } return encoding; } void FromDcmtkBridge::Convert(DicomMap& target, DcmDataset& dataset) { Encoding encoding = DetectEncoding(dataset); target.Clear(); for (unsigned long i = 0; i < dataset.card(); i++) { DcmElement* element = dataset.getElement(i); if (element && element->isLeaf()) { target.SetValue(element->getTag().getGTag(), element->getTag().getETag(), ConvertLeafElement(*element, DicomToJsonFlags_Default, encoding)); } } } DicomTag FromDcmtkBridge::Convert(const DcmTag& tag) { return DicomTag(tag.getGTag(), tag.getETag()); } DicomTag FromDcmtkBridge::GetTag(const DcmElement& element) { return DicomTag(element.getGTag(), element.getETag()); } DicomValue* FromDcmtkBridge::ConvertLeafElement(DcmElement& element, DicomToJsonFlags flags, Encoding encoding) { if (!element.isLeaf()) { // This function is only applicable to leaf elements throw OrthancException(ErrorCode_BadParameterType); } char *c = NULL; if (element.isaString() && element.getString(c).good()) { if (c == NULL) // This case corresponds to the empty string { return new DicomValue("", false); } else { std::string s(c); std::string utf8 = Toolbox::ConvertToUtf8(s, encoding); if (utf8.size() > ORTHANC_MAXIMUM_TAG_LENGTH) { return new DicomValue; // Create a NULL value } else { return new DicomValue(utf8, false); } } } try { // http://support.dcmtk.org/docs/dcvr_8h-source.html switch (element.getVR()) { /** * Deal with binary data (including PixelData). **/ case EVR_OB: // other byte case EVR_OF: // other float case EVR_OW: // other word case EVR_UN: // unknown value representation case EVR_ox: // OB or OW depending on context case EVR_DS: // decimal string case EVR_IS: // integer string case EVR_AS: // age string case EVR_DA: // date string case EVR_DT: // date time string case EVR_TM: // time string case EVR_AE: // application entity title case EVR_CS: // code string case EVR_SH: // short string case EVR_LO: // long string case EVR_ST: // short text case EVR_LT: // long text case EVR_UT: // unlimited text case EVR_PN: // person name case EVR_UI: // unique identifier case EVR_UNKNOWN: // used internally for elements with unknown VR (encoded with 4-byte length field in explicit VR) case EVR_UNKNOWN2B: // used internally for elements with unknown VR with 2-byte length field in explicit VR { if (!(flags & DicomToJsonFlags_ConvertBinaryToNull)) { Uint8* data = NULL; if (element.getUint8Array(data) == EC_Normal) { return new DicomValue(reinterpret_cast<const char*>(data), element.getLength(), true); } } return new DicomValue; } /** * Numberic types **/ case EVR_SL: // signed long { Sint32 f; if (dynamic_cast<DcmSignedLong&>(element).getSint32(f).good()) return new DicomValue(boost::lexical_cast<std::string>(f), false); else return new DicomValue; } case EVR_SS: // signed short { Sint16 f; if (dynamic_cast<DcmSignedShort&>(element).getSint16(f).good()) return new DicomValue(boost::lexical_cast<std::string>(f), false); else return new DicomValue; } case EVR_UL: // unsigned long { Uint32 f; if (dynamic_cast<DcmUnsignedLong&>(element).getUint32(f).good()) return new DicomValue(boost::lexical_cast<std::string>(f), false); else return new DicomValue; } case EVR_US: // unsigned short { Uint16 f; if (dynamic_cast<DcmUnsignedShort&>(element).getUint16(f).good()) return new DicomValue(boost::lexical_cast<std::string>(f), false); else return new DicomValue; } case EVR_FL: // float single-precision { Float32 f; if (dynamic_cast<DcmFloatingPointSingle&>(element).getFloat32(f).good()) return new DicomValue(boost::lexical_cast<std::string>(f), false); else return new DicomValue; } case EVR_FD: // float double-precision { Float64 