// ===========================================================================================
/*!
- * \brief Tool converting SMESH engine calls into commands defined in smesh.py
- *
* 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 SMESH IDL interfaces.
+ * classes differ from ones between corresponding SMESH IDL interfaces.
*
- * The only API method here is SMESH_2smeshpy::ConvertScript(), the rest ones are
- * for internal usage
+ * Everything here is for internal usage by SMESH_2smeshpy::ConvertScript()
+ * declared in SMESH_PythonDump.hxx
*
- * See comments to _pyHypothesis class to know how to assure convertion of a new hypothesis
+ * See comments to _pyHypothesis class to know how to assure convertion of a new
+ * type of hypothesis
*/
// ===========================================================================================
class Resource_DataMapOfAsciiStringAsciiString;
-class SMESH_2smeshpy
-{
-public:
- /*!
- * \brief Convert a python script using commands of smesh.py
- * \param theScript - Input script
- * \param theEntry2AccessorMethod - The returning method names to access to
- * objects wrapped with python class
- * \retval TCollection_AsciiString - Convertion result
- */
- static TCollection_AsciiString
- ConvertScript(const TCollection_AsciiString& theScript,
- Resource_DataMapOfAsciiStringAsciiString& theEntry2AccessorMethod);
-
- /*!
- * \brief Return the name of the python file wrapping IDL API
- * \retval TCollection_AsciiString - The file name
- */
- static char* SmeshpyName() { return "smesh"; }
- static char* GenName() { return "smesh.smesh"; }
-};
-
// ===========================================================================================
// =====================
// INTERNAL STUFF
DEFINE_STANDARD_HANDLE (_pyObject ,Standard_Transient);
DEFINE_STANDARD_HANDLE (_pyGen ,_pyObject);
DEFINE_STANDARD_HANDLE (_pyMesh ,_pyObject);
+DEFINE_STANDARD_HANDLE (_pyMeshEditor,_pyObject);
DEFINE_STANDARD_HANDLE (_pyHypothesis,_pyObject);
DEFINE_STANDARD_HANDLE (_pyAlgorithm ,_pyHypothesis);
bool IsEmpty() const { return myString.IsEmpty(); }
TCollection_AsciiString GetIndentation();
const TCollection_AsciiString & GetResultValue();
+ const int GetNbResultValues();
+ const TCollection_AsciiString & GetResultValue(int res);
const TCollection_AsciiString & GetObject();
const TCollection_AsciiString & GetMethod();
const TCollection_AsciiString & GetArg( int index );
void Flush();
Handle(_pyHypothesis) FindHyp( const _pyID& theHypID );
Handle(_pyHypothesis) FindAlgo( const _pyID& theGeom, const _pyID& theMesh,
- const TCollection_AsciiString& theAlgoType);
+ const Handle(_pyHypothesis)& theHypothesis);
void ExchangeCommands( Handle(_pyCommand) theCmd1, Handle(_pyCommand) theCmd2 );
void SetCommandAfter( Handle(_pyCommand) theCmd, Handle(_pyCommand) theAfterCmd );
std::list< Handle(_pyCommand) >& GetCommands() { return myCommands; }
void SetAccessorMethod(const _pyID& theID, const char* theMethod );
bool AddMeshAccessorMethod( Handle(_pyCommand) theCmd ) const;
bool AddAlgoAccessorMethod( Handle(_pyCommand) theCmd ) const;
- const char* AccessorMethod() const { return SMESH_2smeshpy::GenName(); }
+ const char* AccessorMethod() const;
private:
- std::map< _pyID, Handle(_pyMesh) > myMeshes;
- std::list< Handle(_pyHypothesis) > myHypos;
- std::list< Handle(_pyCommand) > myCommands;
- int myNbCommands;
- bool myHasPattern;
+ std::map< _pyID, Handle(_pyMesh) > myMeshes;
+ std::map< _pyID, Handle(_pyMeshEditor) > myMeshEditors;
+ std::list< Handle(_pyHypothesis) > myHypos;
+ std::list< Handle(_pyCommand) > myCommands;
+ int myNbCommands;
+ bool myHasPattern;
Resource_DataMapOfAsciiStringAsciiString& myID2AccessorMethod;
DEFINE_STANDARD_RTTI (_pyGen)
bool myHasEditor;
public:
_pyMesh(const Handle(_pyCommand) theCreationCmd);
+ _pyMesh(const Handle(_pyCommand) theCreationCmd, const TCollection_AsciiString &);
const _pyID& GetGeom() { return GetCreationCmd()->GetArg(1); }
void Process( const Handle(_pyCommand)& theCommand);
void Flush();
const char* AccessorMethod() const { return _pyMesh_ACCESS_METHOD; }
private:
+ static bool NeedMeshAccess( const Handle(_pyCommand)& theCommand );
static void AddMeshAccess( const Handle(_pyCommand)& theCommand )
{ theCommand->SetObject( theCommand->GetObject() + "." _pyMesh_ACCESS_METHOD ); }
+ //friend class _pyMeshEditor;
DEFINE_STANDARD_RTTI (_pyMesh)
};
#undef _pyMesh_ACCESS_METHOD
+// -------------------------------------------------------------------------------------
+/*!
+ * \brief MeshEditor convert its commands to ones of mesh
+ */
+// -------------------------------------------------------------------------------------
+class _pyMeshEditor: public _pyObject
+{
+ _pyID myMesh;
+ TCollection_AsciiString myCreationCmdStr;
+public:
+ _pyMeshEditor(const Handle(_pyCommand)& theCreationCmd);
+ void Process( const Handle(_pyCommand)& theCommand);
+ virtual void Flush() {}
+
+ DEFINE_STANDARD_RTTI (_pyMesh)
+};
+
// -------------------------------------------------------------------------------------
/*!
