// Copyright (C) 2007-2012 CEA/DEN, EDF R&D, OPEN CASCADE // // Copyright (C) 2003-2007 OPEN CASCADE, EADS/CCR, LIP6, CEA/DEN, // CEDRAT, EDF R&D, LEG, PRINCIPIA R&D, BUREAU VERITAS // // This library 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 2.1 of the License. // // This library 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 library; if not, write to the Free Software // Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA // // See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com // // File : SMESH_smesh.hxx // Created : Fri Nov 18 12:05:18 2005 // Author : Edward AGAPOV (eap) // #ifndef SMESH_smesh_HeaderFile #define SMESH_smesh_HeaderFile #include #include #include #include #include #include #include #include #include #include #include #include CORBA_CLIENT_HEADER(SALOMEDS) // =========================================================================================== /*! * This file was created in order to respond to requirement of bug PAL10494: * SMESH python dump uses idl interface. * * The creation reason is that smesh.py commands defining hypotheses encapsulate * several SMESH engine method calls. As well, the dependencies between smesh.py * classes differ from ones between corresponding SMESH IDL interfaces. * * Everything here is for internal usage by SMESH_2smeshpy::ConvertScript() * declared in SMESH_PythonDump.hxx */ // =========================================================================================== class Resource_DataMapOfAsciiStringAsciiString; // =========================================================================================== // ===================== // INTERNAL STUFF // ===================== // =========================================================================================== class _pyCommand; class _pyObject; class _pyGen; class _pyMesh; class _pySubMesh; class _pyHypothesis; class _pyAlgorithm; class _pyHypothesisReader; DEFINE_STANDARD_HANDLE (_pyCommand ,Standard_Transient); DEFINE_STANDARD_HANDLE (_pyObject ,Standard_Transient); DEFINE_STANDARD_HANDLE (_pyHypothesisReader,Standard_Transient); DEFINE_STANDARD_HANDLE (_pyGen ,_pyObject); DEFINE_STANDARD_HANDLE (_pyMesh ,_pyObject); DEFINE_STANDARD_HANDLE (_pySubMesh ,_pyObject); DEFINE_STANDARD_HANDLE (_pyGroup ,_pySubMesh); DEFINE_STANDARD_HANDLE (_pyMeshEditor ,_pyObject); DEFINE_STANDARD_HANDLE (_pyHypothesis ,_pyObject); DEFINE_STANDARD_HANDLE (_pyAlgorithm ,_pyHypothesis); typedef TCollection_AsciiString _pyID; typedef TCollection_AsciiString _AString; // =========================================================== /*! * \brief Class operating on a command string looking like * ResultValue = Object.Method( Arg1, Arg2,...) */ // =========================================================== class _pyCommand: public Standard_Transient { int myOrderNb; //!< position within the script _AString myString; //!< command text _AString myRes, myObj, myMeth; //!< found parts of command TColStd_SequenceOfAsciiString myArgs; //!< found arguments TColStd_SequenceOfInteger myBegPos; //!< where myRes, myObj, ... begin std::list< Handle(_pyCommand) > myDependentCmds; //!< commands that sould follow me in the script enum { UNKNOWN=-1, EMPTY=0, RESULT_IND, OBJECT_IND, METHOD_IND, ARG1_IND }; int GetBegPos( int thePartIndex ); void SetBegPos( int thePartIndex, int thePosition ); void SetPart( int thePartIndex, const _AString& theNewPart, _AString& theOldPart); void FindAllArgs() { GetArg(1); } public: _pyCommand() {}; _pyCommand( const _AString& theString, int theNb=-1 ) : myString( theString ), myOrderNb( theNb ) {}; _AString & GetString() { return myString; } int GetOrderNb() const { return myOrderNb; } void SetOrderNb( int theNb ) { myOrderNb = theNb; } typedef void* TAddr; TAddr GetAddress() const { return (void*) this; } int Length() { return myString.Length(); } void Clear() { myString.Clear(); myBegPos.Clear(); myArgs.Clear(); } bool