-// Copyright (C) 2007-2013 CEA/DEN, EDF R&D
+// Copyright (C) 2007-2015 CEA/DEN, EDF R&D
//
// 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.
+// version 2.1 of the License, or (at your option) any later version.
//
// This library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
#include <SMESH_MesherHelper.hxx>
#include <StdMeshers_FaceSide.hxx>
#include <StdMeshers_ViscousLayers2D.hxx>
+#include <SMESH_File.hxx>
#include <utilities.h>
#include <gp_XY.hxx>
#include <gp_XYZ.hxx>
-#ifndef WNT
+#ifndef WIN32
#include <fenv.h>
#endif
* =========== PYTHON ==============
* ==================================*/
-typedef struct {
- PyObject_HEAD
- int softspace;
- std::string *out;
- } PyStdOut;
-
-static void
-PyStdOut_dealloc(PyStdOut *self)
+namespace
{
- PyObject_Del(self);
-}
+ typedef struct {
+ PyObject_HEAD
+ int softspace;
+ std::string *out;
+ } PyStdOut;
+
+ static void
+ PyStdOut_dealloc(PyStdOut *self)
+ {
+ PyObject_Del(self);
+ }
-static PyObject *
-PyStdOut_write(PyStdOut *self, PyObject *args)
-{
- char *c;
- int l;
- if (!PyArg_ParseTuple(args, "t#:write",&c, &l))
- return NULL;
+ static PyObject *
+ PyStdOut_write(PyStdOut *self, PyObject *args)
+ {
+ char *c;
+ int l;
+ if (!PyArg_ParseTuple(args, "t#:write",&c, &l))
+ return NULL;
- //std::cerr << c ;
- *(self->out)=*(self->out)+c;
+ *(self->out)=*(self->out)+c;
- Py_INCREF(Py_None);
- return Py_None;
-}
+ Py_INCREF(Py_None);
+ return Py_None;
+ }
-static PyMethodDef PyStdOut_methods[] = {
- {"write", (PyCFunction)PyStdOut_write, METH_VARARGS,
- PyDoc_STR("write(string) -> None")},
- {NULL, NULL} /* sentinel */
-};
-
-static PyMemberDef PyStdOut_memberlist[] = {
- {(char*)"softspace", T_INT, offsetof(PyStdOut, softspace), 0,
- (char*)"flag indicating that a space needs to be printed; used by print"},
- {NULL} /* Sentinel */
-};
-
-static PyTypeObject PyStdOut_Type = {
- /* The ob_type field must be initialized in the module init function
- * to be portable to Windows without using C++. */
- PyObject_HEAD_INIT(NULL)
- 0, /*ob_size*/
- "PyOut", /*tp_name*/
- sizeof(PyStdOut), /*tp_basicsize*/
- 0, /*tp_itemsize*/
- /* methods */
- (destructor)PyStdOut_dealloc, /*tp_dealloc*/
- 0, /*tp_print*/
- 0, /*tp_getattr*/
- 0, /*tp_setattr*/
- 0, /*tp_compare*/
- 0, /*tp_repr*/
- 0, /*tp_as_number*/
- 0, /*tp_as_sequence*/
- 0, /*tp_as_mapping*/
- 0, /*tp_hash*/
- 0, /*tp_call*/
- 0, /*tp_str*/
- PyObject_GenericGetAttr, /*tp_getattro*/
- /* softspace is writable: we must supply tp_setattro */
- PyObject_GenericSetAttr, /* tp_setattro */
- 0, /*tp_as_buffer*/
- Py_TPFLAGS_DEFAULT, /*tp_flags*/
- 0, /*tp_doc*/
- 0, /*tp_traverse*/
- 0, /*tp_clear*/
- 0, /*tp_richcompare*/
- 0, /*tp_weaklistoffset*/
- 0, /*tp_iter*/
- 0, /*tp_iternext*/
- PyStdOut_methods, /*tp_methods*/
- PyStdOut_memberlist, /*tp_members*/
- 0, /*tp_getset*/
- 0, /*tp_base*/
- 0, /*tp_dict*/
- 0, /*tp_descr_get*/
- 0, /*tp_descr_set*/
- 0, /*tp_dictoffset*/
- 0, /*tp_init*/
- 0, /*tp_alloc*/
- 0, /*tp_new*/
- 0, /*tp_free*/
- 0, /*tp_is_gc*/
-};
-
-PyObject * newPyStdOut( std::string& out )
-{
- PyStdOut *self;
- self = PyObject_New(PyStdOut, &PyStdOut_Type);
- if (self == NULL)
- return NULL;
- self->softspace = 0;
- self->out=&out;
- return (PyObject*)self;
+ static PyMethodDef PyStdOut_methods[] = {
+ {"write", (PyCFunction)PyStdOut_write, METH_VARARGS,
+ PyDoc_STR("write(string) -> None")},
+ {NULL, NULL} /* sentinel */
+ };
+
+ static PyMemberDef PyStdOut_memberlist[] = {
+ {(char*)"softspace", T_INT, offsetof(PyStdOut, softspace), 0,
+ (char*)"flag indicating that a space needs to be printed; used by print"},
+ {NULL} /* Sentinel */
+ };
+
+ static PyTypeObject PyStdOut_Type = {
+ /* The ob_type field must be initialized in the module init function
+ * to be portable to Windows without using C++. */
+ PyObject_HEAD_INIT(NULL)
+ 0, /*ob_size*/
+ "PyOut", /*tp_name*/
+ sizeof(PyStdOut), /*tp_basicsize*/
+ 0, /*tp_itemsize*/
+ /* methods */
+ (destructor)PyStdOut_dealloc, /*tp_dealloc*/
+ 0, /*tp_print*/
+ 0, /*tp_getattr*/
+ 0, /*tp_setattr*/
+ 0, /*tp_compare*/
+ 0, /*tp_repr*/
+ 0, /*tp_as_number*/
+ 0, /*tp_as_sequence*/
+ 0, /*tp_as_mapping*/
+ 0, /*tp_hash*/
+ 0, /*tp_call*/
+ 0, /*tp_str*/
+ PyObject_GenericGetAttr, /*tp_getattro*/
+ /* softspace is writable: we must supply tp_setattro */
+ PyObject_GenericSetAttr, /* tp_setattro */
+ 0, /*tp_as_buffer*/
+ Py_TPFLAGS_DEFAULT, /*tp_flags*/
+ 0, /*tp_doc*/
+ 0, /*tp_traverse*/
+ 0, /*tp_clear*/
+ 0, /*tp_richcompare*/
+ 0, /*tp_weaklistoffset*/
+ 0, /*tp_iter*/
+ 0, /*tp_iternext*/
+ PyStdOut_methods, /*tp_methods*/
+ PyStdOut_memberlist, /*tp_members*/
+ 0, /*tp_getset*/
+ 0, /*tp_base*/
+ 0, /*tp_dict*/
+ 0, /*tp_descr_get*/
+ 0, /*tp_descr_set*/
+ 0, /*tp_dictoffset*/
+ 0, /*tp_init*/
+ 0, /*tp_alloc*/
+ 0, /*tp_new*/
+ 0, /*tp_free*/
+ 0, /*tp_is_gc*/
+ };
+
+ PyObject * newPyStdOut( std::string& out )
+ {
+ PyStdOut* self = PyObject_New(PyStdOut, &PyStdOut_Type);
+ if (self) {
+ self->softspace = 0;
+ self->out=&out;
+ }
+ return (PyObject*)self;
+ }
}
////////////////////////END PYTHON///////////////////////////
//////////////////MY MAPS////////////////////////////////////////
+namespace {
TopTools_IndexedMapOfShape FacesWithSizeMap;
std::map<int,string> FaceId2SizeMap;
TopTools_IndexedMapOfShape EdgesWithSizeMap;
std::map<int,PyObject*> EdgeId2PythonSmp;
std::map<int,PyObject*> VertexId2PythonSmp;
+typedef std::map<int, std::vector< BLSURFPlugin_Attractor* > > TId2ClsAttractorVec;
+TId2ClsAttractorVec FaceId2ClassAttractor;
+TId2ClsAttractorVec FaceIndex2ClassAttractor;
std::map<int,std::vector<double> > FaceId2AttractorCoords;
-std::map<int,BLSURFPlugin_Attractor*> FaceId2ClassAttractor;
-std::map<int,BLSURFPlugin_Attractor*> FaceIndex2ClassAttractor;
+int theNbAttractors;
TopTools_IndexedMapOfShape FacesWithEnforcedVertices;
std::map< int, BLSURFPlugin_Hypothesis::TEnfVertexCoordsList > FaceId2EnforcedVertexCoords;
bool HasSizeMapOnEdge=false;
bool HasSizeMapOnVertex=false;
//bool HasAttractorOnFace=false;
-
+}
//=============================================================================
/*!
*
{
MESSAGE("BLSURFPlugin_BLSURF::BLSURFPlugin_BLSURF");
- _name = "BLSURF";
+ _name = "MG-CADSurf";//"BLSURF";
_shapeType = (1 << TopAbs_FACE); // 1 bit /shape type
_compatibleHypothesis.push_back(BLSURFPlugin_Hypothesis::GetHypType());
_compatibleHypothesis.push_back(StdMeshers_ViscousLayers2D::GetHypType());
myStudy = NULL;
myStudy = aStudyMgr->GetStudyByID(_studyId);
- if (myStudy)
+ if ( !myStudy->_is_nil() )
MESSAGE("myStudy->StudyId() = " << myStudy->StudyId());
/* Initialize the Python interpreter */
EnfVertexCoords2ProjVertex.clear();
EnfVertexCoords2EnfVertexList.clear();
-#ifdef WITH_SMESH_CANCEL_COMPUTE
_compute_canceled = false;
-#endif
}
//=============================================================================
return true; // can work with no hypothesis
}
- for ( itl = hyps.begin(); itl != hyps.end(); ++itl )
+ for ( itl = hyps.begin(); itl != hyps.end() && ( aStatus == HYP_OK ); ++itl )
{
theHyp = *itl;
string hypName = theHyp->GetName();
}
else if ( hypName == StdMeshers_ViscousLayers2D::GetHypType() )
{
- _haveViscousLayers = true;
+ if ( !_haveViscousLayers )
+ {
+ if ( error( StdMeshers_ViscousLayers2D::CheckHypothesis( aMesh, aShape, aStatus )))
+ _haveViscousLayers = true;
+ }
}
else
{
//=============================================================================
/*!
