if plugin in plugin_list: continue
# add paths of plugin
- plugin_list.append(plugin)
+ plugin_list.append(plugin)
if not os.environ.has_key("SALOME_"+plugin+"Resources"):
resource_path = os.path.join(plugin_root,"share",salome_subdir,"resources",plugin.lower())
os.environ["SALOME_"+plugin+"Resources"] = resource_path
resource_path_list.append( resource_path )
add_path(os.path.join(plugin_root,get_lib_dir(),python_version, "site-packages",salome_subdir), "PYTHONPATH")
add_path(os.path.join(plugin_root,get_lib_dir(),salome_subdir), "PYTHONPATH")
-
+
if sys.platform == "win32":
add_path(os.path.join(plugin_root,get_lib_dir(),salome_subdir), "PATH")
add_path(os.path.join(plugin_root,"bin",salome_subdir), "PYTHONPATH")
break
os.environ["SMESH_MeshersList"] = ":".join(plugin_list)
os.environ["SalomeAppConfig"] = os.environ["SalomeAppConfig"] + psep + psep.join(resource_path_list)
-
elif comType == 2:
for i in range(a.number):
ind = a.indexes[ii]
- print ind
+ print ind
ii = ii+1
- print ii
+ print ii
i1 = a.indexes[ii]
ii = ii+1
i2 = a.indexes[ii]
- print i2
+ print i2
ii = ii+1
- print "ii", ii
+ print "ii", ii
i3 = a.indexes[ii]
- print i3
+ print i3
#ii = ii+1
ii = ii+1
print "AddTriangle %i - %i %i %i" % (ind, i1, i2, i3)
myStudyBuilder = myStudy.NewBuilder()
if myStudyBuilder is None:
- raise RuntimeError, " Null myStudyBuilder"
+ raise RuntimeError, " Null myStudyBuilder"
father = myStudy.FindComponent("SMESH")
if father is None:
- father = myStudyBuilder.NewComponent("SMESH")
- FName = myStudyBuilder.FindOrCreateAttribute(father, "AttributeName")
- Comp = modulecatalog.GetComponent("SMESH")
- FName.SetValue(Comp._get_componentusername())
- aPixmap = myStudyBuilder.FindOrCreateAttribute(father, "AttributePixMap")
- aPixmap.SetPixMap("ICON_OBJBROWSER_Mesh")
+ father = myStudyBuilder.NewComponent("SMESH")
+ FName = myStudyBuilder.FindOrCreateAttribute(father, "AttributeName")
+ Comp = modulecatalog.GetComponent("SMESH")
+ FName.SetValue(Comp._get_componentusername())
+ aPixmap = myStudyBuilder.FindOrCreateAttribute(father, "AttributePixMap")
+ aPixmap.SetPixMap("ICON_OBJBROWSER_Mesh")
myStudyBuilder.DefineComponentInstance(father,smesh)
Tag_HypothesisRoot = 1
Tag_AlgorithmsRoot = 2
-
+
Tag_RefOnShape = 1
Tag_RefOnAppliedHypothesis = 2
Tag_RefOnAppliedAlgorithms = 3
-
+
Tag_SubMeshOnVertex = 4
Tag_SubMeshOnEdge = 5
Tag_SubMeshOnFace = 6
#------------------------------------------------------------
def Init():
- pass
+ pass
#------------------------------------------------------------
def AddNewMesh(IOR):
- # VSR: added temporarily - objects are published automatically by the engine
- aSO = myStudy.FindObjectIOR( IOR )
- if aSO is not None:
- return aSO.GetID()
- # VSR ######################################################################
-
- res,HypothesisRoot = mySComponentMesh.FindSubObject ( Tag_HypothesisRoot )
- if HypothesisRoot is None or res == 0:
- HypothesisRoot = myStudyBuilder.NewObjectToTag(mySComponentMesh, Tag_HypothesisRoot)
- aName = myStudyBuilder.FindOrCreateAttribute(HypothesisRoot, "AttributeName")
- aName.SetValue("Hypotheses")
- aPixmap = myStudyBuilder.FindOrCreateAttribute(HypothesisRoot, "AttributePixMap")
- aPixmap.SetPixMap( "mesh_tree_hypo.png" )
- aSelAttr = myStudyBuilder.FindOrCreateAttribute(HypothesisRoot, "AttributeSelectable")
- aSelAttr.SetSelectable(0)
-
- res, AlgorithmsRoot = mySComponentMesh.FindSubObject (Tag_AlgorithmsRoot)
- if AlgorithmsRoot is None or res == 0:
- AlgorithmsRoot = myStudyBuilder.NewObjectToTag (mySComponentMesh, Tag_AlgorithmsRoot)
- aName = myStudyBuilder.FindOrCreateAttribute(AlgorithmsRoot, "AttributeName")
- aName.SetValue("Algorithms")
- aPixmap = myStudyBuilder.FindOrCreateAttribute(AlgorithmsRoot, "AttributePixMap")
- aPixmap.SetPixMap( "mesh_tree_algo.png" )
- aSelAttr = myStudyBuilder.FindOrCreateAttribute(AlgorithmsRoot, "AttributeSelectable")
- aSelAttr.SetSelectable(0)
-
- HypothesisRoot = HypothesisRoot._narrow(SALOMEDS.SObject)
- newMesh = myStudyBuilder.NewObject(mySComponentMesh)
- aPixmap = myStudyBuilder.FindOrCreateAttribute(newMesh, "AttributePixMap")
- aPixmap.SetPixMap( "mesh_tree_mesh.png" )
- anIOR = myStudyBuilder.FindOrCreateAttribute(newMesh, "AttributeIOR")
- anIOR.SetValue(IOR)
- return newMesh.GetID()
-
-#------------------------------------------------------------
+ # VSR: added temporarily - objects are published automatically by the engine
+ aSO = myStudy.FindObjectIOR( IOR )
+ if aSO is not None:
+ return aSO.GetID()
+ # VSR ######################################################################
+
+ res,HypothesisRoot = mySComponentMesh.FindSubObject ( Tag_HypothesisRoot )
+ if HypothesisRoot is None or res == 0:
+ HypothesisRoot = myStudyBuilder.NewObjectToTag(mySComponentMesh, Tag_HypothesisRoot)
+ aName = myStudyBuilder.FindOrCreateAttribute(HypothesisRoot, "AttributeName")
+ aName.SetValue("Hypotheses")
+ aPixmap = myStudyBuilder.FindOrCreateAttribute(HypothesisRoot, "AttributePixMap")
+ aPixmap.SetPixMap( "mesh_tree_hypo.png" )
+ aSelAttr = myStudyBuilder.FindOrCreateAttribute(HypothesisRoot, "AttributeSelectable")
+ aSelAttr.SetSelectable(0)
+
+ res, AlgorithmsRoot = mySComponentMesh.FindSubObject (Tag_AlgorithmsRoot)
+ if AlgorithmsRoot is None or res == 0:
+ AlgorithmsRoot = myStudyBuilder.NewObjectToTag (mySComponentMesh, Tag_AlgorithmsRoot)
+ aName = myStudyBuilder.FindOrCreateAttribute(AlgorithmsRoot, "AttributeName")
+ aName.SetValue("Algorithms")
+ aPixmap = myStudyBuilder.FindOrCreateAttribute(AlgorithmsRoot, "AttributePixMap")
+ aPixmap.SetPixMap( "mesh_tree_algo.png" )
+ aSelAttr = myStudyBuilder.FindOrCreateAttribute(AlgorithmsRoot, "AttributeSelectable")
+ aSelAttr.SetSelectable(0)
+
+ HypothesisRoot = HypothesisRoot._narrow(SALOMEDS.SObject)
+ newMesh = myStudyBuilder.NewObject(mySComponentMesh)