IsEmpty() const { return myString.IsEmpty(); } _AString GetIndentation(); const _AString & GetResultValue(); const int GetNbResultValues(); _AString GetResultValue(int res); const _AString & GetObject(); const _AString & GetMethod(); const _AString & GetArg( int index ); int GetNbArgs() { FindAllArgs(); return myArgs.Length(); } bool MethodStartsFrom(const _AString& beg) { GetMethod(); return ( myMeth.Location( beg, 1, myMeth.Length() ) == 1 ); } void SetResultValue( const _AString& theResult ) { GetResultValue(); SetPart( RESULT_IND, theResult, myRes ); } void SetObject(const _AString& theObject) { GetObject(); SetPart( OBJECT_IND, theObject, myObj ); } void SetMethod(const _AString& theMethod) { GetMethod(); SetPart( METHOD_IND, theMethod, myMeth ); } void SetArg( int index, const _AString& theArg); void RemoveArgs(); void Comment(); static bool SkipSpaces( const _AString & theSring, int & thePos ); static _AString GetWord( const _AString & theSring, int & theStartPos, const bool theForward, const bool dotIsWord = false); static bool IsStudyEntry( const _AString& str ); static std::list< _pyID > GetStudyEntries( const _AString& str ); void AddDependantCmd( Handle(_pyCommand) cmd, bool prepend = false) { if (prepend) myDependentCmds.push_front( cmd ); else myDependentCmds.push_back( cmd ); } bool SetDependentCmdsAfter() const; bool AddAccessorMethod( _pyID theObjectID, const char* theAcsMethod ); DEFINE_STANDARD_RTTI (_pyCommand) }; // ------------------------------------------------------------------------------------- /*! * \brief Root of all objects. It counts calls of Process() */ // ------------------------------------------------------------------------------------- class _pyObject: public Standard_Transient { protected: _pyID myID; Handle(_pyCommand) myCreationCmd; std::list< Handle(_pyCommand) > myProcessedCmds; bool myIsPublished; void setID(const _pyID& theID); public: _pyObject(const Handle(_pyCommand)& theCreationCmd, const _pyID& theID=_pyID()); const _pyID& GetID() { return myID.IsEmpty() ? myCreationCmd->GetResultValue() : myID; } static _pyID FatherID(const _pyID & childID); const Handle(_pyCommand)& GetCreationCmd() { return myCreationCmd; } int GetNbCalls() const { return myProcessedCmds.size(); } bool IsInStudy() const { return myIsPublished; } virtual void SetRemovedFromStudy(const bool isRemoved) { myIsPublished = !isRemoved; } void SetCreationCmd( Handle(_pyCommand) cmd ) { myCreationCmd = cmd; } int GetCommandNb() { return myCreationCmd->GetOrderNb(); } void AddProcessedCmd( const Handle(_pyCommand) & cmd ) { if (myProcessedCmds.empty() || myProcessedCmds.back()!=cmd) myProcessedCmds.push_back( cmd );} std::list< Handle(_pyCommand) >& GetProcessedCmds() { return myProcessedCmds; } virtual void Process(const Handle(_pyCommand) & cmd) { AddProcessedCmd(cmd); } virtual void Flush() = 0; virtual const char* AccessorMethod() const; virtual bool CanClear() { return !myIsPublished; } virtual void ClearCommands(); virtual void Free() {} DEFINE_STANDARD_RTTI (_pyObject) }; // ------------------------------------------------------------------------------------- /*! * \brief Data used to restore cleared Compute() command of an exported mesh * when an imported mesh is created */ // ------------------------------------------------------------------------------------- struct ExportedMeshData { Handle(_pyMesh) myMesh; Handle(_pyCommand) myLastComputeCmd; _AString myLastComputeCmdString; ExportedMeshData() {} ExportedMeshData( const Handle(_pyMesh)& mesh, Handle(_pyCommand) computeCmd): myMesh( mesh ), myLastComputeCmd( computeCmd ) { if ( !myLastComputeCmd.IsNull()) myLastComputeCmdString = myLastComputeCmd->GetString(); } }; // ------------------------------------------------------------------------------------- /*! * \brief Class corresponding to SMESH_Gen. It holds info on existing * meshes and hypotheses */ // ------------------------------------------------------------------------------------- class _pyGen: public _pyObject { public: _pyGen(Resource_DataMapOfAsciiStringAsciiString& theEntry2AccessorMethod, Resource_DataMapOfAsciiStringAsciiString& theObjectNames, SALOMEDS::Study_ptr& theStudy, const bool theToKeepAllCommands); Handle(_pyCommand) AddCommand( const _AString& theCommand ); void ExchangeCommands( Handle(_pyCommand) theCmd1, Handle(_pyCommand) theCmd2 ); void SetCommandAfter( Handle(_pyCommand) theCmd, Handle(_pyCommand) theAfterCmd ); void SetCommandBefore( Handle(_pyCommand) theCmd, Handle(_pyCommand) theBeforeCmd ); Handle(_pyCommand)& GetLastCommand(); std::list< Handle(_pyCommand) >& GetCommands() { return myCommands; } void PlaceSubmeshAfterItsCreation( Handle(_pyCommand) theCmdUsingSubmesh ) const; _pyID GenerateNewID( const _pyID& theID ); void AddObject( Handle(_pyObject)& theObj ); void SetProxyObject( const _pyID& theID, Handle(_pyObject)& theObj ); Handle(_pyObject) FindObject( const _pyID& theObjID ) const; Handle(_pySubMesh) FindSubMesh( const _pyID& theSubMeshID ); Handle(_pyHypothesis) FindHyp( const _pyID& theHypID ); Handle(_pyHypothesis) FindAlgo( const _pyID& theGeom, const _pyID& theMesh, const Handle(_pyHypothesis)& theHypothesis); void SetAccessorMethod(const _pyID& theID, const char* theMethod ); bool AddMeshAccessorMethod( Handle(_pyCommand) theCmd ) const; bool AddAlgoAccessorMethod( Handle(_pyCommand) theCmd ) const; virtual const char* AccessorMethod() const; bool IsGeomObject(const _pyID& theObjID) const; bool IsNotPublished(const _pyID& theObjID) const; bool IsToKeepAllCommands() const { return myToKeepAllCommands; } void AddExportedMesh(const _AString& file, const ExportedMeshData& mesh ) { myFile2ExportedMesh[ file ] = mesh; } ExportedMeshData& FindExportedMesh( const _AString& file ) { return myFile2ExportedMesh[ file ]; } virtual void Process( const Handle(_pyCommand)& theCommand ); virtual void Flush(); virtual void ClearCommands(); virtual void Free(); Handle( _pyHypothesisReader ) GetHypothesisReader() const; private: void setNeighbourCommand( Handle(_pyCommand)& theCmd, Handle(_pyCommand)& theOtherCmd, const bool theIsAfter ); private: std::map< _pyID, Handle(_pyMesh) > myMeshes; std::map< _pyID, Handle(_pyMeshEditor) > myMeshEditors; std::map< _pyID, Handle(_pyObject) > myObjects; std::list< Handle(_pyHypothesis) > myHypos; std::list< Handle(_pyCommand) > myCommands; int myNbCommands; Resource_DataMapOfAsciiStringAsciiString& myID2AccessorMethod; Resource_DataMapOfAsciiStringAsciiString& myObjectNames; Handle(_pyCommand) myLastCommand; int myNbFilters; bool myToKeepAllCommands; SALOMEDS::Study_var myStudy; int myGeomIDNb, myGeomIDIndex; std::map< _AString, ExportedMeshData > myFile2ExportedMesh; Handle( _pyHypothesisReader ) myHypReader; DEFINE_STANDARD_RTTI (_pyGen) }; // ------------------------------------------------------------------------------------- /*! * \brief Contains commands concerning mesh substructures */ // ------------------------------------------------------------------------------------- #define _pyMesh_ACCESS_METHOD "GetMesh()" class _pyMesh: public _pyObject { std::list< Handle(_pyHypothesis) > myHypos; std::list< Handle(_pyCommand) > myAddHypCmds; std::list< Handle(_pySubMesh) > mySubmeshes; std::list< Handle(_pyGroup) > myGroups; std::list< Handle(_pyMeshEditor)> myEditors; //d::list< Handle(_pyMesh) > myFatherMeshes; // this mesh depends on std::list< Handle(_pyMesh) > myChildMeshes; // depending on me bool myGeomNotInStudy; Handle(_pyCommand) myLastComputeCmd; public: _pyMesh(const Handle(_pyCommand) creationCmd); _pyMesh(const Handle(_pyCommand) theCreationCmd, const _pyID & id); const _pyID& GetGeom() { return GetCreationCmd()->GetArg(1); } void AddGroup( const Handle(_pyGroup)& g ) { myGroups.push_back( g ); } void AddEditor( const Handle(_pyMeshEditor)& e ) { myEditors.push_back( e ); } bool