- * Pass parameters to BLSURF
+ * Pass parameters to MG-CADSurf
*/
//=============================================================================
-inline std::string to_string(double d)
+inline std::string val_to_string(double d)
{
std::ostringstream o;
o << d;
return o.str();
}
-inline std::string to_string_rel(double d)
+inline std::string val_to_string_rel(double d)
{
std::ostringstream o;
o << d;
return o.str();
}
-inline std::string to_string(int i)
+inline std::string val_to_string(int i)
{
std::ostringstream o;
o << i;
return o.str();
}
-inline std::string to_string_rel(int i)
+inline std::string val_to_string_rel(int i)
{
std::ostringstream o;
o << i;
}
double _smp_phy_size;
-// #if BLSURF_VERSION_LONG >= "3.1.1"
-// // sizemap_t *geo_sizemap_e, *geo_sizemap_f;
-// sizemap_t *iso_sizemap_p, *iso_sizemap_e, *iso_sizemap_f;
-// // sizemap_t *clean_geo_sizemap_e, *clean_geo_sizemap_f;
-// sizemap_t *clean_iso_sizemap_p, *clean_iso_sizemap_e, *clean_iso_sizemap_f;
-// #endif
status_t size_on_surface(integer face_id, real *uv, real *size, void *user_data);
status_t size_on_edge(integer edge_id, real t, real *size, void *user_data);
status_t size_on_vertex(integer vertex_id, real *size, void *user_data);
// MESSAGE("point OK");
}
+// One sub-shape to get ids from
+BLSURFPlugin_BLSURF::TListOfIDs _getSubShapeIDsInMainShape(TopoDS_Shape theMainShape, TopoDS_Shape theSubShape,
+ TopAbs_ShapeEnum theShapeType)
+{
+ BLSURFPlugin_BLSURF::TListOfIDs face_ids;
+ TopTools_IndexedMapOfShape anIndices;
+ anIndices.Clear();
+ TopExp::MapShapes(theMainShape, theShapeType, anIndices);
+
+// Standard_Boolean result = BRepTools::Write(theMainShape,"main_shape.brep");
+
+ for (TopExp_Explorer face_iter(theSubShape,theShapeType);face_iter.More();face_iter.Next())
+ {
+ int face_id = anIndices.FindIndex(face_iter.Current());
+ if (face_id == 0)
+ throw SALOME_Exception ( SMESH_Comment("Sub_shape not found in main_shape"));
+ face_ids.push_back(face_id);
+// std::ostringstream o;
+// o << "face_" << face_id << ".brep";
+// std::string face_name = o.str();
+// const TopoDS_Face& face = TopoDS::Face(face_iter.Current());
+// Standard_Boolean result = BRepTools::Write(face,face_name.c_str());
+ }
+
+ return face_ids;
+}
+
+BLSURFPlugin_BLSURF::TListOfIDs _getSubShapeIDsInMainShape(SMESH_Mesh* theMesh,
+ TopoDS_Shape theSubShape,
+ TopAbs_ShapeEnum theShapeType)
+{
+ BLSURFPlugin_BLSURF::TListOfIDs face_ids;
+
+ for (TopExp_Explorer face_iter(theSubShape,theShapeType);face_iter.More();face_iter.Next())
+ {
+ int face_id = theMesh->GetMeshDS()->ShapeToIndex(face_iter.Current());
+ if (face_id == 0)
+ throw SALOME_Exception ( SMESH_Comment("Sub_shape not found in main_shape"));
+ face_ids.push_back(face_id);
+ }
+
+ return face_ids;
+}
+
+void BLSURFPlugin_BLSURF::addCoordsFromVertices(const std::vector<std::string> &theVerticesEntries, std::vector<double> &theVerticesCoords)
+{
+ for (std::vector<std::string>::const_iterator it = theVerticesEntries.begin(); it != theVerticesEntries.end(); it++)
+ {
+ BLSURFPlugin_Hypothesis::TEntry theVertexEntry = *it;
+ MESSAGE("Vertex entry " << theVertexEntry);
+ addCoordsFromVertex(theVertexEntry, theVerticesCoords);
+ }
+}
+
+
+void BLSURFPlugin_BLSURF::addCoordsFromVertex(BLSURFPlugin_Hypothesis::TEntry theVertexEntry, std::vector<double> &theVerticesCoords)
+{
+ if (theVertexEntry!="")
+ {
+ TopoDS_Shape aShape = entryToShape(theVertexEntry);
+
+ gp_Pnt aPnt = BRep_Tool::Pnt( TopoDS::Vertex( aShape ) );
+ double theX, theY, theZ;
+ theX = aPnt.X();
+ theY = aPnt.Y();
+ theZ = aPnt.Z();
+
+ theVerticesCoords.push_back(theX);
+ theVerticesCoords.push_back(theY);
+ theVerticesCoords.push_back(theZ);
+ }
+}
+
/////////////////////////////////////////////////////////
+void BLSURFPlugin_BLSURF::createPreCadFacesPeriodicity(TopoDS_Shape theGeomShape, const BLSURFPlugin_Hypothesis::TPreCadPeriodicity &preCadPeriodicity)
+{
+ MESSAGE("BLSURFPlugin_BLSURF::createFacesPeriodicity");
-void BLSURFPlugin_BLSURF::SetParameters(
-// #if BLSURF_VERSION_LONG >= "3.1.1"
-// cad_t * c,
-// #endif
- const BLSURFPlugin_Hypothesis* hyp,
+ TopoDS_Shape geomShape1 = entryToShape(preCadPeriodicity.shape1Entry);
+ TopoDS_Shape geomShape2 = entryToShape(preCadPeriodicity.shape2Entry);
+
+ TListOfIDs theFace1_ids = _getSubShapeIDsInMainShape(theGeomShape, geomShape1, TopAbs_FACE);
+ TListOfIDs theFace2_ids = _getSubShapeIDsInMainShape(theGeomShape, geomShape2, TopAbs_FACE);
+
+ TPreCadPeriodicityIDs preCadFacesPeriodicityIDs;
+ preCadFacesPeriodicityIDs.shape1IDs = theFace1_ids;
+ preCadFacesPeriodicityIDs.shape2IDs = theFace2_ids;
+
+ MESSAGE("preCadPeriodicity.theSourceVerticesEntries.size(): " << preCadPeriodicity.theSourceVerticesEntries.size());
+ MESSAGE("preCadPeriodicity.theTargetVerticesEntries.size(): " << preCadPeriodicity.theTargetVerticesEntries.size());
+
+ addCoordsFromVertices(preCadPeriodicity.theSourceVerticesEntries, preCadFacesPeriodicityIDs.theSourceVerticesCoords);
+ addCoordsFromVertices(preCadPeriodicity.theTargetVerticesEntries, preCadFacesPeriodicityIDs.theTargetVerticesCoords);
+
+ MESSAGE("preCadFacesPeriodicityIDs.theSourceVerticesCoords.size(): " << preCadFacesPeriodicityIDs.theSourceVerticesCoords.size());
+ MESSAGE("preCadFacesPeriodicityIDs.theTargetVerticesCoords.size(): " << preCadFacesPeriodicityIDs.theTargetVerticesCoords.size());
+
+ _preCadFacesIDsPeriodicityVector.push_back(preCadFacesPeriodicityIDs);
+ MESSAGE("_preCadFacesIDsPeriodicityVector.size() = " << _preCadFacesIDsPeriodicityVector.size());
+ MESSAGE("BLSURFPlugin_BLSURF::createFacesPeriodicity END");
+
+}
+
+/////////////////////////////////////////////////////////
+void BLSURFPlugin_BLSURF::createPreCadEdgesPeriodicity(TopoDS_Shape theGeomShape, const BLSURFPlugin_Hypothesis::TPreCadPeriodicity &preCadPeriodicity)
+{
+ MESSAGE("BLSURFPlugin_BLSURF::createEdgesPeriodicity");
+
+ TopoDS_Shape geomShape1 = entryToShape(preCadPeriodicity.shape1Entry);
+ TopoDS_Shape geomShape2 = entryToShape(preCadPeriodicity.shape2Entry);
+
+ TListOfIDs theEdge1_ids = _getSubShapeIDsInMainShape(theGeomShape, geomShape1, TopAbs_EDGE);
+ TListOfIDs theEdge2_ids = _getSubShapeIDsInMainShape(theGeomShape, geomShape2, TopAbs_EDGE);
+
+ TPreCadPeriodicityIDs preCadEdgesPeriodicityIDs;
+ preCadEdgesPeriodicityIDs.shape1IDs = theEdge1_ids;
+ preCadEdgesPeriodicityIDs.shape2IDs = theEdge2_ids;
+
+ addCoordsFromVertices(preCadPeriodicity.theSourceVerticesEntries, preCadEdgesPeriodicityIDs.theSourceVerticesCoords);
+ addCoordsFromVertices(preCadPeriodicity.theTargetVerticesEntries, preCadEdgesPeriodicityIDs.theTargetVerticesCoords);
+
+ _preCadEdgesIDsPeriodicityVector.push_back(preCadEdgesPeriodicityIDs);
+ MESSAGE("_preCadEdgesIDsPeriodicityVector.size() = " << _preCadEdgesIDsPeriodicityVector.size());
+ MESSAGE("BLSURFPlugin_BLSURF::createEdgesPeriodicity END");
+
+}
+
+/////////////////////////////////////////////////////////
+void BLSURFPlugin_BLSURF::createFacesPeriodicity(TopoDS_Shape theGeomShape, BLSURFPlugin_Hypothesis::TEntry theFace1, BLSURFPlugin_Hypothesis::TEntry theFace2)
+{
+ MESSAGE("BLSURFPlugin_BLSURF::createFacesPeriodicity");
+
+ TopoDS_Shape GeomShape1 = entryToShape(theFace1);
+ TopoDS_Shape GeomShape2 = entryToShape(theFace2);
+
+ TListOfIDs theFace1_ids = _getSubShapeIDsInMainShape(theGeomShape, GeomShape1, TopAbs_FACE);
+ TListOfIDs theFace2_ids = _getSubShapeIDsInMainShape(theGeomShape, GeomShape2, TopAbs_FACE);
+
+ // Only one face id, since only a face can be selected
+ int theFace1_id = theFace1_ids[0];
+ int theFace2_id = theFace2_ids[0];
+
+ std::pair<int, int> pairOfFacesID = std::make_pair(theFace1_id, theFace2_id);
+
+ _facesIDsPeriodicityVector.push_back(pairOfFacesID);
+ MESSAGE("_facesIDsPeriodicityVector.size() = " << _facesIDsPeriodicityVector.size());
+ MESSAGE("BLSURFPlugin_BLSURF::createFacesPeriodicity END");
+
+}
+
+
+/////////////////////////////////////////////////////////
+void BLSURFPlugin_BLSURF::createEdgesPeriodicity(TopoDS_Shape theGeomShape, BLSURFPlugin_Hypothesis::TEntry theFace1, BLSURFPlugin_Hypothesis::TEntry theEdge1,
+ BLSURFPlugin_Hypothesis::TEntry theFace2, BLSURFPlugin_Hypothesis::TEntry theEdge2, int edge_orientation)
+{
+ MESSAGE("BLSURFPlugin_BLSURF::createEdgesPeriodicity");
+
+ TEdgePeriodicityIDs edgePeriodicityIDs;
+
+ if (theFace1 != "")
+ {
+ TopoDS_Shape GeomFace1 = entryToShape(theFace1);
+ TListOfIDs theFace1_ids = _getSubShapeIDsInMainShape(theGeomShape, GeomFace1, TopAbs_FACE);
+ // Only one face id, since only a face can be selected
+ edgePeriodicityIDs.theFace1ID = theFace1_ids[0];
+ }
+ else
+ edgePeriodicityIDs.theFace1ID = 0;
+ if (theFace2 != "")
+ {
+ TopoDS_Shape GeomFace2 = entryToShape(theFace2);
+ TListOfIDs theFace2_ids = _getSubShapeIDsInMainShape(theGeomShape, GeomFace2, TopAbs_FACE);
+ edgePeriodicityIDs.theFace2ID = theFace2_ids[0];
+ }
+ else
+ edgePeriodicityIDs.theFace2ID = 0;
+
+ TopoDS_Shape GeomEdge1 = entryToShape(theEdge1);
+ TopoDS_Shape GeomEdge2 = entryToShape(theEdge2);
+
+ TListOfIDs theEdge1_ids = _getSubShapeIDsInMainShape(theGeomShape, GeomEdge1, TopAbs_EDGE);
+ TListOfIDs theEdge2_ids = _getSubShapeIDsInMainShape(theGeomShape, GeomEdge2, TopAbs_EDGE);
+
+ if (edge_orientation == 0 && GeomEdge1.Closed())
+ {
+ // if edge is closed, we have to set its orientation
+ MESSAGE("GeomEdge1.Orientation() = " << GeomEdge1.Orientation());
+ MESSAGE("GeomEdge2.Orientation() = " << GeomEdge2.Orientation());
+ if(GeomEdge1.Orientation() == TopAbs_FORWARD)
+ edge_orientation = CAD_ORIENTATION_REVERSED;
+ else
+ edge_orientation = CAD_ORIENTATION_FORWARD;
+ }
+
+ // Only one edge id, since only a edge can be selected
+ edgePeriodicityIDs.theEdge1ID = theEdge1_ids[0];
+ edgePeriodicityIDs.theEdge2ID = theEdge2_ids[0];
+ edgePeriodicityIDs.edge_orientation = edge_orientation;
+
+ _edgesIDsPeriodicityVector.push_back(edgePeriodicityIDs);
+ MESSAGE("_edgesIDsPeriodicityVector.size() = " << _edgesIDsPeriodicityVector.size());
+ MESSAGE("BLSURFPlugin_BLSURF::createEdgesPeriodicity END");
+
+}
+
+
+/////////////////////////////////////////////////////////
+void BLSURFPlugin_BLSURF::createVerticesPeriodicity(TopoDS_Shape theGeomShape, BLSURFPlugin_Hypothesis::TEntry theEdge1, BLSURFPlugin_Hypothesis::TEntry theVertex1,
+ BLSURFPlugin_Hypothesis::TEntry theEdge2, BLSURFPlugin_Hypothesis::TEntry theVertex2)
+{
+ MESSAGE("BLSURFPlugin_BLSURF::createVerticesPeriodicity");
+
+ TopoDS_Shape GeomEdge1 = entryToShape(theEdge1);
+ TopoDS_Shape GeomVertex1 = entryToShape(theVertex1);
+ TopoDS_Shape GeomEdge2 = entryToShape(theEdge2);
+ TopoDS_Shape GeomVertex2 = entryToShape(theVertex2);
+
+ TListOfIDs theEdge1_ids = _getSubShapeIDsInMainShape(theGeomShape, GeomEdge1, TopAbs_EDGE);
+ TListOfIDs vertices1_ids = _getSubShapeIDsInMainShape(theGeomShape, GeomVertex1, TopAbs_VERTEX);