* \brief Root class for hypothesis
*
- * HOWTO assure convertion of a new hypothesis
- * In NewHypothesis():
- * 1. add a case for the name of the new hypothesis and
- * 2. initialize _pyHypothesis fields:
- * . myDim - hypothesis dimention;
- * . myType - type name of the algorithm creating the hypothesis;
- * . myCreationMethod - method name of the algorithm creating the hypothesis;
- * . append to myArgMethods interface methods setting param values in the
- * order they are used when myCreationMethod is called. It is supposed that
- * each interface method sets only one parameter, if it is not so, you are
+ * HOWTO assure convertion of a new type of hypothesis
+ * In _pyHypothesis::NewHypothesis():
+ * 1. add a case for the name of the new hypothesis
+ * 2. use SetConvMethodAndType() to set
+ * . for algo: algorithm name and method of Mesh creating the algo
+ * . for hypo: name of the algorithm and method creating the hypothesis
+ * 3. append to myArgMethods interface methods setting param values in the
+ * order they are used when creation method is called. If arguments of
+ * the creation method can't be easily got from calls of hypothesis methods, you are
* to derive a specific class from _pyHypothesis that would redefine Process(),
* see _pyComplexParamHypo for example
*/
class _pyHypothesis: public _pyObject
{
protected:
- bool myIsAlgo, myIsWrapped; //myIsLocal, myIsConverted;
- //int myDim/*, myAdditionCmdNb*/;
- _pyID myGeom, myMesh;
- TCollection_AsciiString myCreationMethod, myType;
- TColStd_SequenceOfAsciiString myArgs;
- TColStd_SequenceOfAsciiString myArgMethods;
- TColStd_SequenceOfInteger myNbArgsByMethod;
+ bool myIsAlgo, myIsWrapped;
+ _pyID myGeom, myMesh;
+ // a hypothesis can be used and created by different algos by different methods
+ std::map<TCollection_AsciiString, TCollection_AsciiString > myType2CreationMethod;
+ //TCollection_AsciiString myCreationMethod, myType;
+ TColStd_SequenceOfAsciiString myArgs; // creation arguments
+ TColStd_SequenceOfAsciiString myArgMethods; // hypo methods setting myArgs
+ TColStd_SequenceOfInteger myNbArgsByMethod; // nb args set by each method
std::list<Handle(_pyCommand)> myArgCommands;
std::list<Handle(_pyCommand)> myUnknownCommands;
public:
_pyHypothesis(const Handle(_pyCommand)& theCreationCmd);
- void SetConvMethodAndType(const char* creationMethod, const char* type=0)
- { myCreationMethod = (char*)creationMethod; if ( type ) myType = (char*)type; }
-// void SetDimMethodType(const int dim, const char* creationMethod, const char* type=0)
-// { myDim = dim; myCreationMethod = (char*)creationMethod; if ( type ) myType = (char*)type; }
+ void SetConvMethodAndType(const char* creationMethod, const char* type)
+ { myType2CreationMethod[ (char*)type ] = (char*)creationMethod; }
void AddArgMethod(const char* method, const int nbArgs = 1)
{ myArgMethods.Append( (char*)method ); myNbArgsByMethod.Append( nbArgs ); }
const TColStd_SequenceOfAsciiString& GetArgs() const { return myArgs; }
- const TCollection_AsciiString& GetCreationMethod() const { return myCreationMethod; }
const std::list<Handle(_pyCommand)>& GetArgCommands() const { return myArgCommands; }
void ClearAllCommands();
virtual bool IsAlgo() const { return myIsAlgo; }
+ bool IsValid() const { return !myType2CreationMethod.empty(); }
bool IsWrapped() const { return myIsWrapped; }
- //bool & IsConverted() { return myIsConverted; }
- //int GetDim() const { return myDim; }
const _pyID & GetGeom() const { return myGeom; }
void SetMesh( const _pyID& theMeshId) { if ( myMesh.IsEmpty() ) myMesh = theMeshId; }
const _pyID & GetMesh() const { return myMesh; }
- const TCollection_AsciiString GetType() { return myType; }
+ const TCollection_AsciiString& GetAlgoType() const
+ { return myType2CreationMethod.begin()->first; }
+ const TCollection_AsciiString& GetAlgoCreationMethod() const
+ { return myType2CreationMethod.begin()->second; }
+ bool CanBeCreatedBy(const TCollection_AsciiString& algoType ) const
+ { return myType2CreationMethod.find( algoType ) != myType2CreationMethod.end(); }
+ const TCollection_AsciiString& GetCreationMethod(const TCollection_AsciiString& algoType) const
+ { return myType2CreationMethod.find( algoType )->second; }
bool IsWrappable(const _pyID& theMesh) { return !myIsWrapped && myMesh == theMesh; }
virtual bool Addition2Creation( const Handle(_pyCommand)& theAdditionCmd,
const _pyID& theMesh);
static Handle(_pyHypothesis) NewHypothesis( const Handle(_pyCommand)& theCreationCmd);
- // bool HasMesh() const { return !myMesh.IsEmpty(); }
- // void SetGeom( const _pyID& theGeomID ) { myGeom = theGeomID; }
void Process( const Handle(_pyCommand)& theCommand);
void Flush();