Mercurial > hg > orthanc
view OrthancServer/Sources/Database/Compatibility/DatabaseLookup.cpp @ 5858:66fd63b8601e find-refactoring tip
StorageAccessOnFind: cont
author | Alain Mazy <am@orthanc.team> |
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date | Mon, 04 Nov 2024 22:34:14 +0100 |
parents | 7030fa489669 |
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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 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 * 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" #include "DatabaseLookup.h" #include "../../../../OrthancFramework/Sources/OrthancException.h" #include "../../Search/DicomTagConstraint.h" #include "../../ServerToolbox.h" #include "SetOfResources.h" namespace Orthanc { namespace Compatibility { namespace { // Anonymous namespace to avoid clashes between compiler modules class MainTagsConstraints : boost::noncopyable { private: std::vector<DicomTagConstraint*> constraints_; public: ~MainTagsConstraints() { for (size_t i = 0; i < constraints_.size(); i++) { assert(constraints_[i] != NULL); delete constraints_[i]; } } void Reserve(size_t n) { constraints_.reserve(n); } size_t GetSize() const { return constraints_.size(); } DicomTagConstraint& GetConstraint(size_t i) const { if (i >= constraints_.size()) { throw OrthancException(ErrorCode_ParameterOutOfRange); } else { assert(constraints_[i] != NULL); return *constraints_[i]; } } void Add(const DatabaseDicomTagConstraint& constraint) { constraints_.push_back(new DicomTagConstraint(constraint)); } }; } static void ApplyIdentifierConstraint(SetOfResources& candidates, ILookupResources& compatibility, const DatabaseDicomTagConstraint& constraint, ResourceType level) { std::list<int64_t> matches; switch (constraint.GetConstraintType()) { case ConstraintType_Equal: compatibility.LookupIdentifier(matches, level, constraint.GetTag(), IdentifierConstraintType_Equal, constraint.GetSingleValue()); break; case ConstraintType_SmallerOrEqual: compatibility.LookupIdentifier(matches, level, constraint.GetTag(), IdentifierConstraintType_SmallerOrEqual, constraint.GetSingleValue()); break; case ConstraintType_GreaterOrEqual: compatibility.LookupIdentifier(matches, level, constraint.GetTag(), IdentifierConstraintType_GreaterOrEqual, constraint.GetSingleValue()); break; case ConstraintType_Wildcard: compatibility.LookupIdentifier(matches, level, constraint.GetTag(), IdentifierConstraintType_Wildcard, constraint.GetSingleValue()); break; case ConstraintType_List: for (size_t i = 0; i < constraint.GetValuesCount(); i++) { std::list<int64_t> tmp; compatibility.LookupIdentifier(tmp, level, constraint.GetTag(), IdentifierConstraintType_Wildcard, constraint.GetValue(i)); matches.splice(matches.end(), tmp); } break; default: throw OrthancException(ErrorCode_InternalError); } candidates.Intersect(matches); } static void ApplyIdentifierRange(SetOfResources& candidates, ILookupResources& compatibility, const DatabaseDicomTagConstraint& smaller, const DatabaseDicomTagConstraint& greater, ResourceType level) { assert(smaller.GetConstraintType() == ConstraintType_SmallerOrEqual && greater.GetConstraintType() == ConstraintType_GreaterOrEqual && smaller.GetTag() == greater.GetTag() && ServerToolbox::IsIdentifier(smaller.GetTag(), level)); std::list<int64_t> matches; compatibility.LookupIdentifierRange(matches, level, smaller.GetTag(), greater.GetSingleValue(), smaller.GetSingleValue()); candidates.Intersect(matches); } static void ApplyLevel(SetOfResources& candidates, IDatabaseWrapper::ITransaction& transaction, ILookupResources& compatibility, const DatabaseDicomTagConstraints& lookup, ResourceType level) { typedef std::set<const DatabaseDicomTagConstraint*> SetOfConstraints; typedef std::map<DicomTag, SetOfConstraints> Identifiers; // (1) Select which constraints apply to this level, and split // them between "identifier tags" constraints and "main DICOM // tags" constraints Identifiers identifiers; SetOfConstraints mainTags; for (size_t i = 0; i < lookup.GetSize(); i++) { const DatabaseDicomTagConstraint& constraint = lookup.GetConstraint(i); if (constraint.GetLevel() == level) { if (constraint.IsIdentifier()) { identifiers[constraint.GetTag()].insert(&constraint); } else { mainTags.insert(&constraint); } } } // (2) Apply the constraints over the identifiers for (Identifiers::const_iterator it = identifiers.begin(); it != identifiers.end(); ++it) { // Check whether some range