IsNotGeomPublished() { return myGeomNotInStudy; } virtual void Process( const Handle(_pyCommand)& theCommand); virtual void Flush(); virtual void SetRemovedFromStudy(const bool isRemoved); virtual bool CanClear(); virtual void ClearCommands(); virtual void Free() { /*myFatherMeshes.clear();*/ myChildMeshes.clear(); } virtual const char* AccessorMethod() const { return _pyMesh_ACCESS_METHOD; } private: void addFatherMesh( const Handle(_pyMesh)& mesh ); void addFatherMesh( const _pyID& meshID ); static bool NeedMeshAccess( const Handle(_pyCommand)& theCommand ); static void AddMeshAccess( const Handle(_pyCommand)& theCommand ) { theCommand->SetObject( theCommand->GetObject() + "." _pyMesh_ACCESS_METHOD ); } DEFINE_STANDARD_RTTI (_pyMesh) }; #undef _pyMesh_ACCESS_METHOD // ------------------------------------------------------------------------------------- /*! * \brief MeshEditor convert its commands to ones of mesh */ // ------------------------------------------------------------------------------------- class _pyMeshEditor: public _pyObject { _pyID myMesh; _AString myCreationCmdStr; public: _pyMeshEditor(const Handle(_pyCommand)& theCreationCmd); _pyID GetMesh() const { return myMesh; } virtual void Process( const Handle(_pyCommand)& theCommand); virtual void Flush() {} virtual bool CanClear(); DEFINE_STANDARD_RTTI (_pyMesh) }; // ------------------------------------------------------------------------------------- /*! * \brief Root class for hypothesis */ // ------------------------------------------------------------------------------------- class _pyHypothesis: public _pyObject { friend class _pyHypothesisReader; protected: bool myIsAlgo, myIsWrapped; _pyID myGeom, myMesh; struct CreationMethod { _AString myMethod; // method of algo or mesh creating a hyp // myArgNb(i)-th arg of myArgMethods(i) of hyp becomes an i-th arg of myMethod std::vector<_AString> myArgMethods; std::vector myArgNb; // arg nb countered from 1 std::vector<_AString> myArgs; // creation arguments }; void setCreationArg( const int argNb, const _AString& arg ); // a hypothesis can be created by different algos by different methods typedef std::map<_AString, CreationMethod > TType2CrMethod; TType2CrMethod myAlgoType2CreationMethod; std::set< _AString > myAccumulativeMethods; CreationMethod* myCurCrMethod; // used for adding to myAlgoType2CreationMethod std::list myArgCommands; std::list myUnusedCommands; std::list myReferredObjs; // maps used to clear commands setting parameters if result of setting is // discared (e.g. by mesh.Clear()) std::map<_AString, std::list > myMeth2Commands; std::map< _pyCommand::TAddr, std::list > myComputeAddr2Cmds; std::list myComputeCmds; void rememberCmdOfParameter( const Handle(_pyCommand) & cmd ); bool isCmdUsedForCompute( const Handle(_pyCommand) & cmd, _pyCommand::TAddr avoidComputeAddr=NULL ) const; public: _pyHypothesis(const Handle(_pyCommand)& theCreationCmd); void SetConvMethodAndType(const _AString& creationMethod, const _AString& type) { myCurCrMethod = &myAlgoType2CreationMethod[ type ]; myCurCrMethod->myMethod = creationMethod; } void AddArgMethod(const _AString& method, const int argNb = 1) { myCurCrMethod->myArgMethods.push_back( method ); myCurCrMethod->myArgNb.push_back( argNb ); } void AddAccumulativeMethod( const _AString& method) { myAccumulativeMethods.insert( method ); } //const TColStd_SequenceOfAsciiString& GetArgs() const { return myArgs; } const std::list& GetArgCommands() const { return myArgCommands; } void ClearAllCommands(); virtual bool IsAlgo() const { return myIsAlgo; } bool IsValid() const { return !myAlgoType2CreationMethod.empty(); } bool IsWrapped() const { return myIsWrapped; } const _pyID & GetGeom() const { return myGeom; } void SetMesh( const _pyID& theMeshId) { if ( myMesh.IsEmpty() ) myMesh = theMeshId; } const _pyID & GetMesh() const { return myMesh; } const _AString& GetAlgoType() const { return