+ TListOfIDs theEdge2_ids = _getSubShapeIDsInMainShape(theGeomShape, GeomEdge2, TopAbs_EDGE);
+ TListOfIDs vertices2_ids = _getSubShapeIDsInMainShape(theGeomShape, GeomVertex2, TopAbs_VERTEX);
+
+ // Only one vertex id, since only a vertex can be selected
+ TVertexPeriodicityIDs vertexPeriodicityIDs;
+ vertexPeriodicityIDs.theEdge1ID = theEdge1_ids[0];
+ vertexPeriodicityIDs.theVertex1ID = vertices1_ids[0];
+ vertexPeriodicityIDs.theEdge2ID = theEdge2_ids[0];
+ vertexPeriodicityIDs.theVertex2ID = vertices2_ids[0];
+
+ _verticesIDsPeriodicityVector.push_back(vertexPeriodicityIDs);
+ MESSAGE("_verticesIDsPeriodicityVector.size() = " << _verticesIDsPeriodicityVector.size());
+ MESSAGE("BLSURFPlugin_BLSURF::createVerticesPeriodicity END");
+
+}
+
+/////////////////////////////////////////////////////////
+
+void BLSURFPlugin_BLSURF::SetParameters(const BLSURFPlugin_Hypothesis* hyp,
cadsurf_session_t * css,
precad_session_t * pcs,
const TopoDS_Shape& theGeomShape,
- bool * use_precad
- )
+ bool * use_precad
+ )
{
// rnc : Bug 1457
// Clear map so that it is not stored in the algorithm with old enforced vertices in it
EnfVertexCoords2EnfVertexList.clear();
-
- double diagonal = SMESH_Mesh::GetShapeDiagonalSize( theGeomShape );
- double bbSegmentation = _gen->GetBoundaryBoxSegmentation();
- int _physicalMesh = BLSURFPlugin_Hypothesis::GetDefaultPhysicalMesh();
- int _geometricMesh = BLSURFPlugin_Hypothesis::GetDefaultGeometricMesh();
- double _phySize = BLSURFPlugin_Hypothesis::GetDefaultPhySize(diagonal, bbSegmentation);
- bool _phySizeRel = BLSURFPlugin_Hypothesis::GetDefaultPhySizeRel();
- double _minSize = BLSURFPlugin_Hypothesis::GetDefaultMinSize(diagonal);
- bool _minSizeRel = BLSURFPlugin_Hypothesis::GetDefaultMinSizeRel();
- double _maxSize = BLSURFPlugin_Hypothesis::GetDefaultMaxSize(diagonal);
- bool _maxSizeRel = BLSURFPlugin_Hypothesis::GetDefaultMaxSizeRel();
- double _gradation = BLSURFPlugin_Hypothesis::GetDefaultGradation();
- bool _quadAllowed = BLSURFPlugin_Hypothesis::GetDefaultQuadAllowed();
- double _angleMesh = BLSURFPlugin_Hypothesis::GetDefaultAngleMesh();
- double _chordalError = BLSURFPlugin_Hypothesis::GetDefaultChordalError(diagonal);
- bool _anisotropic = BLSURFPlugin_Hypothesis::GetDefaultAnisotropic();
- double _anisotropicRatio = BLSURFPlugin_Hypothesis::GetDefaultAnisotropicRatio();
- bool _removeTinyEdges = BLSURFPlugin_Hypothesis::GetDefaultRemoveTinyEdges();
- double _tinyEdgeLength = BLSURFPlugin_Hypothesis::GetDefaultTinyEdgeLength(diagonal);
- bool _badElementRemoval = BLSURFPlugin_Hypothesis::GetDefaultBadElementRemoval();
- double _badElementAspectRatio = BLSURFPlugin_Hypothesis::GetDefaultBadElementAspectRatio();
- bool _optimizeMesh = BLSURFPlugin_Hypothesis::GetDefaultOptimizeMesh();
- bool _quadraticMesh = BLSURFPlugin_Hypothesis::GetDefaultQuadraticMesh();
- int _verb = BLSURFPlugin_Hypothesis::GetDefaultVerbosity();
- int _topology = BLSURFPlugin_Hypothesis::GetDefaultTopology();
+
+ double diagonal = SMESH_Mesh::GetShapeDiagonalSize( theGeomShape );
+ double bbSegmentation = _gen->GetBoundaryBoxSegmentation();
+ int _physicalMesh = BLSURFPlugin_Hypothesis::GetDefaultPhysicalMesh();
+ int _geometricMesh = BLSURFPlugin_Hypothesis::GetDefaultGeometricMesh();
+ double _phySize = BLSURFPlugin_Hypothesis::GetDefaultPhySize(diagonal, bbSegmentation);
+ bool _phySizeRel = BLSURFPlugin_Hypothesis::GetDefaultPhySizeRel();
+ double _minSize = BLSURFPlugin_Hypothesis::GetDefaultMinSize(diagonal);
+ bool _minSizeRel = BLSURFPlugin_Hypothesis::GetDefaultMinSizeRel();
+ double _maxSize = BLSURFPlugin_Hypothesis::GetDefaultMaxSize(diagonal);
+ bool _maxSizeRel = BLSURFPlugin_Hypothesis::GetDefaultMaxSizeRel();
+ double _gradation = BLSURFPlugin_Hypothesis::GetDefaultGradation();
+ bool _quadAllowed = BLSURFPlugin_Hypothesis::GetDefaultQuadAllowed();
+ double _angleMesh = BLSURFPlugin_Hypothesis::GetDefaultAngleMesh();
+ double _chordalError = BLSURFPlugin_Hypothesis::GetDefaultChordalError(diagonal);
+ bool _anisotropic = BLSURFPlugin_Hypothesis::GetDefaultAnisotropic();
+ double _anisotropicRatio = BLSURFPlugin_Hypothesis::GetDefaultAnisotropicRatio();
+ bool _removeTinyEdges = BLSURFPlugin_Hypothesis::GetDefaultRemoveTinyEdges();
+ double _tinyEdgeLength = BLSURFPlugin_Hypothesis::GetDefaultTinyEdgeLength(diagonal);
+ bool _badElementRemoval = BLSURFPlugin_Hypothesis::GetDefaultBadElementRemoval();
+ double _badElementAspectRatio = BLSURFPlugin_Hypothesis::GetDefaultBadElementAspectRatio();
+ bool _optimizeMesh = BLSURFPlugin_Hypothesis::GetDefaultOptimizeMesh();
+ bool _quadraticMesh = BLSURFPlugin_Hypothesis::GetDefaultQuadraticMesh();
+ int _verb = BLSURFPlugin_Hypothesis::GetDefaultVerbosity();
+ int _topology = BLSURFPlugin_Hypothesis::GetDefaultTopology();
// PreCAD
- int _precadMergeEdges = BLSURFPlugin_Hypothesis::GetDefaultPreCADMergeEdges();
- int _precadProcess3DTopology = BLSURFPlugin_Hypothesis::GetDefaultPreCADProcess3DTopology();
- int _precadDiscardInput = BLSURFPlugin_Hypothesis::GetDefaultPreCADDiscardInput();
+ int _precadMergeEdges = BLSURFPlugin_Hypothesis::GetDefaultPreCADMergeEdges();
+ int _precadProcess3DTopology = BLSURFPlugin_Hypothesis::GetDefaultPreCADProcess3DTopology();
+ int _precadDiscardInput = BLSURFPlugin_Hypothesis::GetDefaultPreCADDiscardInput();
if (hyp) {
}
if (hyp->GetGradation() > 0)
_gradation = hyp->GetGradation();
- _quadAllowed = hyp->GetQuadAllowed();
- if (hyp->GetAngleMesh() > 0)
- _angleMesh = hyp->GetAngleMesh();
- if (hyp->GetChordalError() > 0)
- _chordalError = hyp->GetChordalError();
- _anisotropic = hyp->GetAnisotropic();
- if (hyp->GetAnisotropicRatio() >= 0)
- _anisotropicRatio = hyp->GetAnisotropicRatio();
- _removeTinyEdges = hyp->GetRemoveTinyEdges();
- if (hyp->GetTinyEdgeLength() > 0)
- _tinyEdgeLength = hyp->GetTinyEdgeLength();
- _badElementRemoval = hyp->GetBadElementRemoval();
- if (hyp->GetBadElementAspectRatio() >= 0)
- _badElementAspectRatio = hyp->GetBadElementAspectRatio();
- _optimizeMesh = hyp->GetOptimizeMesh();
- _quadraticMesh = hyp->GetQuadraticMesh();
+ _quadAllowed = hyp->GetQuadAllowed();
+ if (hyp->GetAngleMesh() > 0)
+ _angleMesh = hyp->GetAngleMesh();
+ if (hyp->GetChordalError() > 0)
+ _chordalError = hyp->GetChordalError();
+ _anisotropic = hyp->GetAnisotropic();
+ if (hyp->GetAnisotropicRatio() >= 0)
+ _anisotropicRatio = hyp->GetAnisotropicRatio();
+ _removeTinyEdges = hyp->GetRemoveTinyEdges();
+ if (hyp->GetTinyEdgeLength() > 0)
+ _tinyEdgeLength = hyp->GetTinyEdgeLength();
+ _badElementRemoval = hyp->GetBadElementRemoval();
+ if (hyp->GetBadElementAspectRatio() >= 0)
+ _badElementAspectRatio = hyp->GetBadElementAspectRatio();
+ _optimizeMesh = hyp->GetOptimizeMesh();
+ _quadraticMesh = hyp->GetQuadraticMesh();
_verb = hyp->GetVerbosity();
- _topology = (int) hyp->GetTopology();
- // PreCAD
- _precadMergeEdges = hyp->GetPreCADMergeEdges();
- _precadProcess3DTopology = hyp->GetPreCADProcess3DTopology();
- _precadDiscardInput = hyp->GetPreCADDiscardInput();
+ _topology = (int) hyp->GetTopology();
+ // PreCAD
+ _precadMergeEdges = hyp->GetPreCADMergeEdges();
+ _precadProcess3DTopology = hyp->GetPreCADProcess3DTopology();
+ _precadDiscardInput = hyp->GetPreCADDiscardInput();
- const BLSURFPlugin_Hypothesis::TOptionValues & opts = hyp->GetOptionValues();
+ const BLSURFPlugin_Hypothesis::TOptionValues& opts = hyp->GetOptionValues();
BLSURFPlugin_Hypothesis::TOptionValues::const_iterator opIt;
for ( opIt = opts.begin(); opIt != opts.end(); ++opIt )
if ( !opIt->second.empty() ) {
MESSAGE("cadsurf_set_param(): " << opIt->first << " = " << opIt->second);
set_param(css, opIt->first.c_str(), opIt->second.c_str());
}
-
- const BLSURFPlugin_Hypothesis::TOptionValues & preCADopts = hyp->GetPreCADOptionValues();
+
+ const BLSURFPlugin_Hypothesis::TOptionValues& custom_opts = hyp->GetCustomOptionValues();
+ for ( opIt = custom_opts.begin(); opIt != custom_opts.end(); ++opIt )
+ if ( !opIt->second.empty() ) {
+ MESSAGE("cadsurf_set_param(): " << opIt->first << " = " << opIt->second);
+ set_param(css, opIt->first.c_str(), opIt->second.c_str());
+ }
+
+ const BLSURFPlugin_Hypothesis::TOptionValues& preCADopts = hyp->GetPreCADOptionValues();
for ( opIt = preCADopts.begin(); opIt != preCADopts.end(); ++opIt )
if ( !opIt->second.empty() ) {
- if (_topology == BLSURFPlugin_Hypothesis::PreCAD) {
- MESSAGE("precad_set_param(): " << opIt->first << " = " << opIt->second);
- precad_set_param(pcs, opIt->first.c_str(), opIt->second.c_str());
- }
+ *use_precad = true;
+ MESSAGE("precad_set_param(): " << opIt->first << " = " << opIt->second);
+ precad_set_param(pcs, opIt->first.c_str(), opIt->second.c_str());
+ }
+
+ const BLSURFPlugin_Hypothesis::TOptionValues& custom_preCADopts = hyp->GetCustomPreCADOptionValues();
+ for ( opIt = custom_preCADopts.begin(); opIt != custom_preCADopts.end(); ++opIt )
+ if ( !opIt->second.empty() ) {
+ *use_precad = true;
+ MESSAGE("precad_set_param(): " << opIt->first << " = " << opIt->second);
+ precad_set_param(pcs, opIt->first.c_str(), opIt->second.c_str());
}
}
// else {
// PreCAD
if (_topology == BLSURFPlugin_Hypothesis::PreCAD) {
*use_precad = true;
- precad_set_param(pcs, "verbose", to_string(_verb).c_str());
+ precad_set_param(pcs, "verbose", val_to_string(_verb).c_str());
precad_set_param(pcs, "merge_edges", _precadMergeEdges ? "1" : "0");
precad_set_param(pcs, "process_3d_topology", _precadProcess3DTopology ? "1" : "0");
precad_set_param(pcs, "discard_input_topology", _precadDiscardInput ? "1" : "0");
}
+ // unlimit mesh size (issue 0022266)
+ set_param(css, "max_number_of_points_per_patch", "1000000");
bool useGradation = false;
switch (_physicalMesh)
{
case BLSURFPlugin_Hypothesis::PhysicalGlobalSize:
set_param(css, "physical_size_mode", "global");
- set_param(css, "global_physical_size", _phySizeRel ? to_string_rel(_phySize).c_str() : to_string(_phySize).c_str());
+ set_param(css, "global_physical_size", _phySizeRel ? val_to_string_rel(_phySize).c_str() : val_to_string(_phySize).c_str());
break;
case BLSURFPlugin_Hypothesis::PhysicalLocalSize:
set_param(css, "physical_size_mode", "local");
- set_param(css, "global_physical_size", _phySizeRel ? to_string_rel(_phySize).c_str() : to_string(_phySize).c_str());
+ set_param(css, "global_physical_size", _phySizeRel ? val_to_string_rel(_phySize).c_str() : val_to_string(_phySize).c_str());
useGradation = true;
break;
default:
{
case BLSURFPlugin_Hypothesis::GeometricalGlobalSize:
set_param(css, "geometric_size_mode", "global");
- set_param(css, "geometric_approximation", to_string(_angleMesh).c_str());
- set_param(css, "chordal_error", to_string(_chordalError).c_str());
+ set_param(css, "geometric_approximation", val_to_string(_angleMesh).c_str());
+ set_param(css, "chordal_error", val_to_string(_chordalError).c_str());
useGradation = true;
break;
case BLSURFPlugin_Hypothesis::GeometricalLocalSize:
set_param(css, "geometric_size_mode", "local");
