// // Extraction.h // // Library: Data // Package: DataCore // Module: Extraction // // Definition of the Extraction class. // // Copyright (c) 2006, Applied Informatics Software Engineering GmbH. // and Contributors. // // SPDX-License-Identifier: BSL-1.0 // #ifndef Data_Extraction_INCLUDED #define Data_Extraction_INCLUDED #include "Poco/Data/Data.h" #include "Poco/Data/AbstractExtraction.h" #include "Poco/Data/Preparation.h" #include "Poco/Data/TypeHandler.h" #include "Poco/Data/Column.h" #include "Poco/Data/Position.h" #include "Poco/Data/DataException.h" #include #include #include #include #include #include namespace Poco { namespace Data { template class Extraction: public AbstractExtraction /// Concrete Data Type specific extraction of values from a query result set. { public: using ValType = T; using ValPtr = SharedPtr; using Type = Extraction; using Ptr = SharedPtr; Extraction(T& result, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default(), _extracted(false), _null(false) /// Creates an Extraction object at specified position. /// Uses an empty object T as default value. { } Extraction(T& result, const T& def, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default(def), _extracted(false), _null(false) /// Creates an Extraction object at specified position. /// Uses the provided def object as default value. { } ~Extraction() /// Destroys the Extraction object. { } std::size_t numOfColumnsHandled() const { return TypeHandler::size(); } std::size_t numOfRowsHandled() const { return _extracted ? 1u : 0; } std::size_t numOfRowsAllowed() const { return 1u; } bool isNull(std::size_t /*row*/ = 0) const { return _null; } std::size_t extract(std::size_t pos) { if (_extracted) throw ExtractException("value already extracted"); _extracted = true; AbstractExtractor::Ptr pExt = getExtractor(); TypeHandler::extract(pos, _rResult, _default, pExt); _null = isValueNull(_rResult, pExt->isNull(pos)); return 1u; } void reset() { _extracted = false; } bool canExtract() const { return !_extracted; } AbstractPreparation::Ptr createPreparation(AbstractPreparator::Ptr& pPrep, std::size_t pos) { return new Preparation(pPrep, pos, _rResult); } private: T& _rResult; T _default; bool _extracted; bool _null; }; template class Extraction>: public AbstractExtraction /// Vector Data Type specialization for extraction of values from a query result set. { public: using ValType = std::vector; using ValPtr = SharedPtr; using Type = Extraction; using Ptr = SharedPtr; Extraction(std::vector& result, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default() { _rResult.clear(); } Extraction(std::vector& result, const T& def, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default(def) { _rResult.clear(); } virtual ~Extraction() { } std::size_t numOfColumnsHandled() const { return TypeHandler::size(); } std::size_t numOfRowsHandled() const { return static_cast(_rResult.size()); } std::size_t numOfRowsAllowed() const { return getLimit(); } bool isNull(std::size_t row) const { try { return _nulls.at(row); } catch (std::out_of_range& ex) { throw RangeException(ex.what()); } } std::size_t extract(std::size_t pos) { AbstractExtractor::Ptr pExt = getExtractor(); _rResult.push_back(_default); TypeHandler::extract(pos, _rResult.back(), _default, pExt); _nulls.push_back(isValueNull(_rResult.back(), pExt->isNull(pos))); return 1u; } AbstractPreparation::Ptr createPreparation(AbstractPreparator::Ptr& pPrep, std::size_t pos) { return new Preparation(pPrep, pos, _default); } void reset() { _nulls.clear(); } protected: const std::vector& result() const { return _rResult; } private: std::vector& _rResult; T _default; std::deque _nulls; }; template <> class Extraction>: public AbstractExtraction /// Vector bool specialization for extraction of values from a query result set. { public: using ValType = std::vector; using ValPtr = SharedPtr; using Type = Extraction; using Ptr = SharedPtr; Extraction(std::vector& result, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default() { _rResult.clear(); } Extraction(std::vector& result, const bool& def, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default(def) { _rResult.clear(); } virtual ~Extraction() { } std::size_t numOfColumnsHandled() const { return TypeHandler::size(); } std::size_t numOfRowsHandled() const { return static_cast(_rResult.size()); } std::size_t numOfRowsAllowed() const { return getLimit(); } bool isNull(std::size_t row) const { try { return _nulls.at(row); } catch (std::out_of_range& ex) { throw RangeException(ex.what()); } } std::size_t extract(std::size_t pos) { AbstractExtractor::Ptr pExt = getExtractor(); bool tmp = _default; TypeHandler::extract(pos, tmp, _default, pExt); _rResult.push_back(tmp); _nulls.push_back(pExt->isNull(pos)); return 1u; } AbstractPreparation::Ptr createPreparation(AbstractPreparator::Ptr& pPrep, std::size_t pos) { return new Preparation(pPrep, pos, _default); } void