+ aPixmap = myStudyBuilder.FindOrCreateAttribute(newMesh, "AttributePixMap")
+ aPixmap.SetPixMap( "mesh_tree_mesh.png" )
+ anIOR = myStudyBuilder.FindOrCreateAttribute(newMesh, "AttributeIOR")
+ anIOR.SetValue(IOR)
+ return newMesh.GetID()
+
+#------------------------------------------------------------
def AddNewHypothesis(IOR):
- # VSR: added temporarily - objects are published automatically by the engine
- aSO = myStudy.FindObjectIOR( IOR )
- if aSO is not None:
- return aSO.GetID()
- # VSR ######################################################################
-
- res, HypothesisRoot = mySComponentMesh.FindSubObject (Tag_HypothesisRoot)
- if HypothesisRoot is None or res == 0:
- HypothesisRoot = myStudyBuilder.NewObjectToTag (mySComponentMesh, Tag_HypothesisRoot)
- aName = myStudyBuilder.FindOrCreateAttribute(HypothesisRoot, "AttributeName")
- aName.SetValue("Hypotheses")
- aSelAttr = myStudyBuilder.FindOrCreateAttribute(HypothesisRoot, "AttributeSelectable")
- aSelAttr.SetSelectable(0)
- aPixmap = myStudyBuilder.FindOrCreateAttribute(HypothesisRoot, "AttributePixMap")
- aPixmap.SetPixMap( "mesh_tree_hypo.png" )
-
- # Add New Hypothesis
- newHypo = myStudyBuilder.NewObject(HypothesisRoot)
- aPixmap = myStudyBuilder.FindOrCreateAttribute(newHypo, "AttributePixMap")
- H = orb.string_to_object(IOR)
- aType = H.GetName()
- aPixmap.SetPixMap( "mesh_tree_hypo.png_" + aType )
- anIOR = myStudyBuilder.FindOrCreateAttribute(newHypo, "AttributeIOR")
- anIOR.SetValue(IOR)
- return newHypo.GetID()
+ # VSR: added temporarily - objects are published automatically by the engine
+ aSO = myStudy.FindObjectIOR( IOR )
+ if aSO is not None:
+ return aSO.GetID()
+ # VSR ######################################################################
+
+ res, HypothesisRoot = mySComponentMesh.FindSubObject (Tag_HypothesisRoot)
+ if HypothesisRoot is None or res == 0:
+ HypothesisRoot = myStudyBuilder.NewObjectToTag (mySComponentMesh, Tag_HypothesisRoot)
+ aName = myStudyBuilder.FindOrCreateAttribute(HypothesisRoot, "AttributeName")
+ aName.SetValue("Hypotheses")
+ aSelAttr = myStudyBuilder.FindOrCreateAttribute(HypothesisRoot, "AttributeSelectable")
+ aSelAttr.SetSelectable(0)
+ aPixmap = myStudyBuilder.FindOrCreateAttribute(HypothesisRoot, "AttributePixMap")
+ aPixmap.SetPixMap( "mesh_tree_hypo.png" )
+
+ # Add New Hypothesis
+ newHypo = myStudyBuilder.NewObject(HypothesisRoot)
+ aPixmap = myStudyBuilder.FindOrCreateAttribute(newHypo, "AttributePixMap")
+ H = orb.string_to_object(IOR)
+ aType = H.GetName()
+ aPixmap.SetPixMap( "mesh_tree_hypo.png_" + aType )
+ anIOR = myStudyBuilder.FindOrCreateAttribute(newHypo, "AttributeIOR")
+ anIOR.SetValue(IOR)
+ return newHypo.GetID()
#------------------------------------------------------------
def AddNewAlgorithms(IOR):
- # VSR: added temporarily - objects are published automatically by the engine
- aSO = myStudy.FindObjectIOR( IOR )