f; if (dynamic_cast<DcmFloatingPointDouble&>(element).getFloat64(f).good()) return new DicomValue(boost::lexical_cast<std::string>(f), false); else return new DicomValue; } /** * Attribute tag. **/ case EVR_AT: { DcmTagKey tag; if (dynamic_cast<DcmAttributeTag&>(element).getTagVal(tag, 0).good()) { DicomTag t(tag.getGroup(), tag.getElement()); return new DicomValue(t.Format(), false); } else { return new DicomValue; } } /** * Sequence types, should never occur at this point because of * "element.isLeaf()". **/ case EVR_SQ: // sequence of items return new DicomValue; /** * Internal to DCMTK. **/ case EVR_xs: // SS or US depending on context case EVR_lt: // US, SS or OW depending on context, used for LUT Data (thus the name) case EVR_na: // na="not applicable", for data which has no VR case EVR_up: // up="unsigned pointer", used internally for DICOMDIR suppor case EVR_item: // used internally for items case EVR_metainfo: // used internally for meta info datasets case EVR_dataset: // used internally for datasets case EVR_fileFormat: // used internally for DICOM files case EVR_dicomDir: // used internally for DICOMDIR objects case EVR_dirRecord: // used internally for DICOMDIR records case EVR_pixelSQ: // used internally for pixel sequences in a compressed image case EVR_pixelItem: // used internally for pixel items in a compressed image case EVR_PixelData: // used internally for uncompressed pixeld data case EVR_OverlayData: // used internally for overlay data return new DicomValue; /** * Default case. **/ default: return new DicomValue; } } catch (boost::bad_lexical_cast) { return new DicomValue; } catch (std::bad_cast) { return new DicomValue; } } static Json::Value& PrepareNode(Json::Value& parent, DcmElement& element, DicomToJsonFormat format) { assert(parent.type() == Json::objectValue); DicomTag tag(FromDcmtkBridge::GetTag(element)); const std::string formattedTag = tag.Format(); if (format == DicomToJsonFormat_Short) { parent[formattedTag] = Json::nullValue; return parent[formattedTag]; } // This code gives access to the name of the private tags DcmTag tagbis(element.getTag()); const std::string tagName(tagbis.getTagName()); switch (format) { case DicomToJsonFormat_Human: parent[tagName] = Json::nullValue; return parent[tagName]; case DicomToJsonFormat_Full: { parent[formattedTag] = Json::objectValue; Json::Value& node = parent[formattedTag]; if (element.isLeaf()) { node["Name"] = tagName; if (tagbis.getPrivateCreator() != NULL) { node["PrivateCreator"] = tagbis.getPrivateCreator(); } return node; } else { node["Name"] = tagName; node["Type"] = "Sequence"; node["Value"] = Json::nullValue; return node["Value"]; } } default: throw OrthancException(ErrorCode_ParameterOutOfRange); } } static void LeafValueToJson(Json::Value& target, const DicomValue& value, DicomToJsonFormat format, DicomToJsonFlags flags, unsigned int maxStringLength) { Json::Value* targetValue = NULL; Json::Value* targetType = NULL; switch (format) { case DicomToJsonFormat_Short: case DicomToJsonFormat_Human: { assert(target.type() == Json::nullValue); targetValue = ⌖ break; } case DicomToJsonFormat_Full: { assert(target.type() == Json::objectValue); target["Value"] = Json::nullValue; target["Type"] = Json::nullValue; targetType = &target["Type"]; targetValue = &target["Value"]; break; } default: throw OrthancException(ErrorCode_ParameterOutOfRange); } assert(targetValue != NULL); assert(targetValue->type() == Json::nullValue); assert(targetType == NULL || targetType->type() == Json::nullValue); if (value.IsNull()) { if (targetType != NULL) { *targetType = "Null"; } } else if (value.IsBinary()) { if (flags & DicomToJsonFlags_ConvertBinaryToAscii) { *targetValue = Toolbox::ConvertToAscii(value.GetContent()); } else { std::string s; value.FormatDataUriScheme(s); *targetValue = s; } if (targetType != NULL) { *targetType = "Binary"; } } else if (maxStringLength == 0 || value.GetContent().size() <= maxStringLength) { *targetValue = value.GetContent(); if (targetType != NULL) { *targetType = "String"; } } else { if (targetType != NULL) { *targetType = "TooLong"; } } } static void DatasetToJson(Json::Value& parent, DcmItem& item, DicomToJsonFormat format, DicomToJsonFlags flags, unsigned int maxStringLength, Encoding encoding); void FromDcmtkBridge::ToJson(Json::Value& parent, DcmElement& element, DicomToJsonFormat format, DicomToJsonFlags flags, unsigned int maxStringLength, Encoding encoding) { if (parent.type() == Json::nullValue) { parent = Json::objectValue; } assert(parent.type() == Json::objectValue); Json::Value& target = PrepareNode(parent, element, format); if (element.isLeaf()) { std::auto_ptr<DicomValue> v(FromDcmtkBridge::ConvertLeafElement(element, flags, encoding)); LeafValueToJson(target, *v, format, flags, maxStringLength); } else { assert(target.type() == Json::nullValue); target = Json::arrayValue; // "All subclasses of DcmElement except for DcmSequenceOfItems // are leaf nodes, while DcmSequenceOfItems, DcmItem, DcmDataset // etc. are not." The following dynamic_cast is thus OK. DcmSequenceOfItems& sequence = dynamic_cast<DcmSequenceOfItems&>(element); for (unsigned long i = 0; i < sequence.card(); i++) { DcmItem* child = sequence.getItem(i); Json::Value& v = target.append(Json::objectValue); DatasetToJson(v, *child, format, flags, maxStringLength, encoding); } } } static void DatasetToJson(Json::Value& parent, DcmItem& item, DicomToJsonFormat format, DicomToJsonFlags flags, unsigned int maxStringLength, Encoding encoding) { assert(parent.type() == Json::objectValue); for (unsigned long i = 0; i < item.card(); i++) { DcmElement* element = item.getElement(i); if (element == NULL) { throw OrthancException(ErrorCode_InternalError); } DicomTag tag(FromDcmtkBridge::Convert(element->getTag())); /*element->getTag().isPrivate()*/ if (tag.IsPrivate() && !(flags & DicomToJsonFlags_IncludePrivateTags)) { continue; } if (!(flags & DicomToJsonFlags_IncludeUnknownTags)) { DictionaryLocker locker; if (locker->findEntry(element->getTag(), NULL) == NULL) { continue; } } DcmEVR evr = element->getTag().getEVR(); if (evr == EVR_OB || evr == EVR_OF || evr == EVR_OW || evr == EVR_UN || evr == EVR_ox) { // This is a binary tag if ((tag == DICOM_TAG_PIXEL_DATA && !(flags & DicomToJsonFlags_IncludePixelData)) || (tag != DICOM_TAG_PIXEL_DATA && !(flags & DicomToJsonFlags_IncludeBinary))) { continue; } } FromDcmtkBridge::ToJson(parent, *element, format, flags, maxStringLength, encoding); } } void FromDcmtkBridge::ToJson(Json::Value& target, DcmDataset& dataset, DicomToJsonFormat format, DicomToJsonFlags flags, unsigned int maxStringLength) { target = Json::objectValue; DatasetToJson(target, dataset, format, flags, maxStringLength, DetectEncoding(dataset)); } void FromDcmtkBridge::ToJson(Json::Value& target, DcmMetaInfo& dataset, DicomToJsonFormat format, DicomToJsonFlags flags, unsigned int maxStringLength) { target = Json::objectValue; DatasetToJson(target, dataset, format, flags, maxStringLength, Encoding_Ascii); } std::string FromDcmtkBridge::GetName(const DicomTag& t) { // Some patches for important tags because of different DICOM // dictionaries between DCMTK versions std::string n = t.GetMainTagsName(); if (n.size() != 0) { return n; } // End of patches #if 0 DcmTagKey