constraint over identifiers is // present at this level const DatabaseDicomTagConstraint* smaller = NULL; const DatabaseDicomTagConstraint* greater = NULL; for (SetOfConstraints::const_iterator it2 = it->second.begin(); it2 != it->second.end(); ++it2) { assert(*it2 != NULL); if ((*it2)->GetConstraintType() == ConstraintType_SmallerOrEqual) { smaller = *it2; } if ((*it2)->GetConstraintType() == ConstraintType_GreaterOrEqual) { greater = *it2; } } if (smaller != NULL && greater != NULL) { // There is a range constraint: Apply it, as it is more efficient ApplyIdentifierRange(candidates, compatibility, *smaller, *greater, level); } else { smaller = NULL; greater = NULL; } for (SetOfConstraints::const_iterator it2 = it->second.begin(); it2 != it->second.end(); ++it2) { // Check to avoid applying twice the range constraint if (*it2 != smaller && *it2 != greater) { ApplyIdentifierConstraint(candidates, compatibility, **it2, level); } } } // (3) Apply the constraints over the main DICOM tags (no index // here, so this is less efficient than filtering over the // identifiers) if (!mainTags.empty()) { MainTagsConstraints c; c.Reserve(mainTags.size()); for (SetOfConstraints::const_iterator it = mainTags.begin(); it != mainTags.end(); ++it) { assert(*it != NULL); c.Add(**it); } std::list<int64_t> source; candidates.Flatten(compatibility, source); candidates.Clear(); std::list<int64_t> filtered; for (std::list<int64_t>::const_iterator candidate = source.begin(); candidate != source.end(); ++candidate) { DicomMap tags; transaction.GetMainDicomTags(tags, *candidate); bool match = true; for (size_t i = 0; i < c.GetSize(); i++) { if (!c.GetConstraint(i).IsMatch(tags)) { match = false; break; } } if (match) { filtered.push_back(*candidate); } } candidates.Intersect(filtered); } } static std::string GetOneInstance(IDatabaseWrapper::ITransaction& compatibility, int64_t resource, ResourceType level) { for (int i = level; i < ResourceType_Instance; i++) { assert(compatibility.GetResourceType(resource) == static_cast<ResourceType>(i)); std::list<int64_t> children; compatibility.GetChildrenInternalId(children, resource); if (children.empty()) { throw OrthancException(ErrorCode_Database); } resource = children.front(); } return compatibility.GetPublicId(resource); } void DatabaseLookup::ApplyLookupResources(std::list<std::string>& resourcesId, std::list<std::string>* instancesId, const DatabaseDicomTagConstraints& lookup, ResourceType queryLevel, size_t limit) { // This is a re-implementation of // "../../../Resources/Graveyard/DatabaseOptimizations/LookupResource.cpp" assert(ResourceType_Patient < ResourceType_Study && ResourceType_Study < ResourceType_Series && ResourceType_Series < ResourceType_Instance); ResourceType upperLevel = queryLevel; ResourceType lowerLevel = queryLevel; for (size_t i = 0; i < lookup.GetSize(); i++) { ResourceType level = lookup.GetConstraint(i).GetLevel(); if (level < upperLevel) { upperLevel = level; } if (level > lowerLevel) { lowerLevel = level; } } assert(upperLevel <= queryLevel && queryLevel <= lowerLevel); SetOfResources candidates(transaction_, upperLevel); for (int level = upperLevel; level <= lowerLevel; level++) { ApplyLevel(candidates, transaction_, compatibility_, lookup, static_cast<ResourceType>(level)); if (level != lowerLevel) { candidates.GoDown(); } } std::list<int64_t> resources; candidates.Flatten(compatibility_, resources); // Climb up, up to queryLevel for (int level = lowerLevel; level > queryLevel; level--) { std::list<int64_t> parents; for (std::list<int64_t>::const_iterator it = resources.begin(); it != resources.end(); ++it) { int64_t parent; if (transaction_.LookupParent(parent, *it)) { parents.push_back(parent); } } resources.swap(parents); } // Apply the limit, if given if (limit != 0 && resources.size() > limit) { resources.resize(limit); } // Get the public ID of all the selected resources size_t pos = 0; for (std::list<int64_t>::const_iterator it = resources.begin(); it != resources.end(); ++it, pos++) { assert(transaction_.GetResourceType(*it) == queryLevel); const std::string resource = transaction_.GetPublicId(*it); resourcesId.push_back(resource); if (instancesId != NULL) { if (queryLevel == ResourceType_Instance) { // The resource is itself the instance instancesId->push_back(resource); } else { // Collect one child instance for each of the selected resources instancesId->push_back(GetOneInstance(transaction_, *it, queryLevel)); } } } } } }