- if aSO is not None:
- return aSO.GetID()
- # VSR ######################################################################
-
- res, AlgorithmsRoot = mySComponentMesh.FindSubObject (Tag_AlgorithmsRoot)
- if AlgorithmsRoot is None or res == 0:
- AlgorithmsRoot = myStudyBuilde.NewObjectToTag (mySComponentMesh, Tag_AlgorithmsRoot)
- aName = myStudyBuilder.FindOrCreateAttribute(AlgorithmsRoot, "AttributeName")
- aName.SetValue("Algorithms")
- aSelAttr = myStudyBuilder.FindOrCreateAttribute(AlgorithmsRoot, "AttributeSelectable")
- aSelAttr.SetSelectable(0)
- aPixmap = myStudyBuilder.FindOrCreateAttribute(AlgorithmsRoot, "AttributePixMap")
- aPixmap.SetPixMap( "mesh_tree_algo.png" )
+ # VSR: added temporarily - objects are published automatically by the engine
+ aSO = myStudy.FindObjectIOR( IOR )
+ if aSO is not None:
+ return aSO.GetID()
+ # VSR ######################################################################
+
+ res, AlgorithmsRoot = mySComponentMesh.FindSubObject (Tag_AlgorithmsRoot)
+ if AlgorithmsRoot is None or res == 0:
+ AlgorithmsRoot = myStudyBuilde.NewObjectToTag (mySComponentMesh, Tag_AlgorithmsRoot)
+ aName = myStudyBuilder.FindOrCreateAttribute(AlgorithmsRoot, "AttributeName")
+ aName.SetValue("Algorithms")
+ aSelAttr = myStudyBuilder.FindOrCreateAttribute(AlgorithmsRoot, "AttributeSelectable")
+ aSelAttr.SetSelectable(0)
+ aPixmap = myStudyBuilder.FindOrCreateAttribute(AlgorithmsRoot, "AttributePixMap")
+ aPixmap.SetPixMap( "mesh_tree_algo.png" )
# Add New Algorithms
- newHypo = myStudyBuilder.NewObject(AlgorithmsRoot)
- aPixmap = myStudyBuilder.FindOrCreateAttribute(newHypo, "AttributePixMap")
- aPixmap = anAttr._narrow(SALOMEDS.AttributePixMap)
- H = orb.string_to_object(IOR)
- aType = H.GetName(); #QString in fact
- aPixmap.SetPixMap( "mesh_tree_algo.png_" + aType )
- anIOR = myStudyBuilder.FindOrCreateAttribute(newHypo, "AttributeIOR")
- anIOR.SetValue(IOR)
- return newHypo.GetID()
+ newHypo = myStudyBuilder.NewObject(AlgorithmsRoot)
+ aPixmap = myStudyBuilder.FindOrCreateAttribute(newHypo, "AttributePixMap")
+ aPixmap = anAttr._narrow(SALOMEDS.AttributePixMap)
+ H = orb.string_to_object(IOR)
+ aType = H.GetName(); #QString in fact
+ aPixmap.SetPixMap( "mesh_tree_algo.png_" + aType )
+ anIOR = myStudyBuilder.FindOrCreateAttribute(newHypo, "AttributeIOR")
+ anIOR.SetValue(IOR)
+ return newHypo.GetID()
#------------------------------------------------------------
def SetShape(ShapeEntry, MeshEntry):
- SO_MorSM = myStudy.FindObjectID( MeshEntry )
- SO_GeomShape = myStudy.FindObjectID( ShapeEntry )
+ SO_MorSM = myStudy.FindObjectID( MeshEntry )
+ SO_GeomShape = myStudy.FindObjectID( ShapeEntry )
- if SO_MorSM is not None and SO_GeomShape is not None :
- # VSR: added temporarily - shape reference is published automatically by the engine
- res, Ref = SO_MorSM.FindSubObject( Tag_RefOnShape )
- if res == 1 :
- return