tag(t.GetGroup(), t.GetElement()); const DcmDataDictionary& dict = dcmDataDict.rdlock(); const DcmDictEntry* entry = dict.findEntry(tag, NULL); std::string s(DcmTag_ERROR_TagName); if (entry != NULL) { s = std::string(entry->getTagName()); } dcmDataDict.unlock(); return s; #else DcmTag tag(t.GetGroup(), t.GetElement()); const char* name = tag.getTagName(); if (name == NULL) { return DcmTag_ERROR_TagName; } else { return std::string(name); } #endif } DicomTag FromDcmtkBridge::ParseTag(const char* name) { if (strlen(name) == 9 && isxdigit(name[0]) && isxdigit(name[1]) && isxdigit(name[2]) && isxdigit(name[3]) && (name[4] == '-' || name[4] == ',') && isxdigit(name[5]) && isxdigit(name[6]) && isxdigit(name[7]) && isxdigit(name[8])) { uint16_t group = GetTagValue(name); uint16_t element = GetTagValue(name + 5); return DicomTag(group, element); } if (strlen(name) == 8 && isxdigit(name[0]) && isxdigit(name[1]) && isxdigit(name[2]) && isxdigit(name[3]) && isxdigit(name[4]) && isxdigit(name[5]) && isxdigit(name[6]) && isxdigit(name[7])) { uint16_t group = GetTagValue(name); uint16_t element = GetTagValue(name + 4); return DicomTag(group, element); } #if 0 const DcmDataDictionary& dict = dcmDataDict.rdlock(); const DcmDictEntry* entry = dict.findEntry(name); if (entry == NULL) { dcmDataDict.unlock(); throw OrthancException(ErrorCode_UnknownDicomTag); } else { DcmTagKey key = entry->getKey(); DicomTag tag(key.getGroup(), key.getElement()); dcmDataDict.unlock(); return tag; } #else DcmTag tag; if (DcmTag::findTagFromName(name, tag).good()) { return DicomTag(tag.getGTag(), tag.getETag()); } else { throw OrthancException(ErrorCode_UnknownDicomTag); } #endif } bool FromDcmtkBridge::IsUnknownTag(const DicomTag& tag) { DcmTag tmp(tag.GetGroup(), tag.GetElement()); return tmp.isUnknownVR(); } void FromDcmtkBridge::ToJson(Json::Value& result, const DicomMap& values, bool simplify) { if (result.type() != Json::objectValue) { throw OrthancException(ErrorCode_BadParameterType); } result.clear(); for (DicomMap::Map::const_iterator it = values.map_.begin(); it != values.map_.end(); ++it) { if (simplify) { if (it->second->IsNull()) { result[GetName(it->first)] = Json::nullValue; } else { // TODO IsBinary result[GetName(it->first)] = it->second->GetContent(); } } else { Json::Value value = Json::objectValue; value["Name"] = GetName(it->first); if (it->second->IsNull()) { value["Type"] = "Null"; value["Value"] = Json::nullValue; } else { // TODO IsBinary value["Type"] = "String"; value["Value"] = it->second->GetContent(); } result[it->first.Format()] = value; } } } std::string FromDcmtkBridge::GenerateUniqueIdentifier(ResourceType level) { char uid[100]; switch (level) { case ResourceType_Patient: // The "PatientID" field is of type LO (Long String), 64 // Bytes Maximum. An UUID is of length 36, thus it can be used // as a random PatientID. return Toolbox::GenerateUuid(); case ResourceType_Instance: return dcmGenerateUniqueIdentifier(uid, SITE_INSTANCE_UID_ROOT); case ResourceType_Series: return dcmGenerateUniqueIdentifier(uid, SITE_SERIES_UID_ROOT); case ResourceType_Study: return dcmGenerateUniqueIdentifier(uid, SITE_STUDY_UID_ROOT); default: throw OrthancException(ErrorCode_ParameterOutOfRange); } } bool FromDcmtkBridge::SaveToMemoryBuffer(std::string& buffer, DcmDataset& dataSet) { // Determine the transfer syntax which shall be used to write the // information to the file. We always switch to the Little Endian // syntax, with explicit length. // http://support.dcmtk.org/docs/dcxfer_8h-source.html /** * Note that up to Orthanc 0.7.1 (inclusive), the * "EXS_LittleEndianExplicit" was always used to save the DICOM * dataset into memory. We now keep the original transfer syntax * (if available). **/ E_TransferSyntax xfer = dataSet.getOriginalXfer(); if (xfer == EXS_Unknown) { // No information about the original transfer syntax: This is // most probably a DICOM dataset that was read from memory. xfer = EXS_LittleEndianExplicit; } E_EncodingType encodingType = /*opt_sequenceType*/ EET_ExplicitLength; // Create the meta-header information DcmFileFormat ff(&dataSet); ff.validateMetaInfo(xfer); ff.removeInvalidGroups(); // Create a memory buffer with the proper size uint32_t s = ff.calcElementLength(xfer, encodingType); buffer.resize(s); DcmOutputBufferStream ob(&buffer[0], s); // Fill the memory buffer with the meta-header and the dataset ff.transferInit(); OFCondition c = ff.write(ob, xfer, encodingType, NULL, /*opt_groupLength*/ EGL_recalcGL, /*opt_paddingType*/ EPD_withoutPadding); ff.transferEnd(); // Handle errors if (c.good()) { return true; } else { buffer.clear(); return false; } } ValueRepresentation FromDcmtkBridge::GetValueRepresentation(const DicomTag& tag) { DcmTag t(tag.GetGroup(), tag.GetElement()); switch (t.getEVR()) { case EVR_PN: return ValueRepresentation_PatientName; case EVR_DA: return ValueRepresentation_Date; case EVR_DT: return ValueRepresentation_DateTime; case EVR_TM: return ValueRepresentation_Time; case EVR_SQ: return ValueRepresentation_Sequence; default: return ValueRepresentation_Other; } } static bool IsBinaryTag(const DcmTag& key) { return (key.isUnknownVR() || key.getEVR() == EVR_OB || key.getEVR() == EVR_OF || key.getEVR() == EVR_OW || key.getEVR() == EVR_UN || key.getEVR() == EVR_ox); } DcmElement* FromDcmtkBridge::CreateElementForTag(const DicomTag& tag) { DcmTag key(tag.GetGroup(), tag.GetElement()); if (tag.IsPrivate() || IsBinaryTag(key)) { return new DcmOtherByteOtherWord(key); } switch (key.getEVR()) { // http://support.dcmtk.org/docs/dcvr_8h-source.html /** * Binary types, handled above **/ case EVR_OB: // other byte case EVR_OF: // other float case EVR_OW: // other word case EVR_UN: // unknown value representation case EVR_ox: // OB or OW depending on context throw OrthancException(ErrorCode_InternalError); /** * String types. * http://support.dcmtk.org/docs/classDcmByteString.html **/ case EVR_AS: // age string return new DcmAgeString(key); case EVR_AE: // application entity title return new DcmApplicationEntity(key); case EVR_CS: // code string return new DcmCodeString(key); case EVR_DA: // date string return new DcmDate(key); case EVR_DT: // date time string return new DcmDateTime(key); case EVR_DS: // decimal string return new DcmDecimalString(key); case EVR_IS: // integer string return new DcmIntegerString(key); case EVR_TM: // time string return new DcmTime(key); case EVR_UI: // unique identifier return new DcmUniqueIdentifier(key); case EVR_ST: // short text return new DcmShortText(key); case EVR_LO: // long string return new DcmLongString(key); case EVR_LT: // long text return new DcmLongText(key); case EVR_UT: // unlimited text return new DcmUnlimitedText(key); case EVR_SH: // short string return new DcmShortString(key); case EVR_PN: // person name return new DcmPersonName(key); /** * Numerical types **/ case EVR_SL: // signed long return new DcmSignedLong(key); case EVR_SS: // signed short return new DcmSignedShort(key); case EVR_UL: // unsigned long return new DcmUnsignedLong(key); case EVR_US: // unsigned short return new DcmUnsignedShort(key); case EVR_FL: // float single-precision return new DcmFloatingPointSingle(key); case EVR_FD: // float double-precision return new DcmFloatingPointDouble(key); /** * Sequence types, should