- set_param(css, "geometric_approximation", to_string(_angleMesh).c_str());
- set_param(css, "chordal_error", to_string(_chordalError).c_str());
+ set_param(css, "geometric_approximation", val_to_string(_angleMesh).c_str());
+ set_param(css, "chordal_error", val_to_string(_chordalError).c_str());
useGradation = true;
break;
default:
double mins = _minSizeRel ? _minSize * diagonal : _minSize;
// - min size should not be greater than user size
if ( _phySize < mins )
- set_param(css, "min_size", _phySizeRel ? to_string_rel(_phySize).c_str() : to_string(_phySize).c_str());
+ set_param(css, "min_size", _phySizeRel ? val_to_string_rel(_phySize).c_str() : val_to_string(_phySize).c_str());
else
- set_param(css, "min_size", _minSizeRel ? to_string_rel(_minSize).c_str() : to_string(_minSize).c_str());
+ set_param(css, "min_size", _minSizeRel ? val_to_string_rel(_minSize).c_str() : val_to_string(_minSize).c_str());
// - compute absolute max size
double maxs = _maxSizeRel ? _maxSize * diagonal : _maxSize;
// - max size should not be less than user size
if ( _phySize > maxs )
- set_param(css, "max_size", _phySizeRel ? to_string_rel(_phySize).c_str() : to_string(_phySize).c_str());
+ set_param(css, "max_size", _phySizeRel ? val_to_string_rel(_phySize).c_str() : val_to_string(_phySize).c_str());
else
- set_param(css, "max_size", _maxSizeRel ? to_string_rel(_maxSize).c_str() : to_string(_maxSize).c_str());
+ set_param(css, "max_size", _maxSizeRel ? val_to_string_rel(_maxSize).c_str() : val_to_string(_maxSize).c_str());
}
else {
// user size is not explicitly specified
// - if minsize is not explicitly specified, we pass default value computed automatically, in this case "relative" flag is ignored
- set_param(css, "min_size", _minSizeRel ? to_string_rel(_minSize).c_str() : to_string(_minSize).c_str());
+ set_param(css, "min_size", _minSizeRel ? val_to_string_rel(_minSize).c_str() : val_to_string(_minSize).c_str());
// - if maxsize is not explicitly specified, we pass default value computed automatically, in this case "relative" flag is ignored
- set_param(css, "max_size", _maxSizeRel ? to_string_rel(_maxSize).c_str() : to_string(_maxSize).c_str());
+ set_param(css, "max_size", _maxSizeRel ? val_to_string_rel(_maxSize).c_str() : val_to_string(_maxSize).c_str());
}
-
- if ( useGradation )
- set_param(css, "gradation", to_string(_gradation).c_str());
+ // anisotropic and quadrangle mesh requires disabling gradation
+ if ( _anisotropic && _quadAllowed )
+ useGradation = false; // limitation of V1.3
+ if ( useGradation )
+ set_param(css, "gradation", val_to_string(_gradation).c_str());
set_param(css, "element_generation", _quadAllowed ? "quad_dominant" : "triangle");
set_param(css, "metric", _anisotropic ? "anisotropic" : "isotropic");
if ( _anisotropic )
- set_param(css, "anisotropic_ratio", to_string(_anisotropicRatio).c_str());
+ set_param(css, "anisotropic_ratio", val_to_string(_anisotropicRatio).c_str());
set_param(css, "remove_tiny_edges", _removeTinyEdges ? "1" : "0");
if ( _removeTinyEdges )
- set_param(css, "tiny_edge_length", to_string(_tinyEdgeLength).c_str());
+ set_param(css, "tiny_edge_length", val_to_string(_tinyEdgeLength).c_str());
set_param(css, "force_bad_surface_element_removal", _badElementRemoval ? "1" : "0");
if ( _badElementRemoval )
- set_param(css, "bad_surface_element_aspect_ratio", to_string(_badElementAspectRatio).c_str());
+ set_param(css, "bad_surface_element_aspect_ratio", val_to_string(_badElementAspectRatio).c_str());
set_param(css, "optimisation", _optimizeMesh ? "yes" : "no");
set_param(css, "element_order", _quadraticMesh ? "quadratic" : "linear");
- set_param(css, "verbose", to_string(_verb).c_str());
+ set_param(css, "verbose", val_to_string(_verb).c_str());
_smp_phy_size = _phySizeRel ? _phySize*diagonal : _phySize;
if ( _verb > 0 )
// - build the map here for each face with an attractor set and only if the attractor shape as changed since the last call to _buildmap()
// -> define a bool _mapbuilt in the class that is set to false by default and set to true when calling _buildmap() OK
+ theNbAttractors = 0;
const BLSURFPlugin_Hypothesis::TAttractorMap class_attractors = BLSURFPlugin_Hypothesis::GetClassAttractorEntries(hyp);
int key=-1;
BLSURFPlugin_Hypothesis::TAttractorMap::const_iterator AtIt = class_attractors.begin();
if ( !AtIt->second->Empty() ) {
// MESSAGE("cadsurf_set_attractor(): " << AtIt->first << " = " << AtIt->second);
GeomShape = entryToShape(AtIt->first);
+ if ( !SMESH_MesherHelper::IsSubShape( GeomShape, theGeomShape ))
+ continue;
AttShape = AtIt->second->GetAttractorShape();
GeomType = GeomShape.ShapeType();
// Group Management
|| AttShape.ShapeType() == TopAbs_COMPOUND) ){
HasSizeMapOnFace = true;
- if (! FacesWithSizeMap.Contains(TopoDS::Face(GeomShape)) ) {
- key = FacesWithSizeMap.Add(TopoDS::Face(GeomShape) );
- }
- else {
- key = FacesWithSizeMap.FindIndex(TopoDS::Face(GeomShape));
-// MESSAGE("Face with key " << key << " already in map");
- }
+ key = FacesWithSizeMap.Add(TopoDS::Face(GeomShape) );
- FaceId2ClassAttractor[key] = AtIt->second;
+ FaceId2ClassAttractor[key].push_back( AtIt->second );
+ ++theNbAttractors;
}
else{
MESSAGE("Wrong shape type !!")
// #endif
}
}
+
+ // PERIODICITY
+
+ // reset vectors
+ _preCadFacesIDsPeriodicityVector.clear();
+ _preCadEdgesIDsPeriodicityVector.clear();
+ _facesIDsPeriodicityVector.clear();
+ _edgesIDsPeriodicityVector.clear();
+ _verticesIDsPeriodicityVector.clear();
+
+ MESSAGE("SetParameters preCadFacesPeriodicityVector");
+ const BLSURFPlugin_Hypothesis::TPreCadPeriodicityVector preCadFacesPeriodicityVector = BLSURFPlugin_Hypothesis::GetPreCadFacesPeriodicityVector(hyp);
+
+ for (std::size_t i = 0; i<preCadFacesPeriodicityVector.size(); i++){
+ MESSAGE("SetParameters preCadFacesPeriodicityVector[" << i << "]");
+ createPreCadFacesPeriodicity(theGeomShape, preCadFacesPeriodicityVector[i]);
+ }
+ MESSAGE("_preCadFacesIDsPeriodicityVector.size() = " << _preCadFacesIDsPeriodicityVector.size());
+
+ MESSAGE("SetParameters preCadEdgesPeriodicityVector");
+ const BLSURFPlugin_Hypothesis::TPreCadPeriodicityVector preCadEdgesPeriodicityVector = BLSURFPlugin_Hypothesis::GetPreCadEdgesPeriodicityVector(hyp);
+
+ for (std::size_t i = 0; i<preCadEdgesPeriodicityVector.size(); i++){
+ MESSAGE("SetParameters preCadEdgesPeriodicityVector[" << i << "]");
+ createPreCadEdgesPeriodicity(theGeomShape, preCadEdgesPeriodicityVector[i]);
+ }
+ MESSAGE("_preCadEdgesIDsPeriodicityVector.size() = " << _preCadEdgesIDsPeriodicityVector.size());
+
+ if ( _preCadFacesIDsPeriodicityVector.size() > 0 || _preCadEdgesIDsPeriodicityVector.size() > 0 )
+ {
+ MESSAGE("USING PRECAD FOR PERIODICITY")
+ *use_precad = true;
+ precad_set_param(pcs, "verbose", val_to_string(_verb).c_str());
+ }
+
+ MESSAGE("SetParameters facesPeriodicityVector");
+ const BLSURFPlugin_Hypothesis::TFacesPeriodicityVector facesPeriodicityVector = BLSURFPlugin_Hypothesis::GetFacesPeriodicityVector(hyp);
+
+ for (std::size_t i = 0; i<facesPeriodicityVector.size(); i++){
+ MESSAGE("SetParameters facesPeriodicityVector[" << i << "]");
+ createFacesPeriodicity(theGeomShape, facesPeriodicityVector[i].first, facesPeriodicityVector[i].second);
+ }
+ MESSAGE("_facesIDsPeriodicityVector.size() = " << _facesIDsPeriodicityVector.size());
+
+
+ MESSAGE("SetParameters edgesPeriodicityVector");
+ const BLSURFPlugin_Hypothesis::TEdgesPeriodicityVector edgesPeriodicityVector = BLSURFPlugin_Hypothesis::GetEdgesPeriodicityVector(hyp);
+
+ for (std::size_t i = 0; i<edgesPeriodicityVector.size(); i++){
+ MESSAGE("SetParameters edgesPeriodicityVector[" << i << "]");
+ // TODO: passer directement en paramètre edgesPeriodicityVector[i] plutôt que tous ces attributs
+ createEdgesPeriodicity(theGeomShape, edgesPeriodicityVector[i].theFace1Entry, edgesPeriodicityVector[i].theEdge1Entry,
+ edgesPeriodicityVector[i].theFace2Entry, edgesPeriodicityVector[i].theEdge2Entry, edgesPeriodicityVector[i].edge_orientation);
+ }
+ MESSAGE("_edgesIDsPeriodicityVector.size() = " << _edgesIDsPeriodicityVector.size());
+
+ MESSAGE("SetParameters verticesPeriodicityVector");
+ const BLSURFPlugin_Hypothesis::TVerticesPeriodicityVector verticesPeriodicityVector = BLSURFPlugin_Hypothesis::GetVerticesPeriodicityVector(hyp);
+
+ for (std::size_t i = 0; i<verticesPeriodicityVector.size(); i++){
+ MESSAGE("SetParameters verticesPeriodicityVector[" << i << "]");
+ // TODO: passer directement en paramètre verticesPeriodicityVector[i] plutôt que tous ces attributs
+ createVerticesPeriodicity(theGeomShape, verticesPeriodicityVector[i].theEdge1Entry, verticesPeriodicityVector[i].theVertex1Entry,
+ verticesPeriodicityVector[i].theEdge2Entry, verticesPeriodicityVector[i].theVertex2Entry);
+ }
+ MESSAGE("_verticesIDsPeriodicityVector.size() = " << _verticesIDsPeriodicityVector.size());
}
//================================================================================
{
// --------------------------------------------------------------------------
/*!
- * \brief Class correctly terminating usage of BLSURF library at destruction
+ * \brief Class correctly terminating usage of MG-CADSurf library at destruction
*/
class BLSURF_Cleaner
{
cadsurf_session_t* _css;
cad_t * _cad;
dcad_t * _dcad;
+ cad_t * _cleanc;
+ dcad_t * _cleandc;
public:
BLSURF_Cleaner(context_t * ctx,
cadsurf_session_t* css,
cad_t * cad,
- dcad_t * dcad)
+ dcad_t * dcad,
+ cad_t * cleanc,
+ dcad_t * cleandc)
: _ctx ( ctx ),
_css ( css ),
_cad ( cad ),
- _dcad( dcad )
+ _dcad( dcad ),
+ _cleanc( cleanc ),
+ _cleandc( cleandc )
{
}
~BLSURF_Cleaner()
cad_delete(_cad); _cad = 0;
dcad_delete(_dcad); _dcad = 0;
+ cad_delete(_cleanc); _cleanc = 0;
+ dcad_delete(_cleandc); _cleandc = 0;
if ( !exceptContext )
{
context_delete(_ctx); _ctx = 0;
{
// sort nodes by position in the following order:
// SMDS_TOP_FACE=2, SMDS_TOP_EDGE=1, SMDS_TOP_VERTEX=0, SMDS_TOP_3DSPACE=3
- int operator()( const SMDS_MeshNode* n1, const SMDS_MeshNode* n2 ) const
+ bool operator()( const SMDS_MeshNode* n1, const SMDS_MeshNode* n2 ) const
{
- SMDS_TypeOfPosition pos1 = n1->GetPosition()->GetTypeOfPosition();
- SMDS_TypeOfPosition pos2 = n2->GetPosition()->GetTypeOfPosition();
- if ( pos1 == pos2 ) return 0;
- if ( pos1 < pos2 || pos1 == SMDS_TOP_3DSPACE ) return 1;
- return -1;
+ // NEW ORDER: nodes earlier added to sub-mesh are considered "less"
+ return n1->getIdInShape() < n2->getIdInShape();
+ // SMDS_TypeOfPosition pos1 = n1->GetPosition()->GetTypeOfPosition();
+ // SMDS_TypeOfPosition pos2 = n2->GetPosition()->GetTypeOfPosition();
+ // if ( pos1 == pos2 ) return 0;
+ // if ( pos1 < pos2 || pos1 == SMDS_TOP_3DSPACE ) return 1;
+ // return -1;
}
// sort sub-meshes in order: EDGE, VERTEX
bool operator()( const SMESHDS_SubMesh* s1, const SMESHDS_SubMesh* s2 ) const
//================================================================================
/*!