myAlgoType2CreationMethod.begin()->first; } const _AString& GetAlgoCreationMethod() const { return myAlgoType2CreationMethod.begin()->second.myMethod; } bool CanBeCreatedBy(const _AString& algoType ) const { return myAlgoType2CreationMethod.find( algoType ) != myAlgoType2CreationMethod.end(); } const _AString& GetCreationMethod(const _AString& algoType) { return ( myCurCrMethod = & myAlgoType2CreationMethod[ algoType ])->myMethod; } static Handle(_pyHypothesis) NewHypothesis( const Handle(_pyCommand)& theCreationCmd); virtual bool IsWrappable(const _pyID& theMesh) const; virtual bool Addition2Creation( const Handle(_pyCommand)& theAdditionCmd, const _pyID& theMesh); virtual void Process( const Handle(_pyCommand)& theCommand); virtual void Flush(); virtual void Free() { myReferredObjs.clear(); } virtual void Assign( const Handle(_pyHypothesis)& theOther, const _pyID& theMesh ); virtual bool CanClear(); virtual void ClearCommands(); virtual bool GetReferredMeshesAndGeom( std::list< Handle(_pyMesh) >& meshes ); void MeshComputed ( const Handle(_pyCommand)& theComputeCommand ); void ComputeDiscarded( const Handle(_pyCommand)& theComputeCommand ); //void ComputeSaved ( const Handle(_pyCommand)& theComputeCommand ); DEFINE_STANDARD_RTTI (_pyHypothesis) }; // ------------------------------------------------------------------------------------- /*! * \brief Class representing smesh.Mesh_Algorithm */ // ------------------------------------------------------------------------------------- class _pyAlgorithm: public _pyHypothesis { public: _pyAlgorithm(const Handle(_pyCommand)& theCreationCmd); virtual bool Addition2Creation( const Handle(_pyCommand)& theAdditionCmd, const _pyID& theMesh); virtual const char* AccessorMethod() const { return "GetAlgorithm()"; } virtual bool IsWrappable(const _pyID& theMesh) { return !myIsWrapped; } DEFINE_STANDARD_RTTI (_pyAlgorithm) }; // ------------------------------------------------------------------------------------- /*! * \brief Class for hypotheses having several parameters modified by one method */ // ------------------------------------------------------------------------------------- class _pyComplexParamHypo: public _pyHypothesis { public: _pyComplexParamHypo(const Handle(_pyCommand)& theCreationCmd): _pyHypothesis(theCreationCmd) {} virtual void Process( const Handle(_pyCommand)& theCommand); virtual void Flush(); DEFINE_STANDARD_RTTI (_pyComplexParamHypo) }; DEFINE_STANDARD_HANDLE (_pyComplexParamHypo, _pyHypothesis); // ------------------------------------------------------------------------------------- /*! * \brief Class for LayerDistribution hypothesis conversion */ // ------------------------------------------------------------------------------------- class _pyLayerDistributionHypo: public _pyHypothesis { Handle(_pyHypothesis) my1dHyp; _AString myAlgoMethod; public: _pyLayerDistributionHypo(const Handle(_pyCommand)& theCreationCmd, const char* algoMethod): _pyHypothesis(theCreationCmd), myAlgoMethod((char*)algoMethod) {} virtual void Process( const Handle(_pyCommand)& theCommand); virtual void Flush(); virtual bool Addition2Creation( const Handle(_pyCommand)& theAdditionCmd, const _pyID& theMesh); virtual void Free() { my1dHyp.Nullify(); } DEFINE_STANDARD_RTTI (_pyLayerDistributionHypo) }; DEFINE_STANDARD_HANDLE (_pyLayerDistributionHypo, _pyHypothesis); // ------------------------------------------------------------------------------------- /*! * \brief Class representing NumberOfSegments hypothesis */ // ------------------------------------------------------------------------------------- class _pyNumberOfSegmentsHyp: public _pyHypothesis { public: _pyNumberOfSegmentsHyp(const Handle(_pyCommand)& theCrCmd): _pyHypothesis(theCrCmd) {} virtual bool Addition2Creation( const Handle(_pyCommand)& theAdditionCmd, const _pyID& theMesh); void Flush(); DEFINE_STANDARD_RTTI (_pyNumberOfSegmentsHyp) }; DEFINE_STANDARD_HANDLE (_pyNumberOfSegmentsHyp, _pyHypothesis); // ------------------------------------------------------------------------------------- /*! * \brief Class representing SegmentLengthAroundVertex hypothesis */ // ------------------------------------------------------------------------------------- class _pySegmentLengthAroundVertexHyp: public _pyHypothesis { public: _pySegmentLengthAroundVertexHyp(const Handle(_pyCommand)& theCrCmd): _pyHypothesis(theCrCmd) {} virtual bool Addition2Creation( const Handle(_pyCommand)& theAdditionCmd, const _pyID& theMesh); DEFINE_STANDARD_RTTI (_pySegmentLengthAroundVertexHyp) }; DEFINE_STANDARD_HANDLE (_pySegmentLengthAroundVertexHyp, _pyHypothesis); // ------------------------------------------------------------------------------------- /*! * \brief SelfEraser erases creation command if no more it's commands invoked */ // ------------------------------------------------------------------------------------- class _pySelfEraser: public _pyObject { public: _pySelfEraser(const Handle(_pyCommand)& theCreationCmd) :_pyObject(theCreationCmd) { myIsPublished = true; } virtual void Flush(); DEFINE_STANDARD_RTTI (_pySelfEraser) }; DEFINE_STANDARD_HANDLE (_pySelfEraser, _pyObject); // ------------------------------------------------------------------------------------- /*! * \brief SubMesh creation can be moved to the end of engine commands */ // ------------------------------------------------------------------------------------- class _pySubMesh: public _pyObject { Handle(_pyObject) myCreator; Handle(_pyMesh) myMesh; public: _pySubMesh(const Handle(_pyCommand)& theCreationCmd); virtual void Process( const Handle(_pyCommand)& theCommand); virtual void Flush(); virtual Handle(_pyMesh) GetMesh() { return myMesh; } virtual void Free() { myCreator.Nullify(); myMesh.Nullify(); } void SetCreator( const Handle(_pyObject)& theCreator ) { myCreator = theCreator; } static bool CanBeArgOfMethod(const _AString& theMethodName); DEFINE_STANDARD_RTTI (_pySubMesh) }; // ------------------------------------------------------------------------------------- /*! * \brief A filter sets a human readable name to self */ // ------------------------------------------------------------------------------------- class _pyFilter: public _pyObject { _pyID myNewID, myMesh; std::list< Handle(_pyObject) > myUsers; public: _pyFilter(const Handle(_pyCommand)& theCreationCmd, const _pyID& newID=""); void AddUser( const Handle(_pyObject)& user) { myUsers.push_back( user ); } virtual void Process( const Handle(_pyCommand)& theCommand); virtual void Flush(); virtual bool CanClear(); virtual void Free() { myUsers.clear(); } const _pyID& GetNewID() const { return myNewID; } DEFINE_STANDARD_RTTI (_pyFilter) }; DEFINE_STANDARD_HANDLE (_pyFilter, _pyObject); // ------------------------------------------------------------------------------------- /*! * \brief To convert creation of a group by filter */ // ------------------------------------------------------------------------------------- class _pyGroup: public _pySubMesh { Handle(_pyFilter) myFilter; bool myCanClearCreationCmd; public: _pyGroup(const Handle(_pyCommand)& theCreationCmd, const _pyID & id=_pyID()); virtual void Process( const Handle(_pyCommand)& theCommand); virtual void Flush(); virtual void Free() { myFilter.Nullify(); } DEFINE_STANDARD_RTTI (_pyGroup) }; // ------------------------------------------------------------------------------------- /*! * \brief Class reading _pyHypothesis'es from resource files of mesher Plugins */ // ------------------------------------------------------------------------------------- class _pyHypothesisReader: public Standard_Transient { std::map<_AString, Handle(_pyHypothesis)> myType2Hyp; public: _pyHypothesisReader(); Handle(_pyHypothesis) GetHypothesis(const _AString& hypType, const Handle(_pyCommand)& creationCmd) const; DEFINE_STANDARD_RTTI (_pyHypothesisReader) }; #endif