never occur at this point. **/ case EVR_SQ: // sequence of items throw OrthancException(ErrorCode_ParameterOutOfRange); /** * TODO **/ case EVR_AT: // attribute tag throw OrthancException(ErrorCode_NotImplemented); /** * Internal to DCMTK. **/ case EVR_xs: // SS or US depending on context case EVR_lt: // US, SS or OW depending on context, used for LUT Data (thus the name) case EVR_na: // na="not applicable", for data which has no VR case EVR_up: // up="unsigned pointer", used internally for DICOMDIR suppor case EVR_item: // used internally for items case EVR_metainfo: // used internally for meta info datasets case EVR_dataset: // used internally for datasets case EVR_fileFormat: // used internally for DICOM files case EVR_dicomDir: // used internally for DICOMDIR objects case EVR_dirRecord: // used internally for DICOMDIR records case EVR_pixelSQ: // used internally for pixel sequences in a compressed image case EVR_pixelItem: // used internally for pixel items in a compressed image case EVR_UNKNOWN: // used internally for elements with unknown VR (encoded with 4-byte length field in explicit VR) case EVR_PixelData: // used internally for uncompressed pixeld data case EVR_OverlayData: // used internally for overlay data case EVR_UNKNOWN2B: // used internally for elements with unknown VR with 2-byte length field in explicit VR default: break; } throw OrthancException(ErrorCode_InternalError); } void FromDcmtkBridge::FillElementWithString(DcmElement& element, const DicomTag& tag, const std::string& utf8Value, bool decodeDataUriScheme, Encoding dicomEncoding) { std::string binary; const std::string* decoded = &utf8Value; if (decodeDataUriScheme && boost::starts_with(utf8Value, "data:application/octet-stream;base64,")) { std::string mime; Toolbox::DecodeDataUriScheme(mime, binary, utf8Value); decoded = &binary; } else if (dicomEncoding != Encoding_Utf8) { binary = Toolbox::ConvertFromUtf8(utf8Value, dicomEncoding); decoded = &binary; } DcmTag key(tag.GetGroup(), tag.GetElement()); if (tag.IsPrivate() || IsBinaryTag(key)) { if (element.putUint8Array((const Uint8*) decoded->c_str(), decoded->size()).good()) { return; } else { throw OrthancException(ErrorCode_InternalError); } } bool ok = false; try { switch (key.getEVR()) { // http://support.dcmtk.org/docs/dcvr_8h-source.html /** * TODO. **/ case EVR_OB: // other byte case EVR_OF: // other float case EVR_OW: // other word case EVR_AT: // attribute tag throw OrthancException(ErrorCode_NotImplemented); case EVR_UN: // unknown value representation throw OrthancException(ErrorCode_ParameterOutOfRange); /** * String types. **/ case EVR_DS: // decimal string case EVR_IS: // integer string case EVR_AS: // age string case EVR_DA: // date string case EVR_DT: // date time string case EVR_TM: // time string case EVR_AE: // application entity title case EVR_CS: // code string case EVR_SH: // short string case EVR_LO: // long string case EVR_ST: // short text case EVR_LT: // long text case EVR_UT: // unlimited text case EVR_PN: // person name case EVR_UI: // unique identifier { ok = element.putString(decoded->c_str()).good(); break; } /** * Numerical types **/ case EVR_SL: // signed long { ok = element.putSint32(boost::lexical_cast<Sint32>(*decoded)).good(); break; } case EVR_SS: // signed short { ok = element.putSint16(boost::lexical_cast<Sint16>(*decoded)).good(); break; } case EVR_UL: // unsigned long { ok = element.putUint32(boost::lexical_cast<Uint32>(*decoded)).good(); break; } case EVR_US: // unsigned short { ok = element.putUint16(boost::lexical_cast<Uint16>(*decoded)).good(); break; } case EVR_FL: // float single-precision { ok = element.putFloat32(boost::lexical_cast<float>(*decoded)).good(); break; } case EVR_FD: // float double-precision { ok = element.putFloat64(boost::lexical_cast<double>(*decoded)).good(); break; } /** * Sequence types, should never occur at this point. **/ case EVR_SQ: // sequence of items { ok = false; break; } /** * Internal to DCMTK. **/ case EVR_ox: // OB or OW depending on context case EVR_xs: // SS or US depending on context case EVR_lt: // US, SS or OW depending on context, used for LUT Data (thus the name) case EVR_na: // na="not applicable", for data which has no VR case EVR_up: // up="unsigned pointer", used internally for DICOMDIR suppor case EVR_item: // used internally for items case EVR_metainfo: // used internally for meta info datasets case EVR_dataset: // used internally for datasets case EVR_fileFormat: // used internally for DICOM files case EVR_dicomDir: // used internally for DICOMDIR objects case EVR_dirRecord: // used internally for DICOMDIR records case EVR_pixelSQ: // used internally for pixel sequences in a compressed image case EVR_pixelItem: // used internally for pixel items in a compressed image case EVR_UNKNOWN: // used internally for elements with unknown VR (encoded with 4-byte length field in explicit VR) case EVR_PixelData: // used internally for uncompressed pixeld data case EVR_OverlayData: // used internally for overlay data case EVR_UNKNOWN2B: // used internally for elements with unknown VR with 2-byte length field in explicit VR default: break; } } catch (boost::bad_lexical_cast&) { ok = false; } if (!ok) { throw OrthancException(ErrorCode_InternalError); } } DcmElement* FromDcmtkBridge::FromJson(const DicomTag& tag, const Json::Value& value, bool decodeDataUriScheme, Encoding dicomEncoding) { std::auto_ptr<DcmElement> element; switch (value.type()) { case Json::stringValue: element.reset(CreateElementForTag(tag)); FillElementWithString(*element, tag, value.asString(), decodeDataUriScheme, dicomEncoding); break; case Json::arrayValue: { DcmTag key(tag.GetGroup(), tag.GetElement()); if (key.getEVR() != EVR_SQ) { throw OrthancException(ErrorCode_BadParameterType); } DcmSequenceOfItems* sequence = new DcmSequenceOfItems(key, value.size()); element.reset(sequence); for (Json::Value::ArrayIndex i = 0; i < value.size(); i++) { std::auto_ptr<DcmItem> item(new DcmItem); Json::Value::Members members = value[i].getMemberNames(); for (Json::Value::ArrayIndex j = 0; j < members.size(); j++) { item->insert(FromJson(ParseTag(members[j]), value[i][members[j]], decodeDataUriScheme, dicomEncoding)); } sequence->append(item.release()); } break; } default: throw OrthancException(ErrorCode_BadParameterType); } return element.release(); } DcmEVR FromDcmtkBridge::ParseValueRepresentation(const std::string& s) { if (s == "AE") return EVR_AE; if (s == "AS") return EVR_AS; if (s == "AT") return EVR_AT; if (s == "CS") return EVR_CS; if (s == "DA") return EVR_DA; if (s == "DS") return EVR_DS; if (s == "DT") return EVR_DT; if (s == "FD") return EVR_FD; if (s == "FL") return EVR_FL; if (s == "IS") return EVR_IS; if (s == "LO") return EVR_LO; if (s == "LT") return EVR_LT; if (s == "OB") return EVR_OB; if (s == "OF") return EVR_OF; if (s == "OW") return EVR_OW; if (s == "PN") return EVR_PN; if (s == "SH") return EVR_SH; if (s == "SL") return EVR_SL; if (s == "SQ") return EVR_SQ; if (s == "SS") return EVR_SS; if (s == "ST") return EVR_ST; if (s == "TM") return EVR_TM; if (s == "UI") return EVR_UI; if (s == "UL") return EVR_UL; if (s == "UN") return EVR_UN; if (s == "US") return EVR_US; if (s == "UT") return EVR_UT; throw OrthancException(ErrorCode_ParameterOutOfRange); } }