- * \brief Fills groups on nodes to be merged
+ * \brief Fills groups of nodes to be merged
*/
//================================================================================
}
if ( u2node.size() < 2 ) return;
- double tol = (( u2node.rbegin()->first - u2node.begin()->first ) / 20.) / u2node.size();
+ //double tol = (( u2node.rbegin()->first - u2node.begin()->first ) / 20.) / u2node.size();
+ Standard_Real f,l;
+ BRep_Tool::Range( TopoDS::Edge( shape ), f,l );
+ double tol = (( l - f ) / 20.) / u2node.size();
+
std::multimap< double, const SMDS_MeshNode* >::iterator un2, un1;
for ( un2 = u2node.begin(), un1 = un2++; un2 != u2node.end(); un1 = un2++ )
{
}
}
// make nodes created on the boundary of viscous layer replace nodes created
- // by BLSURF as their SMDS_Position is more correct
+ // by MG-CADSurf as their SMDS_Position is more correct
nodes.sort( ShapeTypeCompare() );
nodeGroupsToMerge.push_back( nodes );
}
continue;
BRepBuilderAPI_MakePolygon wire;
+ const size_t i0 = tmpVertex.size();
for ( size_t iN = 1; iN < wirePoints.size(); ++iN )
{
wire.Add( SMESH_TNodeXYZ( wirePoints[ iN ].node ));
origNodes.push_back( wirePoints[ iN ].node );
tmpVertex.push_back( wire.LastVertex() );
}
- tmpVertex[0] = wire.FirstVertex();
+ tmpVertex[ i0 ] = wire.FirstVertex(); // wire.LastVertex()==NULL for 1 vertex in wire
wire.Close();
if ( !wire.IsDone() )
throw SALOME_Exception("BLSURFPlugin_BLSURF: BRepBuilderAPI_MakePolygon failed");
//_proxyFace = TopoDS::Face( fExp.Current() );
- // Make input mesh for BLSURF: segments on EDGE's of newFace
+ // Make input mesh for MG-CADSurf: segments on EDGE's of newFace
// make nodes and fill in _tmp2origNN
//
//--------------------------------------------------------------------------------
/*!
- * \brief Fill in the origMesh with faces computed by BLSURF in this tmp mesh
+ * \brief Fill in the origMesh with faces computed by MG-CADSurf in this tmp mesh
*/
//--------------------------------------------------------------------------------
helper.SetSubShape( origFace );
helper.SetElementsOnShape( true );
+ SMESH_MesherHelper tmpHelper( *this );
+ tmpHelper.SetSubShape( _proxyFace );
+
// iterate over tmp faces and copy them in origMesh
const SMDS_MeshNode* nodes[27];
const SMDS_MeshNode* nullNode = 0;
_tmp2origNN.insert( _tmp2origNN.end(), make_pair( n, nullNode ));
if ( !n2nIt->second ) {
n->GetXYZ( xyz );
- gp_XY uv = helper.GetNodeUV( _proxyFace, n );
+ gp_XY uv = tmpHelper.GetNodeUV( _proxyFace, n );
n2nIt->second = helper.AddNode( xyz[0], xyz[1], xyz[2], uv.X(), uv.Y() );
}
nodes[ nbN ] = n2nIt->second;
{
std::string * _error;
int _verbosity;
+ double * _progress;
};
// Fix problem with locales
Kernel_Utils::Localizer aLocalizer;
- if ( !compute( aMesh, aShape ))
+ this->SMESH_Algo::_progress = 1e-3; // prevent progress advancment while computing attractors
+
+ if ( !compute( aMesh, aShape, /*allowSubMeshClearing=*/true ))
return false;
if ( _haveViscousLayers )
if ( !viscousMesh )
return false; // error in StdMeshers_ViscousLayers2D::Compute()
- // Compute BLSURF mesh on viscous layers
+ // Compute MG-CADSurf mesh on viscous layers
if ( viscousMesh->NbProxySubMeshes() > 0 )
{
TmpMesh tmpMesh;
const TopoDS_Face& proxyFace = tmpMesh.makeProxyFace( viscousMesh, F );
- if ( !compute( tmpMesh, proxyFace ))
+ if ( !compute( tmpMesh, proxyFace, /*allowSubMeshClearing=*/false ))
return false;
tmpMesh.FillInOrigMesh( aMesh, F );
}
}
- // Re-compute BLSURF mesh on the rest faces if the mesh was cleared
+ // Re-compute MG-CADSurf mesh on the rest faces if the mesh was cleared
for (TopExp_Explorer face_iter(aShape,TopAbs_FACE);face_iter.More();face_iter.Next())
{
SMESH_subMesh* fSM = aMesh.GetSubMesh( F );
if ( fSM->IsMeshComputed() ) continue;
- if ( !compute( aMesh, aShape ))
+ if ( !compute( aMesh, aShape, /*allowSubMeshClearing=*/true ))
return false;
break;
}
//=============================================================================
bool BLSURFPlugin_BLSURF::compute(SMESH_Mesh& aMesh,
- const TopoDS_Shape& aShape)
+ const TopoDS_Shape& aShape,
+ bool allowSubMeshClearing)
{
/* create a distene context (generic object) */
status_t status = STATUS_ERROR;
+ myMesh = &aMesh;
SMESHDS_Mesh* meshDS = aMesh.GetMeshDS();
SMESH_MesherHelper helper( aMesh );
// do not call helper.IsQuadraticSubMesh() because sub-meshes
TSubMeshSet edgeSubmeshes;
TSubMeshSet& mergeSubmeshes = edgeSubmeshes;
- TopTools_IndexedMapOfShape fmap;
- TopTools_IndexedMapOfShape emap;
- TopTools_IndexedMapOfShape pmap;
+ TopTools_IndexedMapOfShape pmap, emap, fmap;
// Issue 0019864. On DebianSarge, FE signals do not obey to OSD::SetSignal(false)
-#ifndef WNT
+#ifndef WIN32
feclearexcept( FE_ALL_EXCEPT );
int oldFEFlags = fedisableexcept( FE_ALL_EXCEPT );
#endif
/* Set the message callback in the working context */
message_cb_user_data mcud;
mcud._error = & this->SMESH_Algo::_comment;
+ mcud._progress = & this->SMESH_Algo::_progress;
mcud._verbosity =
_hypothesis ? _hypothesis->GetVerbosity() : BLSURFPlugin_Hypothesis::GetDefaultVerbosity();
context_set_message_callback(ctx, message_cb, &mcud);
// PreCAD
// If user requests it, send the CAD through Distene preprocessor : PreCAD
cad_t *cleanc = NULL; // preprocessed cad
+ dcad_t *cleandc = NULL; // preprocessed dcad
precad_session_t *pcs = precad_session_new(ctx);
+ // Give both dcad and cad to precad
+ precad_data_set_dcad(pcs, dcad);
precad_data_set_cad(pcs, c);
cadsurf_session_t *css = cadsurf_session_new(ctx);
// an object that correctly deletes all cadsurf objects at destruction
- BLSURF_Cleaner cleaner( ctx,css,c,dcad );
+ BLSURF_Cleaner cleaner( ctx,css,c,dcad,cleanc,cleandc );
MESSAGE("BEGIN SetParameters");
bool use_precad = false;
- SetParameters(
- // #if BLSURF_VERSION_LONG >= "3.1.1"
- // c,
- // #endif
- _hypothesis, css, pcs, aShape, &use_precad);
+ SetParameters(_hypothesis, css, pcs, aShape, &use_precad);
MESSAGE("END SetParameters");
+ MESSAGE("_preCadFacesIDsPeriodicityVector.size() = " << _preCadFacesIDsPeriodicityVector.size());
+
haveQuadraticSubMesh = haveQuadraticSubMesh || (_hypothesis != NULL && _hypothesis->GetQuadraticMesh());
helper.SetIsQuadratic( haveQuadraticSubMesh );
vector<Handle(Geom2d_Curve)> curves;
vector<Handle(Geom_Surface)> surfaces;
- fmap.Clear();
emap.Clear();
pmap.Clear();
FaceId2PythonSmp.clear();
assert(Py_IsInitialized());
PyGILState_STATE gstate;
- gstate = PyGILState_Ensure();
string theSizeMapStr;
{
TopoDS_Face f = TopoDS::Face(face_iter.Current());
+ SMESH_subMesh* fSM = aMesh.GetSubMesh( f );
+ if ( !fSM->IsEmpty() ) continue; // skip already meshed FACE with viscous layers
+
// make INTERNAL face oriented FORWARD (issue 0020993)
if (f.Orientation() != TopAbs_FORWARD && f.Orientation() != TopAbs_REVERSED )
f.Orientation(TopAbs_FORWARD);
- if (fmap.FindIndex(f) > 0)
- continue;
iface = fmap.Add(f);
+// std::string aFileName = "fmap_face_";
+// aFileName.append(val_to_string(iface));
+// aFileName.append(".brep");
+// BRepTools::Write(f,aFileName.c_str());
surfaces.push_back(BRep_Tool::Surface(f));
cad_face_t *fce = cad_face_new(c, iface, surf_fun, surfaces.back());
/* by default a face has no tag (color).