- # VSR ######################################################################
-
- SO = myStudyBuilder.NewObjectToTag (SO_MorSM, Tag_RefOnShape)
- myStudyBuilder.Addreference (SO,SO_GeomShape)
+ if SO_MorSM is not None and SO_GeomShape is not None :
+ # VSR: added temporarily - shape reference is published automatically by the engine
+ res, Ref = SO_MorSM.FindSubObject( Tag_RefOnShape )
+ if res == 1 :
+ return
+ # VSR ######################################################################
+
+ SO = myStudyBuilder.NewObjectToTag (SO_MorSM, Tag_RefOnShape)
+ myStudyBuilder.Addreference (SO,SO_GeomShape)
#------------------------------------------------------------
def SetHypothesis(Mesh_Or_SubMesh_Entry, Hypothesis_Entry):
- SO_MorSM = myStudy.FindObjectID( Mesh_Or_SubMesh_Entry )
- SO_Hypothesis = myStudy.FindObjectID( Hypothesis_Entry )
-
- if SO_MorSM is not None and SO_Hypothesis is not None :
-
- #Find or Create Applied Hypothesis root
- res, AHR = SO_MorSM.FindSubObject (Tag_RefOnAppliedHypothesis)
- if AHR is None or res == 0:
- AHR = myStudyBuilder.NewObjectToTag (SO_MorSM, Tag_RefOnAppliedHypothesis)
- aName = myStudyBuilder.FindOrCreateAttribute(AHR, "AttributeName")
-
- # The same name as in SMESH_Mesh_i::AddHypothesis() ##################
- aName.SetValue("Applied hypotheses")
-
- aSelAttr = myStudyBuilder.FindOrCreateAttribute(AHR, "AttributeSelectable")
- aSelAttr.SetSelectable(0)
- aPixmap = myStudyBuilder.FindOrCreateAttribute(AHR, "AttributePixMap")
- aPixmap.SetPixMap( "mesh_tree_hypo.png" )
-
- # VSR: added temporarily - reference to applied hypothesis is published automatically by the engine
- else :
- it = myStudy.NewChildIterator(AHR)
- while it.More() :
- res, Ref = it.Value().ReferencedObject()
- if res and Ref is not None and Ref.GetID() == Hypothesis_Entry :
- return
- it.Next()
- # VSR ######################################################################
-
- SO = myStudyBuilder.NewObject(AHR)
- myStudyBuilder.Addreference (SO,SO_Hypothesis)
+ SO_MorSM = myStudy.FindObjectID( Mesh_Or_SubMesh_Entry )
+ SO_Hypothesis = myStudy.FindObjectID( Hypothesis_Entry )
+
+ if SO_MorSM is not None and SO_Hypothesis is not None :
+
+ #Find or Create Applied Hypothesis root
+ res, AHR = SO_MorSM.FindSubObject (Tag_RefOnAppliedHypothesis)
+ if AHR is None or res == 0:
+ AHR = myStudyBuilder.NewObjectToTag (SO_MorSM, Tag_RefOnAppliedHypothesis)
+ aName = myStudyBuilder.FindOrCreateAttribute(AHR, "AttributeName")
+
+ # The same name as in SMESH_Mesh_i::AddHypothesis() ##################
+ aName.SetValue("Applied hypotheses")
+
+ aSelAttr = myStudyBuilder.FindOrCreateAttribute(AHR, "AttributeSelectable")
+ aSelAttr.SetSelectable(0)
+ aPixmap = myStudyBuilder.FindOrCreateAttribute(AHR, "AttributePixMap")
+ aPixmap.SetPixMap( "mesh_tree_hypo.png" )
+
+ # VSR: added temporarily - reference to applied hypothesis is published automatically by the engine
+ else :
+ it = myStudy.NewChildIterator(AHR)
