IMPLEMENT_STANDARD_RTTIEXT(_pyComplexParamHypo,_pyHypothesis);
IMPLEMENT_STANDARD_RTTIEXT(_pyNumberOfSegmentsHyp,_pyHypothesis);
IMPLEMENT_STANDARD_RTTIEXT(_pyLayerDistributionHypo,_pyHypothesis);
+IMPLEMENT_STANDARD_RTTIEXT(_pySegmentLengthAroundVertexHyp,_pyHypothesis);
using namespace std;
using SMESH::TPythonDump;
AddMeshAccessorMethod( aCommand );
// Add access to a wrapped algorithm
- AddAlgoAccessorMethod( aCommand );
+ AddAlgoAccessorMethod( aCommand ); // ??? what if algo won't be wrapped at all ???
// PAL12227. PythonDump was not updated at proper time; result is
// aCriteria.append(SMESH.Filter.Criterion(17,26,0,'L1',26,25,1e-07,SMESH.EDGE,-1))
//================================================================================
/*!
- * \brief Add access method to mesh that is object or arg
+ * \brief Add access method to mesh that is an object or an argument
* \param theCmd - command to add access method
* \retval bool - true if added
*/
//================================================================================
/*!
- * \brief Add access method to algo that is object or arg
+ * \brief Add access method to algo that is an object or an argument
* \param theCmd - command to add access method
* \retval bool - true if added
*/
{
list< Handle(_pyHypothesis) >::const_iterator hyp = myHypos.begin();
for ( ; hyp != myHypos.end(); ++hyp ) {
- if ( (*hyp)->IsAlgo() &&
+ if ( (*hyp)->IsAlgo() && /*(*hyp)->IsWrapped() &&*/
theCmd->AddAccessorMethod( (*hyp)->GetID(), (*hyp)->AccessorMethod() ))
return true;
}
void _pyGen::SetCommandAfter( Handle(_pyCommand) theCmd, Handle(_pyCommand) theAfterCmd )
{
-// cout << "SET\t" << theCmd->GetString() << endl << "AFTER\t" << theAfterCmd->GetString() << endl << endl;
+#ifdef _DEBUG_
+//cout << "SET\t" << theAfterCmd->GetString() << endl << "BEFORE\t" << theCmd->GetString() << endl<<endl;
+#endif
list< Handle(_pyCommand) >::iterator pos;
pos = find( myCommands.begin(), myCommands.end(), theCmd );
myCommands.erase( pos );
void addErrorTreatmentCmd( Handle(_pyCommand) & addCmd,
const bool isAlgo)
{
+ return; // TO DEBUD - TreatHypoStatus() is not placed right after addCmd
// addCmd: status = mesh.AddHypothesis( geom, hypo )
// treatement command:
// def TreatHypoStatus(status, hypName, geomName, isAlgo):
SMESH_2smeshpy::SmeshpyName() + ".GetName(" + geomID + "), " +
(char*)( isAlgo ? "True" : "False" ) + " )";
Handle(_pyCommand) cmd = theGen->AddCommand( cmdStr );
- addCmd->AddDependantCmd( cmd );
+ addCmd->AddDependantCmd( cmd, true );
}
}
}
_pyHypothesis::_pyHypothesis(const Handle(_pyCommand)& theCreationCmd):
_pyObject( theCreationCmd )
{
- myDim = myIsAlgo = /*myIsLocal = */myIsWrapped = myIsConverted = false;
+ myIsAlgo = myIsWrapped = /*myIsConverted = myIsLocal = myDim = */false;
}
//================================================================================
// 1D Regular_1D ----------
if ( hypType == "Regular_1D" ) {
- algo->SetDimMethodType( 1, "Segment");
+ // set mesh's method creating algo,
+ // i.e. convertion result will be "regular1d = Mesh.Segment()"
+ algo->SetConvMethodAndType("Segment");
}
else if ( hypType == "LocalLength" ) {
- hyp->SetDimMethodType( 1, "LocalLength", "Regular_1D");
+ // set algo's method creating hyp, and algo type
+ hyp->SetConvMethodAndType( "LocalLength", "Regular_1D");
+ // set method whose 1 arg will become the 1-st arg of hyp creation command
+ // i.e. convertion result will be "locallength = regular1d.LocalLength(<arg of SetLength()>)"
hyp->AddArgMethod( "SetLength" );
}
else if ( hypType == "NumberOfSegments" ) {