- The following call sets it to the same value as the face_id : */
- cad_face_set_tag(fce, iface);
+ The following call sets it to the same value as the Geom module ID : */
+ const int faceTag = meshDS->ShapeToIndex(f);
+ cad_face_set_tag(fce, faceTag);
/* Set face orientation (optional if you want a well oriented output mesh)*/
if(f.Orientation() != TopAbs_FORWARD)
else
cad_face_set_orientation(fce, CAD_ORIENTATION_FORWARD);
- if (HasSizeMapOnFace && !use_precad)
+ if (HasSizeMapOnFace /*&& !use_precad*/) //22903: use_precad seems not to interfere
{
// -----------------
// Classic size map
if (FaceId2SizeMap.find(faceKey)!=FaceId2SizeMap.end()) {
- MESSAGE("A size map is defined on face :"<<faceKey)
- theSizeMapStr = FaceId2SizeMap[faceKey];
+ MESSAGE("A size map is defined on face :"<<faceKey);
+ theSizeMapStr = FaceId2SizeMap[faceKey];
// check if function ends with "return"
if (theSizeMapStr.find(bad_end) == (theSizeMapStr.size()-bad_end.size()-1))
continue;
// Expr To Python function, verification is performed at validation in GUI
+ gstate = PyGILState_Ensure();
PyObject * obj = NULL;
obj= PyRun_String(theSizeMapStr.c_str(), Py_file_input, main_dict, NULL);
Py_DECREF(obj);
func = PyObject_GetAttrString(main_mod, "f");
FaceId2PythonSmp[iface]=func;
FaceId2SizeMap.erase(faceKey);
+ PyGILState_Release(gstate);
}
// Specific size map = Attractor
// -----------------
// Class Attractors
// -----------------
- std::map<int,BLSURFPlugin_Attractor* >::iterator clAttractor_iter = FaceId2ClassAttractor.find(faceKey);
+ TId2ClsAttractorVec::iterator clAttractor_iter = FaceId2ClassAttractor.find(faceKey);
if (clAttractor_iter != FaceId2ClassAttractor.end()){
MESSAGE("Face indice: " << iface);
MESSAGE("Adding attractor");
- FaceIndex2ClassAttractor[iface]=clAttractor_iter->second;
+ std::vector< BLSURFPlugin_Attractor* > & attVec = clAttractor_iter->second;
+ for ( size_t i = 0; i < attVec.size(); ++i )
+ if ( !attVec[i]->IsMapBuilt() ) {
+ std::cout<<"Compute " << theNbAttractors-- << "-th attractor" <<std::endl;
+ attVec[i]->BuildMap();
+ }
+ FaceIndex2ClassAttractor[iface].swap( attVec );
FaceId2ClassAttractor.erase(clAttractor_iter);
}
} // if (HasSizeMapOnFace && !use_precad)
MESSAGE("Point is out of face: node is not created");
if (EnfVertexCoords2ProjVertex.find(xyzCoords) != EnfVertexCoords2ProjVertex.end()) {
EnfVertexCoords2ProjVertex.erase(xyzCoords);
- EnfVertexCoords2EnfVertexList.erase(xyzCoords);
+ // isssue 22783. Do not erase as this point can be IN other face of a group
+ //EnfVertexCoords2EnfVertexList.erase(xyzCoords);
}
}
if ( result == TopAbs_UNKNOWN ) {
MESSAGE("Point position on face is unknown: node is not created");
if (EnfVertexCoords2ProjVertex.find(xyzCoords) != EnfVertexCoords2ProjVertex.end()) {
EnfVertexCoords2ProjVertex.erase(xyzCoords);
- EnfVertexCoords2EnfVertexList.erase(xyzCoords);
+ //EnfVertexCoords2EnfVertexList.erase(xyzCoords);
}
}
if ( result == TopAbs_ON ) {
MESSAGE("Point is on border of face: node is not created");
if (EnfVertexCoords2ProjVertex.find(xyzCoords) != EnfVertexCoords2ProjVertex.end()) {
EnfVertexCoords2ProjVertex.erase(xyzCoords);
- EnfVertexCoords2EnfVertexList.erase(xyzCoords);
+ //EnfVertexCoords2EnfVertexList.erase(xyzCoords);
}
}
if ( result == TopAbs_IN )
SMESH_subMesh* vSM = aMesh.GetSubMesh( v );
vSM->ComputeStateEngine( SMESH_subMesh::COMPUTE );
mergeSubmeshes.insert( vSM->GetSubMeshDS() );
- //if ( tag != pmap.Extent() )
- needMerge = true;
+ // //if ( tag != pmap.Extent() )
+ // needMerge = true;
}
}
if ( tag == 0 ) tag = ienf;
if (ic <= 0)
ic = emap.Add(e);
+// std::string aFileName = "fmap_edge_";
+// aFileName.append(val_to_string(ic));
+// aFileName.append(".brep");
+// BRepTools::Write(e,aFileName.c_str());
+
double tmin,tmax;
curves.push_back(BRep_Tool::CurveOnSurface(e, f, tmin, tmax));
if (theSizeMapStr.find(bad_end) == (theSizeMapStr.size()-bad_end.size()-1))
continue;
// Expr To Python function, verification is performed at validation in GUI
+ gstate = PyGILState_Ensure();
PyObject * obj = NULL;
obj= PyRun_String(theSizeMapStr.c_str(), Py_file_input, main_dict, NULL);
Py_DECREF(obj);
func = PyObject_GetAttrString(main_mod, "f");
EdgeId2PythonSmp[ic]=func;
EdgeId2SizeMap.erase(edgeKey);
+ PyGILState_Release(gstate);
}
}
/* data of nodes existing on the edge */
SMESH_subMesh* sm = aMesh.GetSubMesh( e );
if ( !sm->IsEmpty() )
{
- SMESH_subMeshIteratorPtr subsmIt = sm->getDependsOnIterator( /*includeSelf=*/true,
- /*complexFirst=*/false);
- while ( subsmIt->more() )
- edgeSubmeshes.insert( subsmIt->next()->GetSubMeshDS() );
+ // SMESH_subMeshIteratorPtr subsmIt = sm->getDependsOnIterator( /*includeSelf=*/true,
+ // /*complexFirst=*/false);
+ // while ( subsmIt->more() )
+ // edgeSubmeshes.insert( subsmIt->next()->GetSubMeshDS() );
+ edgeSubmeshes.insert( sm->GetSubMeshDS() );
nodeData.reset( new StdMeshers_FaceSide( f, e, &aMesh, /*isForwrd = */true,
/*ignoreMedium=*/haveQuadraticSubMesh));
if (e.Orientation() == TopAbs_INTERNAL)
cad_edge_set_property(edg, EDGE_PROPERTY_INTERNAL);
- // pass existing nodes of sub-meshes to BLSURF
+ // pass existing nodes of sub-meshes to MG-CADSurf
if ( nodeData )
{
const std::vector<UVPtStruct>& nodeDataVec = nodeData->GetUVPtStruct();
*ip = pmap.FindIndex(v);
if(*ip <= 0) {
*ip = pmap.Add(v);
- SMESH_subMesh* sm = aMesh.GetSubMesh(v);
- if ( sm->IsMeshComputed() )
- edgeSubmeshes.insert( sm->GetSubMeshDS() );
+ // SMESH_subMesh* sm = aMesh.GetSubMesh(v);
+ // if ( sm->IsMeshComputed() )
+ // edgeSubmeshes.insert( sm->GetSubMeshDS() );
}
+
+// std::string aFileName = "fmap_vertex_";
+// aFileName.append(val_to_string(*ip));
+// aFileName.append(".brep");
+// BRepTools::Write(v,aFileName.c_str());
+
if (HasSizeMapOnVertex){
vertexKey = VerticesWithSizeMap.FindIndex(v);
if (VertexId2SizeMap.find(vertexKey)!=VertexId2SizeMap.end()){
if (theSizeMapStr.find(bad_end) == (theSizeMapStr.size()-bad_end.size()-1))
continue;
// Expr To Python function, verification is performed at validation in GUI
+ gstate = PyGILState_Ensure();
PyObject * obj = NULL;
obj= PyRun_String(theSizeMapStr.c_str(), Py_file_input, main_dict, NULL);
Py_DECREF(obj);
func = PyObject_GetAttrString(main_mod, "f");
VertexId2PythonSmp[*ip]=func;
VertexId2SizeMap.erase(vertexKey); // do not erase if using a vector
+ PyGILState_Release(gstate);
}
}
}
const SMDS_MeshNode* n = nIt->next();
if ( n->NbInverseElements( SMDSAbs_Face ) > 0 )
{
- needMerge = true;
+ needMerge = true; // to correctly sew with viscous mesh
// add existing medium nodes to helper
if ( aMesh.NbEdges( ORDER_QUADRATIC ) > 0 )
{
continue;
}
}
+ if ( allowSubMeshClearing )
{
SMDS_ElemIteratorPtr eIt = smDS->GetElements();
- while ( eIt->more() ) meshDS->RemoveFreeElement( eIt->next(), smDS );
+ while ( eIt->more() ) meshDS->RemoveFreeElement( eIt->next(), 0 );
SMDS_NodeIteratorPtr nIt = smDS->GetNodes();
- while ( nIt->more() ) meshDS->RemoveFreeNode( nIt->next(), smDS );
+ while ( nIt->more() ) meshDS->RemoveFreeNode( nIt->next(), 0 );
+ smDS->Clear();
+ }
+ else
+ {
+ needMerge = true;
+ }
+ }
+
+ ///////////////////////
+ // PERIODICITY //
+ ///////////////////////
+
+ MESSAGE("BEFORE PERIODICITY");
+ MESSAGE("_preCadFacesIDsPeriodicityVector.size() = " << _preCadFacesIDsPeriodicityVector.size());
+ if (! _preCadFacesIDsPeriodicityVector.empty()) {
+ MESSAGE("INTO PRECAD FACES PERIODICITY");
+ for (std::size_t i=0; i < _preCadFacesIDsPeriodicityVector.size(); i++){
+ std::vector<int> theFace1_ids = _preCadFacesIDsPeriodicityVector[i].shape1IDs;
+ std::vector<int> theFace2_ids = _preCadFacesIDsPeriodicityVector[i].shape2IDs;
+ int* theFace1_ids_c = &theFace1_ids[0];
+ int* theFace2_ids_c = &theFace2_ids[0];
+ std::ostringstream o;
+ o << "_preCadFacesIDsPeriodicityVector[" << i << "] = [";
+ for (std::size_t j=0; j < theFace1_ids.size(); j++)
+ o << theFace1_ids[j] << ", ";
+ o << "], [";
+ for (std::size_t j=0; j < theFace2_ids.size(); j++)
+ o << theFace2_ids[j] << ", ";
+ o << "]";
+ MESSAGE(o.str());
+ MESSAGE("theFace1_ids.size(): " << theFace1_ids.size());
+ MESSAGE("theFace2_ids.size(): " << theFace2_ids.size());
+ if (_preCadFacesIDsPeriodicityVector[i].theSourceVerticesCoords.empty())
+ {
+ // If no source points, call peridoicity without transformation function
+ MESSAGE("periodicity without transformation function");
+ meshgems_cad_periodicity_transformation_t periodicity_transformation = NULL;
+ status = cad_add_face_multiple_periodicity_with_transformation_function(c, theFace1_ids_c, theFace1_ids.size(),
+ theFace2_ids_c, theFace2_ids.size(), periodicity_transformation, NULL);
+ if(status != STATUS_OK)
+ cout << "cad_add_face_multiple_periodicity_with_transformation_function failed with error code " << status << "\n";
+ }
+ else
+ {
+ // get the transformation vertices
+ MESSAGE("periodicity with transformation vertices");
+ double* theSourceVerticesCoords_c = &_preCadFacesIDsPeriodicityVector[i].theSourceVerticesCoords[0];
+ double* theTargetVerticesCoords_c = &_preCadFacesIDsPeriodicityVector[i].theTargetVerticesCoords[0];
+ int nbSourceVertices = _preCadFacesIDsPeriodicityVector[i].theSourceVerticesCoords.size()/3;
+ int nbTargetVertices = _preCadFacesIDsPeriodicityVector[i].theTargetVerticesCoords.size()/3;
+
+ MESSAGE("nbSourceVertices: " << nbSourceVertices << ", nbTargetVertices: " << nbTargetVertices);
+
+ status = cad_add_face_multiple_periodicity_with_transformation_function_by_points(c, theFace1_ids_c, theFace1_ids.size(),
+ theFace2_ids_c, theFace2_ids.size(), theSourceVerticesCoords_c, nbSourceVertices, theTargetVerticesCoords_c, nbTargetVertices);
+ if(status != STATUS_OK)
+ cout << "cad_add_face_multiple_periodicity_with_transformation_function_by_points failed with error code " << status << "\n";
+ }
+ }
+
+ MESSAGE("END PRECAD FACES PERIODICITY");
+ }
+
+ MESSAGE("_preCadEdgesIDsPeriodicityVector.size() = " << _preCadEdgesIDsPeriodicityVector.size());
+ if (! _preCadEdgesIDsPeriodicityVector.empty()) {
+ MESSAGE("INTO PRECAD EDGES PERIODICITY");
+ for (std::size_t i=0; i < _preCadEdgesIDsPeriodicityVector.size(); i++){
+ std::vector<int> theEdge1_ids = _preCadEdgesIDsPeriodicityVector[i].shape1IDs;
+ std::vector<int> theEdge2_ids = _preCadEdgesIDsPeriodicityVector[i].shape2IDs;
+ // Use the address of the first element of the vector to initialise the array
+ int* theEdge1_ids_c = &theEdge1_ids[0];
+ int* theEdge2_ids_c = &theEdge2_ids[0];
+
+ std::ostringstream o;
+ o << "_preCadEdgesIDsPeriodicityVector[" << i << "] = [";
+ for (std::size_t j=0; j < theEdge1_ids.size(); j++)
+ o << theEdge1_ids[j] << ", ";
+ o << "], [";
+ for (std::size_t j=0; j < theEdge2_ids.size(); j++)
+ o << theEdge2_ids[j] << ", ";
+ o << "]";
+ MESSAGE(o.str());
+ MESSAGE("theEdge1_ids.size(): " << theEdge1_ids.size());
+ MESSAGE("theEdge2_ids.size(): " << theEdge2_ids.size());
+
+ if (_preCadEdgesIDsPeriodicityVector[i].theSourceVerticesCoords.empty())
+ {
+ // If no source points, call peridoicity without transformation function
+ MESSAGE("periodicity without transformation function");
+ meshgems_cad_periodicity_transformation_t periodicity_transformation = NULL;
+ status = cad_add_edge_multiple_periodicity_with_transformation_function(c, theEdge1_ids_c, theEdge1_ids.size(),
+ theEdge2_ids_c, theEdge2_ids.size(), periodicity_transformation, NULL);
+ if(status != STATUS_OK)
+ cout << "cad_add_edge_multiple_periodicity_with_transformation_function failed with error code " << status << "\n";
+ }
+ else
+ {
+ // get the transformation vertices
+ MESSAGE("periodicity with transformation vertices");
+ double* theSourceVerticesCoords_c = &_preCadEdgesIDsPeriodicityVector[i].theSourceVerticesCoords[0];
+ double* theTargetVerticesCoords_c = &_preCadEdgesIDsPeriodicityVector[i].theTargetVerticesCoords[0];
+ int nbSourceVertices = _preCadEdgesIDsPeriodicityVector[i].theSourceVerticesCoords.size()/3;
+ int nbTargetVertices = _preCadEdgesIDsPeriodicityVector[i].theTargetVerticesCoords.size()/3;
+
+ MESSAGE("nbSourceVertices: " << nbSourceVertices << ", nbTargetVertices: " << nbTargetVertices);
+
+ status = cad_add_edge_multiple_periodicity_with_transformation_function_by_points(c, theEdge1_ids_c, theEdge1_ids.size(),
+ theEdge2_ids_c, theEdge2_ids.size(), theSourceVerticesCoords_c, nbSourceVertices, theTargetVerticesCoords_c, nbTargetVertices);
+ if(status != STATUS_OK)
+ cout << "cad_add_edge_multiple_periodicity_with_transformation_function_by_points failed with error code " << status << "\n";
+ else
+ MESSAGE("cad_add_edge_multiple_periodicity_with_transformation_function_by_points succeeded.\n");
+ }
}
+
+ MESSAGE("END PRECAD EDGES PERIODICITY");
}
+ if (! _facesIDsPeriodicityVector.empty()){
+ MESSAGE("INTO FACE PERIODICITY");
+ for (std::size_t i=0; i < _facesIDsPeriodicityVector.size(); i++){
+ int theFace1 = _facesIDsPeriodicityVector[i].first;
+ int theFace2 = _facesIDsPeriodicityVector[i].second;
+ MESSAGE("_facesIDsPeriodicityVector[" << i << "] = (" << theFace1 << ", " << theFace2 << ")");
+ status = cad_add_face_periodicity(c, theFace1, theFace2);
+ if(status != STATUS_OK){
+ cout << "cad_add_face_periodicity failed with error code " << status << "\n";
+ }
+ }
+ MESSAGE("END FACE PERIODICITY");
+ }
+
+
+ if (! _edgesIDsPeriodicityVector.empty()){
+ MESSAGE("INTO EDGE PERIODICITY");
+ for (std::size_t i=0; i < _edgesIDsPeriodicityVector.size(); i++){
+ int theFace1 = _edgesIDsPeriodicityVector[i].theFace1ID;
+ int theEdge1 = _edgesIDsPeriodicityVector[i].theEdge1ID;
+ int theFace2 = _edgesIDsPeriodicityVector[i].theFace2ID;
+ int theEdge2 = _edgesIDsPeriodicityVector[i].theEdge2ID;
+ int edge_orientation = _edgesIDsPeriodicityVector[i].edge_orientation;
+ MESSAGE("_edgesIDsPeriodicityVector[" << i << "] = (" << theFace1 << ", " << theEdge1 << ", " << theFace2 << ", " << theEdge2 << ", " << edge_orientation << ")");
+ status = cad_add_edge_periodicity(c, theFace1, theEdge1, theFace2, theEdge2, edge_orientation);
+ if(status != STATUS_OK){
+ cout << "cad_add_edge_periodicity failed with error code " << status << "\n";
+ }
+ }
+ MESSAGE("END EDGE PERIODICITY");
+ }
+
+ if (! _verticesIDsPeriodicityVector.empty()){
+ MESSAGE("INTO VERTEX PERIODICITY");
+ for (std::size_t i=0; i < _verticesIDsPeriodicityVector.size(); i++){
+ int theEdge1 = _verticesIDsPeriodicityVector[i].theEdge1ID;
+ int theVertex1 = _verticesIDsPeriodicityVector[i].theVertex1ID;
+ int theEdge2 = _verticesIDsPeriodicityVector[i].theEdge2ID;
+ int theVertex2 = _verticesIDsPeriodicityVector[i].theVertex2ID;
+ MESSAGE("_verticesIDsPeriodicityVector[" << i << "] = (" << theEdge1 << ", " << theVertex1 << ", " << theEdge2 << ", " << theVertex2 << ")");
+ status = cad_add_point_periodicity(c, theEdge1, theVertex1, theEdge2, theVertex2);
+ if(status != STATUS_OK){
+ cout << "cad_add_vertex_periodicity failed with error code " << status << "\n";
+ }
+ }
+ MESSAGE("END VERTEX PERIODICITY");
+ }
+
+ ////
if (use_precad) {
+ MESSAGE("use_precad");
/* Now launch the PreCAD process */
status = precad_process(pcs);
if(status != STATUS_OK){
- cout << "PreCAD processing failed with error code " << status << "\n";
+ // TODO: raise an error if status < 0.