+ while it.More() :
+ res, Ref = it.Value().ReferencedObject()
+ if res and Ref is not None and Ref.GetID() == Hypothesis_Entry :
+ return
+ it.Next()
+ # VSR ######################################################################
+
+ SO = myStudyBuilder.NewObject(AHR)
+ myStudyBuilder.Addreference (SO,SO_Hypothesis)
#------------------------------------------------------------
def SetAlgorithms(Mesh_Or_SubMesh_Entry, Algorithms_Entry):
SO_MorSM = myStudy.FindObjectID( Mesh_Or_SubMesh_Entry )
SO_Algorithms = myStudy.FindObjectID( Algorithms_Entry )
- if SO_MorSM != None and SO_Algorithms != None :
- #Find or Create Applied Algorithms root
- res, AHR = SO_MorSM.FindSubObject (Tag_RefOnAppliedAlgorithms)
- if AHR is None or res == 0:
- AHR = myStudyBuilder.NewObjectToTag (SO_MorSM, Tag_RefOnAppliedAlgorithms)
- aName = myStudyBuilder.FindOrCreateAttribute(AHR, "AttributeName")
-
- # The same name as in SMESH_Mesh_i::AddHypothesis() ##################
- aName.SetValue("Applied algorithms")
-
- aSelAttr = myStudyBuilder.FindOrCreateAttribute(AHR, "AttributeSelectable")
- aSelAttr.SetSelectable(0)
- aPixmap = myStudyBuilder.FindOrCreateAttribute(AHR, "AttributePixMap")
- aPixmap.SetPixMap( "mesh_tree_algo.png" )
-
- # VSR: added temporarily - reference to applied hypothesis is published automatically by the engine
- else :
- it = myStudy.NewChildIterator(AHR)
- while it.More() :
- res, Ref = it.Value().ReferencedObject()
- if res and Ref is not None and Ref.GetID() == Algorithms_Entry :
- return
- it.Next()
- # VSR ######################################################################
-
- SO = myStudyBuilder.NewObject(AHR)
- myStudyBuilder.Addreference (SO,SO_Algorithms)
-
+ if SO_MorSM != None and SO_Algorithms != None :
+ #Find or Create Applied Algorithms root
+ res, AHR = SO_MorSM.FindSubObject (Tag_RefOnAppliedAlgorithms)
+ if AHR is None or res == 0:
+ AHR = myStudyBuilder.NewObjectToTag (SO_MorSM, Tag_RefOnAppliedAlgorithms)
+ aName = myStudyBuilder.FindOrCreateAttribute(AHR, "AttributeName")
+
+ # The same name as in SMESH_Mesh_i::AddHypothesis() ##################
+ aName.SetValue("Applied algorithms")
+
+ aSelAttr = myStudyBuilder.FindOrCreateAttribute(AHR, "AttributeSelectable")
+ aSelAttr.SetSelectable(0)
+ aPixmap = myStudyBuilder.FindOrCreateAttribute(AHR, "AttributePixMap")
+ aPixmap.SetPixMap( "mesh_tree_algo.png" )
+
+ # VSR: added temporarily - reference to applied hypothesis is published automatically by the engine
+ else :
+ it = myStudy.NewChildIterator(AHR)
+ while it.More() :
+ res, Ref = it.Value().ReferencedObject()
+ if res and Ref is not None and Ref.GetID() == Algorithms_Entry :
+ return
+ it.Next()
+ # VSR ######################################################################
+
+ SO = myStudyBuilder.NewObject(AHR)
+ myStudyBuilder.Addreference (SO,SO_Algorithms)
+
#------------------------------------------------------------