reset() { _nulls.clear(); } protected: const std::vector& result() const { return _rResult; } private: std::vector& _rResult; bool _default; std::deque _nulls; }; template class Extraction>: public AbstractExtraction /// List Data Type specialization for extraction of values from a query result set. { public: using ValType = std::list; using ValPtr = SharedPtr; using Type = Extraction; using Ptr = SharedPtr; Extraction(std::list& result, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default() { _rResult.clear(); } Extraction(std::list& result, const T& def, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default(def) { _rResult.clear(); } virtual ~Extraction() { } std::size_t numOfColumnsHandled() const { return TypeHandler::size(); } std::size_t numOfRowsHandled() const { return _rResult.size(); } std::size_t numOfRowsAllowed() const { return getLimit(); } bool isNull(std::size_t row) const { try { return _nulls.at(row); } catch (std::out_of_range& ex) { throw RangeException(ex.what()); } } std::size_t extract(std::size_t pos) { AbstractExtractor::Ptr pExt = getExtractor(); _rResult.push_back(_default); TypeHandler::extract(pos, _rResult.back(), _default, pExt); _nulls.push_back(isValueNull(_rResult.back(), pExt->isNull(pos))); return 1u; } AbstractPreparation::Ptr createPreparation(AbstractPreparator::Ptr& pPrep, std::size_t pos) { return new Preparation(pPrep, pos, _default); } void reset() { _nulls.clear(); } protected: const std::list& result() const { return _rResult; } private: std::list& _rResult; T _default; std::deque _nulls; }; template class Extraction>: public AbstractExtraction /// Deque Data Type specialization for extraction of values from a query result set. { public: using ValType = std::deque; using ValPtr = SharedPtr; using Type = Extraction; using Ptr = SharedPtr; Extraction(std::deque& result, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default() { _rResult.clear(); } Extraction(std::deque& result, const T& def, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default(def) { _rResult.clear(); } virtual ~Extraction() { } std::size_t numOfColumnsHandled() const { return TypeHandler::size(); } std::size_t numOfRowsHandled() const { return _rResult.size(); } std::size_t numOfRowsAllowed() const { return getLimit(); } bool isNull(std::size_t row) const { try { return _nulls.at(row); } catch (std::out_of_range& ex) { throw RangeException(ex.what()); } } std::size_t extract(std::size_t pos) { AbstractExtractor::Ptr pExt = getExtractor(); _rResult.push_back(_default); TypeHandler::extract(pos, _rResult.back(), _default, pExt); _nulls.push_back(isValueNull(_rResult.back(), pExt->isNull(pos))); return 1u; } AbstractPreparation::Ptr createPreparation(AbstractPreparator::Ptr& pPrep, std::size_t pos) { return new Preparation(pPrep, pos, _default); } void reset() { _nulls.clear(); } protected: const std::deque& result() const { return _rResult; } private: std::deque& _rResult; T _default; std::deque _nulls; }; template class InternalExtraction: public Extraction /// Container Data Type extension for extraction of values from a query result set. /// /// This class is intended for PocoData internal use - it is used by StatementImpl /// to automatically create internal Extraction in cases when statement returns data and no external storage /// was supplied. It is later used by RecordSet to retrieve the fetched data after statement execution. /// It takes ownership of the Column pointer supplied as constructor argument. Column object, in turn /// owns the data container pointer. /// /// InternalExtraction objects can not be copied or assigned. { public: using HeldValType = typename C::value_type; InternalExtraction(C& result, Column* pColumn, const Position& pos = Position(0)): Extraction(result, HeldValType(), pos), _pColumn(pColumn) /// Creates InternalExtraction. { AbstractExtraction::setHeldType(); } ~InternalExtraction() /// Destroys InternalExtraction. { delete _pColumn; } void reset() { Extraction::reset(); _pColumn->reset(); } const HeldValType& value(int index) const { try { return Extraction::result().at(index); } catch (std::out_of_range& ex) { throw RangeException(ex.what()); } } bool isNull(std::size_t row) const { return Extraction::isNull(row); } const Column& column() const { return *_pColumn; } private: InternalExtraction(); InternalExtraction(const InternalExtraction&); InternalExtraction& operator = (const InternalExtraction&); Column* _pColumn; }; template class Extraction>: public AbstractExtraction /// Set Data Type specialization for extraction of values from a query result set. { public: using ValType = std::set; using ValPtr = SharedPtr; using Type = Extraction; using Ptr = SharedPtr; using Iterator = typename ValType::iterator; Extraction(std::set& result, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default() { _rResult.clear(); } Extraction(std::set& result, const