+ cout << "================ WARNING =================== \n";
+ stringstream msg;
+ msg << "PreCAD processing failed with error code " << status << "\n";
+ msg << *mcud._error;
+ cout << msg.str();
+ cout << "============================================ \n";
+ // the text of _comment is set in message_cb by mcud->_error
+ // => No need to append msg to _comment
+ if (status > 0)
+ {
+ // TODO: fix the SIGSEGV of COMPERR_WARNING with 2 launches
+ error(COMPERR_WARNING, _comment);
+ }
+ if (status < 0)
+ {
+ error(_comment);
+ }
}
else {
// retrieve the pre-processed CAD object
+
+ // dcad
+ cleandc = precad_new_dcad(pcs);
+ if(!cleandc){
+ cout << "Unable to retrieve PreCAD result on dcad \n";
+ }
+ else
+ cout << "PreCAD processing successfull on dcad \n";
+
+ // cad
cleanc = precad_new_cad(pcs);
if(!cleanc){
- cout << "Unable to retrieve PreCAD result \n";
+ cout << "Unable to retrieve PreCAD result on cad \n";
}
- cout << "PreCAD processing successfull \n";
+ else
+ cout << "PreCAD processing successfull on cad \n";
// #if BLSURF_VERSION_LONG >= "3.1.1"
// /* We can now get the updated sizemaps (if any) */
precad_session_delete(pcs);
}
- cadsurf_data_set_dcad(css, dcad);
+ if (cleandc) {
+ cout << "Give the pre-processed dcad object to the current MG-CADSurf session \n";
+ cadsurf_data_set_dcad(css, cleandc);
+ }
+ else {
+ // Use the original one
+ cadsurf_data_set_dcad(css, dcad);
+ }
+
if (cleanc) {
- // Give the pre-processed CAD object to the current BLSurf session
+ // Give the pre-processed CAD object to the current MG-CADSurf session
+ cout << "Give the pre-processed CAD object to the current MG-CADSurf session \n";
cadsurf_data_set_cad(css, cleanc);
}
else {
if ( _comment.empty() )
_comment = "Exception in cadsurf_compute_mesh()";
}
- if ( status != STATUS_OK) {
- // There was an error while meshing
- error(_comment);
- }
-
- PyGILState_Release(gstate);
std::cout << std::endl;
std::cout << "End of Surface Mesh generation" << std::endl;
if (_hypothesis)
GMFFileName = _hypothesis->GetGMFFile();
if (GMFFileName != "") {
- // bool GMFFileMode = _hypothesis->GetGMFFileMode();
- bool asciiFound = (GMFFileName.find(".mesh",GMFFileName.length()-5) != std::string::npos);
+ bool asciiFound = (GMFFileName.find(".mesh", GMFFileName.length()-5) != std::string::npos);
bool binaryFound = (GMFFileName.find(".meshb",GMFFileName.length()-6) != std::string::npos);
if (!asciiFound && !binaryFound)
GMFFileName.append(".mesh");
evquad = (integer *)mesh_calloc_generic_buffer(msh);
tags_buff = (integer*)mesh_calloc_generic_buffer(msh);
- SMDS_MeshNode** nodes = new SMDS_MeshNode*[nv+1];
- bool* tags = new bool[nv+1];
+ std::vector<const SMDS_MeshNode*> nodes(nv+1);
+ std::vector<bool> tags(nv+1);
/* enumerated vertices */
for(int iv=1;iv<=nv;iv++) {
mesh_get_vertex_coordinates(msh, iv, xyz);
mesh_get_vertex_tag(msh, iv, &tag);
// Issue 0020656. Use vertex coordinates
+ nodes[iv] = NULL;
if ( tag > 0 && tag <= pmap.Extent() ) {
TopoDS_Vertex v = TopoDS::Vertex(pmap(tag));
double tol = BRep_Tool::Tolerance( v );
xyz[0] = p.X(), xyz[1] = p.Y(), xyz[2] = p.Z();
else
tag = 0; // enforced or attracted vertex
+ nodes[iv] = SMESH_Algo::VertexNode( v, meshDS );
}
- nodes[iv] = meshDS->AddNode(xyz[0], xyz[1], xyz[2]);
+ if ( !nodes[iv] )
+ nodes[iv] = meshDS->AddNode(xyz[0], xyz[1], xyz[2]);
// Create group of enforced vertices if requested
BLSURFPlugin_Hypothesis::TEnfVertexCoords projVertex;
// the last of the two initial tags (else the output tag is out of emap and hasn't any meaning)
mesh_get_composite_tag_definition(msh, tag, &nb_tag, tags_buff);
if(nb_tag > 1)
- tag=tags_buff[nb_tag-1];
-
+ tag=tags_buff[nb_tag-1];
+ if ( tag > emap.Extent() )
+ {
+ std::cerr << "MG-CADSurf BUG:::: Edge tag " << tag
+ << " more than nb CAD egdes (" << emap.Extent() << ")" << std::endl;
+ continue;
+ }
if (tags[vtx[0]]) {
Set_NodeOnEdge(meshDS, nodes[vtx[0]], emap(tag));
tags[vtx[0]] = false;
mesh_get_triangle_extra_vertices(msh, it, &type, evtri);
mesh_get_triangle_tag(msh, it, &tag);
if (tags[vtx[0]]) {
- meshDS->SetNodeOnFace(nodes[vtx[0]], TopoDS::Face(fmap(tag)));
+ meshDS->SetNodeOnFace(nodes[vtx[0]], tag);
tags[vtx[0]] = false;
};
if (tags[vtx[1]]) {
- meshDS->SetNodeOnFace(nodes[vtx[1]], TopoDS::Face(fmap(tag)));
+ meshDS->SetNodeOnFace(nodes[vtx[1]], tag);
tags[vtx[1]] = false;
};
if (tags[vtx[2]]) {
- meshDS->SetNodeOnFace(nodes[vtx[2]], TopoDS::Face(fmap(tag)));
+ meshDS->SetNodeOnFace(nodes[vtx[2]], tag);
tags[vtx[2]] = false;
};
if (type == MESHGEMS_MESH_ELEMENT_TYPE_TRIA6) {
// QUADRATIC TRIANGLE
if (tags[evtri[0]]) {
- meshDS->SetNodeOnFace(nodes[evtri[0]], TopoDS::Face(fmap(tag)));
+ meshDS->SetNodeOnFace(nodes[evtri[0]], tag);
tags[evtri[0]] = false;
}
if (tags[evtri[1]]) {
- meshDS->SetNodeOnFace(nodes[evtri[1]], TopoDS::Face(fmap(tag)));
+ meshDS->SetNodeOnFace(nodes[evtri[1]], tag);
tags[evtri[1]] = false;
}
if (tags[evtri[2]]) {
- meshDS->SetNodeOnFace(nodes[evtri[2]], TopoDS::Face(fmap(tag)));
+ meshDS->SetNodeOnFace(nodes[evtri[2]], tag);
tags[evtri[2]] = false;
}
tri = meshDS->AddFace(nodes[vtx[0]], nodes[vtx[1]], nodes[vtx[2]],
else {
tri = helper.AddFace(nodes[vtx[0]], nodes[vtx[1]], nodes[vtx[2]]);
}
- meshDS->SetMeshElementOnShape(tri, TopoDS::Face(fmap(tag)));
+ meshDS->SetMeshElementOnShape(tri, tag);
}
/* enumerate quadrangles */
mesh_get_quadrangle_extra_vertices(msh, it, &type, evquad);
mesh_get_quadrangle_tag(msh, it, &tag);
if (tags[vtx[0]]) {
- meshDS->SetNodeOnFace(nodes[vtx[0]], TopoDS::Face(fmap(tag)));
+ meshDS->SetNodeOnFace(nodes[vtx[0]], tag);
tags[vtx[0]] = false;
};
if (tags[vtx[1]]) {
- meshDS->SetNodeOnFace(nodes[vtx[1]], TopoDS::Face(fmap(tag)));
+ meshDS->SetNodeOnFace(nodes[vtx[1]], tag);
tags[vtx[1]] = false;
};
if (tags[vtx[2]]) {
- meshDS->SetNodeOnFace(nodes[vtx[2]], TopoDS::Face(fmap(tag)));
+ meshDS->SetNodeOnFace(nodes[vtx[2]], tag);
tags[vtx[2]] = false;
};
if (tags[vtx[3]]) {
- meshDS->SetNodeOnFace(nodes[vtx[3]], TopoDS::Face(fmap(tag)));
+ meshDS->SetNodeOnFace(nodes[vtx[3]], tag);
tags[vtx[3]] = false;
};
if (type == MESHGEMS_MESH_ELEMENT_TYPE_QUAD9) {
// QUADRATIC QUADRANGLE
std::cout << "This is a quadratic quadrangle" << std::endl;
if (tags[evquad[0]]) {
- meshDS->SetNodeOnFace(nodes[evquad[0]], TopoDS::Face(fmap(tag)));
+ meshDS->SetNodeOnFace(nodes[evquad[0]], tag);
tags[evquad[0]] = false;
}
if (tags[evquad[1]]) {
- meshDS->SetNodeOnFace(nodes[evquad[1]], TopoDS::Face(fmap(tag)));
+ meshDS->SetNodeOnFace(nodes[evquad[1]], tag);
tags[evquad[1]] = false;
}
if (tags[evquad[2]]) {
- meshDS->SetNodeOnFace(nodes[evquad[2]], TopoDS::Face(fmap(tag)));
+ meshDS->SetNodeOnFace(nodes[evquad[2]], tag);
tags[evquad[2]] = false;
}
if (tags[evquad[3]]) {
- meshDS->SetNodeOnFace(nodes[evquad[3]], TopoDS::Face(fmap(tag)));
+ meshDS->SetNodeOnFace(nodes[evquad[3]], tag);
tags[evquad[3]] = false;
}
if (tags[evquad[4]]) {
- meshDS->SetNodeOnFace(nodes[evquad[4]], TopoDS::Face(fmap(tag)));
+ meshDS->SetNodeOnFace(nodes[evquad[4]], tag);
tags[evquad[4]] = false;
}
quad = meshDS->AddFace(nodes[vtx[0]], nodes[vtx[1]], nodes[vtx[2]], nodes[vtx[3]],
else {
quad = helper.AddFace(nodes[vtx[0]], nodes[vtx[1]], nodes[vtx[2]], nodes[vtx[3]]);
}
- meshDS->SetMeshElementOnShape(quad, TopoDS::Face(fmap(tag)));
+ meshDS->SetMeshElementOnShape(quad, tag);
}
/* release the mesh object, the rest is released by cleaner */
cadsurf_data_regain_mesh(css, msh);
- delete [] nodes;
- delete [] tags;
-
- if ( needMerge ) // sew mesh computed by BLSURF with pre-existing mesh
+ if ( needMerge ) // sew mesh computed by MG-CADSurf with pre-existing mesh
{
SMESH_MeshEditor editor( &aMesh );
SMESH_MeshEditor::TListOfListOfNodes nodeGroupsToMerge;
TIDSortedElemSet segementsOnEdge;
- TIDSortedNodeSet nodesOnEdge;
TSubMeshSet::iterator smIt;
SMESHDS_SubMesh* smDS;
- typedef SMDS_StdIterator< const SMDS_MeshNode*, SMDS_NodeIteratorPtr > TNodeIterator;
- double tol;
- // merge nodes on EDGE's with ones computed by BLSURF
+ // merge nodes on EDGE's with ones computed by MG-CADSurf
for ( smIt = mergeSubmeshes.begin(); smIt != mergeSubmeshes.end(); ++smIt )
{
if (! (smDS = *smIt) ) continue;
sm->SetIsAlwaysComputed( true );
// Set error to FACE's w/o elements
- for ( int i = 1; i <= fmap.Extent(); ++i )
+ SMESH_ComputeErrorName err = COMPERR_ALGO_FAILED;
+ if ( _comment.empty() && status == STATUS_OK )
{
- SMESH_subMesh* sm = aMesh.GetSubMesh( fmap(i) );
+ err = COMPERR_WARNING;
+ _comment = "No mesh elements assigned to a face";
+ }
+ bool badFaceFound = false;
+ for (TopExp_Explorer face_iter(aShape,TopAbs_FACE);face_iter.More();face_iter.Next())
+ {
+ TopoDS_Face f = TopoDS::Face(face_iter.Current());
+ SMESH_subMesh* sm = aMesh.GetSubMesh( f );
if ( !sm->GetSubMeshDS() || sm->GetSubMeshDS()->NbElements() == 0 )
- sm->GetComputeError().reset
- ( new SMESH_ComputeError( COMPERR_ALGO_FAILED, _comment, this ));
+ {
+ sm->GetComputeError().reset( new SMESH_ComputeError( err, _comment, this ));
+ badFaceFound = true;
+ }
+ }
+ if ( err == COMPERR_WARNING )
+ {
+ _comment.clear();
+ }
+ if ( status != STATUS_OK && !badFaceFound ) {
+ error(_comment);
}
// Issue 0019864. On DebianSarge, FE signals do not obey to OSD::SetSignal(false)
-#ifndef WNT
+#ifndef WIN32
if ( oldFEFlags > 0 )
feenableexcept( oldFEFlags );
feclearexcept( FE_ALL_EXCEPT );
*/
//================================================================================
-#ifdef WITH_SMESH_CANCEL_COMPUTE
void BLSURFPlugin_BLSURF::CancelCompute()
{
_compute_canceled = true;
}
-#endif
//=============================================================================
/*!