hyp = new _pyNumberOfSegmentsHyp( theCreationCmd );
- hyp->SetDimMethodType( 1, "NumberOfSegments", "Regular_1D");
+ hyp->SetConvMethodAndType( "NumberOfSegments", "Regular_1D");
+ // arg of SetNumberOfSegments() will become the 1-st arg of hyp creation command
hyp->AddArgMethod( "SetNumberOfSegments" );
+ // arg of SetScaleFactor() will become the 2-nd arg of hyp creation command
hyp->AddArgMethod( "SetScaleFactor" );
}
else if ( hypType == "Arithmetic1D" ) {
hyp = new _pyComplexParamHypo( theCreationCmd );
- hyp->SetDimMethodType( 1, "Arithmetic1D", "Regular_1D");
+ hyp->SetConvMethodAndType( "Arithmetic1D", "Regular_1D");
}
else if ( hypType == "StartEndLength" ) {
hyp = new _pyComplexParamHypo( theCreationCmd );
- hyp->SetDimMethodType( 1, "StartEndLength", "Regular_1D");
+ hyp->SetConvMethodAndType( "StartEndLength", "Regular_1D");
}
else if ( hypType == "Deflection1D" ) {
- hyp->SetDimMethodType( 1, "Deflection1D", "Regular_1D");
+ hyp->SetConvMethodAndType( "Deflection1D", "Regular_1D");
hyp->AddArgMethod( "SetDeflection" );
}
else if ( hypType == "Propagation" ) {
- hyp->SetDimMethodType( 1, "Propagation", "Regular_1D");
+ hyp->SetConvMethodAndType( "Propagation", "Regular_1D");
}
else if ( hypType == "QuadraticMesh" ) {
- hyp->SetDimMethodType( 1, "QuadraticMesh", "Regular_1D");
+ hyp->SetConvMethodAndType( "QuadraticMesh", "Regular_1D");
}
else if ( hypType == "AutomaticLength" ) {
- hyp->SetDimMethodType( 1, "AutomaticLength", "Regular_1D");
+ hyp->SetConvMethodAndType( "AutomaticLength", "Regular_1D");
hyp->AddArgMethod( "SetFineness");
}
+ else if ( hypType == "SegmentLengthAroundVertex" ) {
+ hyp = new _pySegmentLengthAroundVertexHyp( theCreationCmd );
+ hyp->SetConvMethodAndType( "LengthNearVertex", "Regular_1D" );
+ hyp->AddArgMethod( "SetLength" );
+ }
// 1D Python_1D ----------
else if ( hypType == "Python_1D" ) {
- algo->SetDimMethodType( 1, "Segment");
+ algo->SetConvMethodAndType( "Segment");
algo->myArgs.Append( "algo=smesh.PYTHON");
}
else if ( hypType == "PythonSplit1D" ) {
- hyp->SetDimMethodType( 1, "PythonSplit1D", "Python_1D");
+ hyp->SetConvMethodAndType( "PythonSplit1D", "Python_1D");
hyp->AddArgMethod( "SetNumberOfSegments");
hyp->AddArgMethod( "SetPythonLog10RatioFunction");
}
// 2D ----------
else if ( hypType == "MEFISTO_2D" ) {
- algo->SetDimMethodType( 2, "Triangle");
+ algo->SetConvMethodAndType( "Triangle");
}
else if ( hypType == "MaxElementArea" ) {
- hyp->SetDimMethodType( 2, "MaxElementArea", "MEFISTO_2D");
+ hyp->SetConvMethodAndType( "MaxElementArea", "MEFISTO_2D");
hyp->AddArgMethod( "SetMaxElementArea");
}
else if ( hypType == "LengthFromEdges" ) {
- hyp->SetDimMethodType( 2, "LengthFromEdges", "MEFISTO_2D");
+ hyp->SetConvMethodAndType( "LengthFromEdges", "MEFISTO_2D");
}
else if ( hypType == "Quadrangle_2D" ) {
- algo->SetDimMethodType( 2, "Quadrangle" );
+ algo->SetConvMethodAndType( "Quadrangle" );
}
else if ( hypType == "QuadranglePreference" ) {
- hyp->SetDimMethodType( 2, "QuadranglePreference", "Quadrangle_2D");
+ hyp->SetConvMethodAndType( "QuadranglePreference", "Quadrangle_2D");
}
// 3D ----------
else if ( hypType == "NETGEN_3D") {
- algo->SetDimMethodType( 3, "Tetrahedron" );
+ algo->SetConvMethodAndType( "Tetrahedron" );
algo->myArgs.Append( "algo=smesh.NETGEN" );
}
else if ( hypType == "MaxElementVolume") {
- hyp->SetDimMethodType( 3, "MaxElementVolume", "NETGEN_3D");
+ hyp->SetConvMethodAndType( "MaxElementVolume", "NETGEN_3D");
hyp->AddArgMethod( "SetMaxElementVolume" );
}
else if ( hypType == "GHS3D_3D" ) {
- algo->SetDimMethodType( 3, "Tetrahedron");
+ algo->SetConvMethodAndType( "Tetrahedron");