T& def, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default(def) { _rResult.clear(); } ~Extraction() { } std::size_t numOfColumnsHandled() const { return TypeHandler::size(); } std::size_t numOfRowsHandled() const { return static_cast(_rResult.size()); } std::size_t numOfRowsAllowed() const { return getLimit(); } std::size_t extract(std::size_t pos) { T tmp; TypeHandler::extract(pos, tmp, _default, getExtractor()); _rResult.insert(tmp); return 1u; } AbstractPreparation::Ptr createPreparation(AbstractPreparator::Ptr& pPrep, std::size_t pos) { return new Preparation(pPrep, pos, _default); } private: std::set& _rResult; T _default; }; template class Extraction>: public AbstractExtraction /// Multiset Data Type specialization for extraction of values from a query result set. { public: using ValType = std::multiset; using ValPtr = SharedPtr; using Type = Extraction; using Ptr = SharedPtr; Extraction(std::multiset& result, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default() { _rResult.clear(); } Extraction(std::multiset& result, const T& def, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default(def) { _rResult.clear(); } ~Extraction() { } std::size_t numOfColumnsHandled() const { return TypeHandler::size(); } std::size_t numOfRowsHandled() const { return static_cast(_rResult.size()); } std::size_t numOfRowsAllowed() const { return getLimit(); } std::size_t extract(std::size_t pos) { T tmp; TypeHandler::extract(pos, tmp, _default, getExtractor()); _rResult.insert(tmp); return 1u; } AbstractPreparation::Ptr createPreparation(AbstractPreparator::Ptr& pPrep, std::size_t pos) { return new Preparation(pPrep, pos, _default); } private: std::multiset& _rResult; T _default; }; template class Extraction>: public AbstractExtraction /// Map Data Type specialization for extraction of values from a query result set. { public: using ValType = std::map; using ValPtr = SharedPtr; using Type = Extraction; using Ptr = SharedPtr; Extraction(std::map& result, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default() { _rResult.clear(); } Extraction(std::map& result, const V& def, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default(def) { _rResult.clear(); } ~Extraction() { } std::size_t numOfColumnsHandled() const { return TypeHandler::size(); } std::size_t numOfRowsHandled() const { return static_cast(_rResult.size()); } std::size_t numOfRowsAllowed() const { return getLimit(); } std::size_t extract(std::size_t pos) { V tmp; TypeHandler::extract(pos, tmp, _default, getExtractor()); _rResult.insert(std::make_pair(tmp(), tmp)); return 1u; } AbstractPreparation::Ptr createPreparation(AbstractPreparator::Ptr& pPrep, std::size_t pos) { return new Preparation(pPrep, pos, _default); } private: std::map& _rResult; V _default; }; template class Extraction>: public AbstractExtraction /// Multimap Data Type specialization for extraction of values from a query result set. { public: using ValType = std::multimap; using ValPtr = SharedPtr; using Type = Extraction; using Ptr = SharedPtr; Extraction(std::multimap& result, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default() { _rResult.clear(); } Extraction(std::multimap& result, const V& def, const Position& pos = Position(0)): AbstractExtraction(Limit::LIMIT_UNLIMITED, pos.value()), _rResult(result), _default(def) { _rResult.clear(); } ~Extraction() { } std::size_t numOfColumnsHandled() const { return TypeHandler::size(); } std::size_t numOfRowsHandled() const { return static_cast(_rResult.size()); } std::size_t numOfRowsAllowed() const { return getLimit(); } std::size_t extract(std::size_t pos) { V tmp; TypeHandler::extract(pos, tmp, _default, getExtractor()); _rResult.insert(std::make_pair(tmp(), tmp)); return 1u; } AbstractPreparation::Ptr createPreparation(AbstractPreparator::Ptr& pPrep, std::size_t pos) { return new Preparation(pPrep, pos, _default); } private: std::multimap& _rResult; V _default; }; namespace Keywords { template inline AbstractExtraction::Ptr into(T& t) /// Convenience function to allow for a more compact creation of an extraction object. { return new Extraction(t); } template inline AbstractExtraction::Ptr into(T& t, const Position& pos) /// Convenience function to allow for a more compact creation of an extraction object /// with multiple recordset support. { return new Extraction(t, pos); } template inline AbstractExtraction::Ptr into(T& t, const Position& pos, const T& def) /// Convenience function to allow for a more compact creation of an extraction object /// with multiple recordset support and the given default { return new Extraction(t, def, pos); } inline AbstractExtractionVecVec& into(AbstractExtractionVecVec& evv) /// Convenience dummy function (for syntax purposes only). { return evv; } inline AbstractExtractionVec& into(AbstractExtractionVec& ev) /// Convenience dummy function (for syntax purposes only). { return ev; } } // namespace Keywords } } // namespace Poco::Data #endif // Data_Extraction_INCLUDED