*/
//=============================================================================
-void BLSURFPlugin_BLSURF::Set_NodeOnEdge(SMESHDS_Mesh* meshDS, SMDS_MeshNode* node, const TopoDS_Shape& ed) {
+void BLSURFPlugin_BLSURF::Set_NodeOnEdge(SMESHDS_Mesh* meshDS, const SMDS_MeshNode* node, const TopoDS_Shape& ed) {
const TopoDS_Edge edge = TopoDS::Edge(ed);
gp_Pnt pnt(node->X(), node->Y(), node->Z());
Standard_Real p1 = 1.0;
TopLoc_Location loc;
Handle(Geom_Curve) curve = BRep_Tool::Curve(edge, loc, p0, p1);
+ if ( curve.IsNull() )
+ {
+ // issue 22499. Node at a sphere apex
+ meshDS->SetNodeOnEdge(node, edge, p0);
+ return;
+ }
if ( !loc.IsIdentity() ) pnt.Transform( loc.Transformation().Inverted() );
GeomAPI_ProjectPointOnCurve proj(pnt, curve, p0, p1);
meshDS->MoveNode( node, curve_pnt.X(), curve_pnt.Y(), curve_pnt.Z() );
}
}
-// GProp_GProps LProps;
-// BRepGProp::LinearProperties(ed, LProps);
-// double lg = (double)LProps.Mass();
meshDS->SetNodeOnEdge(node, edge, pa);
}
status_t curv_fun(real t, real *uv, real *dt, real *dtt, void *user_data)
{
/* t is given. It contains the t (time) 1D parametric coordintaes
- of the point PreCAD/BLSurf is querying on the curve */
+ of the point PreCAD/MG-CADSurf is querying on the curve */
- /* user_data identifies the edge PreCAD/BLSurf is querying
+ /* user_data identifies the edge PreCAD/MG-CADSurf is querying
* (see cad_edge_new later in this example) */
const Geom2d_Curve*pargeo = (const Geom2d_Curve*) user_data;
if (uv){
- /* BLSurf is querying the function evaluation */
+ /* MG-CADSurf is querying the function evaluation */
gp_Pnt2d P;
P=pargeo->Value(t);
uv[0]=P.X(); uv[1]=P.Y();
real *duu, real *duv, real *dvv, void *user_data)
{
/* uv[2] is given. It contains the u,v coordinates of the point
- * PreCAD/BLSurf is querying on the surface */
+ * PreCAD/MG-CADSurf is querying on the surface */
- /* user_data identifies the face PreCAD/BLSurf is querying (see
+ /* user_data identifies the face PreCAD/MG-CADSurf is querying (see
* cad_face_new later in this example)*/
const Geom_Surface* geometry = (const Geom_Surface*) user_data;
status_t size_on_surface(integer face_id, real *uv, real *size, void *user_data)
{
- //MESSAGE("size_on_surface")
+ TId2ClsAttractorVec::iterator f2attVec;
if (FaceId2PythonSmp.count(face_id) != 0){
- //MESSAGE("A size map is used to calculate size on face : "<<face_id)
- PyObject * pyresult = NULL;
- PyObject* new_stderr = NULL;
assert(Py_IsInitialized());
PyGILState_STATE gstate;
gstate = PyGILState_Ensure();
- pyresult = PyObject_CallFunction(FaceId2PythonSmp[face_id],(char*)"(f,f)",uv[0],uv[1]);
+ PyObject* pyresult = PyObject_CallFunction(FaceId2PythonSmp[face_id],(char*)"(f,f)",uv[0],uv[1]);
real result;
if ( pyresult != NULL) {
result = PyFloat_AsDouble(pyresult);
else{
fflush(stderr);
string err_description="";
- new_stderr = newPyStdOut(err_description);
+ PyObject* new_stderr = newPyStdOut(err_description);
+ PyObject* old_stderr = PySys_GetObject((char*)"stderr");
+ Py_INCREF(old_stderr);
PySys_SetObject((char*)"stderr", new_stderr);
PyErr_Print();
- PySys_SetObject((char*)"stderr", PySys_GetObject((char*)"__stderr__"));
+ PySys_SetObject((char*)"stderr", old_stderr);
Py_DECREF(new_stderr);
MESSAGE("Can't evaluate f(" << uv[0] << "," << uv[1] << ")" << " error is " << err_description);
result = *((real*)user_data);
*size = result;
PyGILState_Release(gstate);
}
- else if (FaceIndex2ClassAttractor.count(face_id) !=0 && !FaceIndex2ClassAttractor[face_id]->Empty()){
+ else if (( f2attVec = FaceIndex2ClassAttractor.find(face_id)) != FaceIndex2ClassAttractor.end() && !f2attVec->second.empty()){
// MESSAGE("attractor used on face :"<<face_id)
// MESSAGE("List of attractor is not empty")
// MESSAGE("Attractor empty : "<< FaceIndex2ClassAttractor[face_id]->Empty())
- real result = FaceIndex2ClassAttractor[face_id]->GetSize(uv[0],uv[1]);
+ real result = 0;
+ result = 1e100;
+ std::vector< BLSURFPlugin_Attractor* > & attVec = f2attVec->second;
+ for ( size_t i = 0; i < attVec.size(); ++i )
+ {
+ //result += attVec[i]->GetSize(uv[0],uv[1]);
+ result = Min( result, attVec[i]->GetSize(uv[0],uv[1]));
+ }
+ //*size = result / attVec.size(); // mean of sizes defined by all attractors
*size = result;
}
else {
status_t size_on_edge(integer edge_id, real t, real *size, void *user_data)
{
if (EdgeId2PythonSmp.count(edge_id) != 0){
- PyObject * pyresult = NULL;
- PyObject* new_stderr = NULL;
assert(Py_IsInitialized());
PyGILState_STATE gstate;
gstate = PyGILState_Ensure();
- pyresult = PyObject_CallFunction(EdgeId2PythonSmp[edge_id],(char*)"(f)",t);
+ PyObject* pyresult = PyObject_CallFunction(EdgeId2PythonSmp[edge_id],(char*)"(f)",t);
real result;
if ( pyresult != NULL) {
result = PyFloat_AsDouble(pyresult);
else{
fflush(stderr);
string err_description="";
- new_stderr = newPyStdOut(err_description);
+ PyObject* new_stderr = newPyStdOut(err_description);
+ PyObject* old_stderr = PySys_GetObject((char*)"stderr");
+ Py_INCREF(old_stderr);
PySys_SetObject((char*)"stderr", new_stderr);
PyErr_Print();
- PySys_SetObject((char*)"stderr", PySys_GetObject((char*)"__stderr__"));
+ PySys_SetObject((char*)"stderr", old_stderr);
Py_DECREF(new_stderr);
MESSAGE("Can't evaluate f(" << t << ")" << " error is " << err_description);
result = *((real*)user_data);
status_t size_on_vertex(integer point_id, real *size, void *user_data)
{
if (VertexId2PythonSmp.count(point_id) != 0){
- PyObject * pyresult = NULL;
- PyObject* new_stderr = NULL;
assert(Py_IsInitialized());
PyGILState_STATE gstate;
gstate = PyGILState_Ensure();
- pyresult = PyObject_CallFunction(VertexId2PythonSmp[point_id],(char*)"");
+ PyObject* pyresult = PyObject_CallFunction(VertexId2PythonSmp[point_id],(char*)"");
real result;
if ( pyresult != NULL) {
result = PyFloat_AsDouble(pyresult);
else {
fflush(stderr);
string err_description="";
- new_stderr = newPyStdOut(err_description);
+ PyObject* new_stderr = newPyStdOut(err_description);
+ PyObject* old_stderr = PySys_GetObject((char*)"stderr");
+ Py_INCREF(old_stderr);
PySys_SetObject((char*)"stderr", new_stderr);
PyErr_Print();
- PySys_SetObject((char*)"stderr", PySys_GetObject((char*)"__stderr__"));
+ PySys_SetObject((char*)"stderr", old_stderr);
Py_DECREF(new_stderr);
MESSAGE("Can't evaluate f()" << " error is " << err_description);
result = *((real*)user_data);
}
/*
- * The following function will be called for PreCAD/BLSurf message
+ * The following function will be called for PreCAD/MG-CADSurf message
* printing. See context_set_message_callback (later in this
* template) for how to set user_data.
*/
message_get_description(msg, &desc);
string err( desc );
message_cb_user_data * mcud = (message_cb_user_data*)user_data;
- if ( errnumber < 0 || err.find("license") != string::npos ) {
+ // Get all the error message and some warning messages related to license and periodicity
+ if ( errnumber < 0 ||
+ err.find("license" ) != string::npos ||
+ err.find("periodicity") != string::npos )
+ {
// remove ^A from the tail
int len = strlen( desc );
while (len > 0 && desc[len-1] != '\n')
len--;
mcud->_error->append( desc, len );
}
- else if ( mcud->_verbosity > 0 ) {
- std::cout << desc << std::endl;
+ else {
+ if ( errnumber == 3009001 )
+ * mcud->_progress = atof( desc + 11 ) / 100.;
+ if ( mcud->_verbosity > 0 )
+ std::cout << desc << std::endl;
}
return STATUS_OK;
}
-/* This is the interrupt callback. PreCAD/BLSurf will call this
+/* This is the interrupt callback. PreCAD/MG-CADSurf will call this
* function regularily. See the file meshgems/interrupt.h
*/
status_t interrupt_cb(integer *interrupt_status, void *user_data)
{
integer you_want_to_continue = 1;
-#ifdef WITH_SMESH_CANCEL_COMPUTE
BLSURFPlugin_BLSURF* tmp = (BLSURFPlugin_BLSURF*)user_data;
you_want_to_continue = !tmp->computeCanceled();
-#endif
if(you_want_to_continue)
{
*interrupt_status = INTERRUPT_CONTINUE;
return STATUS_OK;
}
- else /* you want to stop BLSurf */
+ else /* you want to stop MG-CADSurf */
{
*interrupt_status = INTERRUPT_STOP;
return STATUS_ERROR;