algo->myArgs.Append( "algo=smesh.GHS3D" );
}
else if ( hypType == "Hexa_3D" ) {
- algo->SetDimMethodType( 3, "Hexahedron");
+ algo->SetConvMethodAndType( "Hexahedron");
}
// Repetitive ---------
else if ( hypType == "Projection_1D" ) {
- algo->SetDimMethodType( 1, "Projection1D");
+ algo->SetConvMethodAndType( "Projection1D");
}
else if ( hypType == "ProjectionSource1D" ) {
- hyp->SetDimMethodType( 1, "SourceEdge", "Projection_1D");
+ hyp->SetConvMethodAndType( "SourceEdge", "Projection_1D");
hyp->AddArgMethod( "SetSourceEdge");
hyp->AddArgMethod( "SetSourceMesh");
+ // 2 args of SetVertexAssociation() will become the 3-th and 4-th args of hyp creation command
hyp->AddArgMethod( "SetVertexAssociation", 2 );
}
else if ( hypType == "Projection_2D" ) {
- algo->SetDimMethodType( 2, "Projection2D");
+ algo->SetConvMethodAndType( "Projection2D");
}
else if ( hypType == "ProjectionSource2D" ) {
- hyp->SetDimMethodType( 2, "SourceFace", "Projection_2D");
+ hyp->SetConvMethodAndType( "SourceFace", "Projection_2D");
hyp->AddArgMethod( "SetSourceFace");
hyp->AddArgMethod( "SetSourceMesh");
hyp->AddArgMethod( "SetVertexAssociation", 4 );
}
else if ( hypType == "Projection_3D" ) {
- algo->SetDimMethodType( 3, "Projection3D");
+ algo->SetConvMethodAndType( "Projection3D");
}
else if ( hypType == "ProjectionSource3D" ) {
- hyp->SetDimMethodType( 3, "SourceShape3D", "Projection_3D");
+ hyp->SetConvMethodAndType( "SourceShape3D", "Projection_3D");
hyp->AddArgMethod( "SetSource3DShape");
hyp->AddArgMethod( "SetSourceMesh");
hyp->AddArgMethod( "SetVertexAssociation", 4 );
}
else if ( hypType == "Prism_3D" ) {
- algo->SetDimMethodType( 3, "Prism");
+ algo->SetConvMethodAndType( "Prism");
}
else if ( hypType == "RadialPrism_3D" ) {
- algo->SetDimMethodType( 3, "Prism");
+ algo->SetConvMethodAndType( "Prism");
}
else if ( hypType == "NumberOfLayers" ) {
- hyp->SetDimMethodType( 3, "NumberOfLayers", "RadialPrism_3D");
+ hyp->SetConvMethodAndType( "NumberOfLayers", "RadialPrism_3D");
hyp->AddArgMethod( "SetNumberOfLayers" );
}
else if ( hypType == "LayerDistribution" ) {
hyp = new _pyLayerDistributionHypo( theCreationCmd );
- hyp->SetDimMethodType( 3, "LayerDistribution", "RadialPrism_3D");
-// hyp->AddArgMethod( "SetSource3DShape");
-// hyp->AddArgMethod( "SetSourceMesh");
-// hyp->AddArgMethod( "SetVertexAssociation", 4 );
+ hyp->SetConvMethodAndType( "LayerDistribution", "RadialPrism_3D");
}
- if ( algo->GetDim() ) {
+ if ( !algo->GetCreationMethod().IsEmpty() ) {
algo->myType = hypType;
return algo;
}
}
}
+//================================================================================
+/*!
+ * \brief Convert the command adding "SegmentLengthAroundVertex" to mesh
+ * into regular1D.LengthNearVertex( length, vertex )
+ * \param theCmd - The command like mesh.AddHypothesis( vertex, SegmentLengthAroundVertex )
+ * \param theMesh - The mesh needing this hypo
+ * \retval bool - false if the command cant be converted
+ */
+//================================================================================
+
+bool _pySegmentLengthAroundVertexHyp::Addition2Creation( const Handle(_pyCommand)& theCmd,
+ const _pyID& theMeshID)
+{
+ if ( IsWrappable( theMeshID )) {
+
+ _pyID vertex = theCmd->GetArg( 1 );
+
+ // mesh.AddHypothesis(vertex, SegmentLengthAroundVertex) --> theMeshID.LengthNearVertex( length )
+ if ( _pyHypothesis::Addition2Creation( theCmd, theMeshID )) {
+ // set 2-nd arg
+ theCmd->SetArg( 2, vertex );
+ return true;
+ }
+ }
+ return false;
+}
+
//================================================================================
/*!
* \brief _pyAlgorithm constructor
int afterEnd = beg + theObjectID.Length();
Standard_Character c = myString.Value( afterEnd );
if ( !isalnum( c ) && c != ':' ) {
- // insertion
- int oldLen = Length();
- myString.Insert( afterEnd, (char*) theAcsMethod );
- myString.Insert( afterEnd, "." );
- // update starting positions of the parts following the modified one
- int posDelta = Length() - oldLen;
- for ( int i = 1; i <= myBegPos.Length(); ++i ) {
- if ( myBegPos( i ) > afterEnd )
- myBegPos( i ) += posDelta;
+ // check if accessor method already present
+ if ( c != '.' ||
+ myString.Location( (char*) theAcsMethod, afterEnd, Length() ) != afterEnd+1) {
+ // insertion
+ int oldLen = Length();
+ myString.Insert( afterEnd, (char*) theAcsMethod );
+ myString.Insert( afterEnd, "." );
+ // update starting positions of the parts following the modified one
+ int posDelta = Length() - oldLen;
+ for ( int i = 1; i <= myBegPos.Length(); ++i ) {
+ if ( myBegPos( i ) > afterEnd )
+ myBegPos( i ) += posDelta;
+ }
+ return true;
}
- return true;
}
beg = afterEnd; // is a part - next search
}
static TCollection_AsciiString GetWord( const TCollection_AsciiString & theSring,
int & theStartPos, const bool theForward,
const bool dotIsWord = false);
- void AddDependantCmd( Handle(_pyCommand) cmd)
- { return myDependentCmds.push_back( cmd ); }
+ 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 );
class _pyHypothesis: public _pyObject
{
protected:
- bool myIsAlgo, /*myIsLocal, */myIsWrapped, myIsConverted;
- int myDim/*, myAdditionCmdNb*/;
+ bool myIsAlgo, myIsWrapped; //myIsLocal, myIsConverted;
+ //int myDim/*, myAdditionCmdNb*/;
_pyID myGeom, myMesh;
TCollection_AsciiString myCreationMethod, myType;
TColStd_SequenceOfAsciiString myArgs;
std::list<Handle(_pyCommand)> myUnknownCommands;
public:
_pyHypothesis(const Handle(_pyCommand)& theCreationCmd);
- 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=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 AddArgMethod(const char* method, const int nbArgs = 1)
{ myArgMethods.Append( (char*)method ); myNbArgsByMethod.Append( nbArgs ); }
const TColStd_SequenceOfAsciiString& GetArgs() const { return myArgs; }
void ClearAllCommands();
virtual bool IsAlgo() const { return myIsAlgo; }
bool IsWrapped() const { return myIsWrapped; }
- bool & IsConverted() { return myIsConverted; }
- int GetDim() const { return myDim; }
+ //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; }
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);
+ const char* AccessorMethod() const { return "GetAlgorithm()"; }
+
+ DEFINE_STANDARD_RTTI (_pyAlgorithm)
+};
+
// -------------------------------------------------------------------------------------
/*!
* \brief Class for hypotheses having several parameters modified by one method
};
DEFINE_STANDARD_HANDLE (_pyLayerDistributionHypo, _pyHypothesis);
-
// -------------------------------------------------------------------------------------
/*!
* \brief Class representing NumberOfSegments hypothesis
// -------------------------------------------------------------------------------------
/*!
- * \brief Class representing smesh.Mesh_Algorithm
+ * \brief Class representing SegmentLengthAroundVertex hypothesis
*/
// -------------------------------------------------------------------------------------
-class _pyAlgorithm: public _pyHypothesis
+class _pySegmentLengthAroundVertexHyp: public _pyHypothesis
{
public:
- _pyAlgorithm(const Handle(_pyCommand)& theCreationCmd);
+ _pySegmentLengthAroundVertexHyp(const Handle(_pyCommand)& theCrCmd): _pyHypothesis(theCrCmd) {}
virtual bool Addition2Creation( const Handle(_pyCommand)& theAdditionCmd,
const _pyID& theMesh);
- const char* AccessorMethod() const { return "GetAlgorithm()"; }
-
- DEFINE_STANDARD_RTTI (_pyAlgorithm)
+ DEFINE_STANDARD_RTTI (_pySegmentLengthAroundVertexHyp)
};
+DEFINE_STANDARD_HANDLE (_pySegmentLengthAroundVertexHyp, _pyHypothesis);
#endif