def UnSetHypothesis( Applied_Hypothesis_Entry ):
- SO_Applied_Hypothesis = myStudy.FindObjectID( Applied_Hypothesis_Entry )
- if SO_Applied_Hypothesis :
- myStudyBuilder.RemoveObject(SO_Applied_Hypothesis)
-
+ SO_Applied_Hypothesis = myStudy.FindObjectID( Applied_Hypothesis_Entry )
+ if SO_Applied_Hypothesis :
+ myStudyBuilder.RemoveObject(SO_Applied_Hypothesis)
+
#------------------------------------------------------------
def AddSubMesh ( SO_Mesh_Entry, SM_IOR, ST):
- # VSR: added temporarily - objects are published automatically by the engine
- aSO = myStudy.FindObjectIOR( SM_IOR )
- if aSO is not None:
- return aSO.GetID()
- # VSR ######################################################################
-
- SO_Mesh = myStudy.FindObjectID( SO_Mesh_Entry )
- if ( SO_Mesh ) :
-
- if ST == ShapeType["COMPSOLID"] :
- Tag_Shape = Tag_SubMeshOnSolid
- Name = "SubMeshes on Solid"
- elif ST == ShapeType["FACE"] :
- Tag_Shape = Tag_SubMeshOnFace
- Name = "SubMeshes on Face"
- elif ST == ShapeType["EDGE"] :
- Tag_Shape = Tag_SubMeshOnEdge
- Name = "SubMeshes on Edge"
- elif ST == ShapeType["VERTEX"] :
- Tag_Shape = Tag_SubMeshOnVertex
- Name = "SubMeshes on Vertex"
- else :
- Tag_Shape = Tag_SubMeshOnCompound
- Name = "SubMeshes on Compound"
-
- res, SubmeshesRoot = SO_Mesh.FindSubObject (Tag_Shape)
- if SubmeshesRoot is None or res == 0:
- SubmeshesRoot = myStudyBuilder.NewObjectToTag (SO_Mesh, Tag_Shape)
- aName = myStudyBuilder.FindOrCreateAttribute(SubmeshesRoot, "AttributeName")
- aName.SetValue(Name)
- aSelAttr = myStudyBuilder.FindOrCreateAttribute(SubmeshesRoot, "AttributeSelectable")
- aSelAttr.SetSelectable(0)
-
- SO = myStudyBuilder.NewObject (SubmeshesRoot)
- anIOR = myStudyBuilder.FindOrCreateAttribute(SO, "AttributeIOR")
- anIOR.SetValue(SM_IOR)
- return SO.GetID()
-
- return None
+ # VSR: added temporarily - objects are published automatically by the engine
+ aSO = myStudy.FindObjectIOR( SM_IOR )
+ if aSO is not None:
+ return aSO.GetID()
+ # VSR ######################################################################
+
+ SO_Mesh = myStudy.FindObjectID( SO_Mesh_Entry )
+ if ( SO_Mesh ) :
+
+ if ST == ShapeType["COMPSOLID"] :
+ Tag_Shape = Tag_SubMeshOnSolid
+ Name = "SubMeshes on Solid"
+ elif ST == ShapeType["FACE"] :
+ Tag_Shape = Tag_SubMeshOnFace
+ Name = "SubMeshes on Face"
+ elif ST == ShapeType["EDGE"] :
+ Tag_Shape = Tag_SubMeshOnEdge
+ Name = "SubMeshes on Edge"
+ elif ST == ShapeType["VERTEX"] :
+ Tag_Shape = Tag_SubMeshOnVertex
+ Name = "SubMeshes on Vertex"
+ else :
+ Tag_Shape = Tag_SubMeshOnCompound
+ Name = "SubMeshes on Compound"
+
+ res, SubmeshesRoot = SO_Mesh.FindSubObject (Tag_Shape)
+ if SubmeshesRoot is None or res == 0:
+ SubmeshesRoot = myStudyBuilder.NewObjectToTag (SO_Mesh, Tag_Shape)
+ aName = myStudyBuilder.FindOrCreateAttribute(SubmeshesRoot, "AttributeName")
+ aName.SetValue(Name)
+ aSelAttr = myStudyBuilder.FindOrCreateAttribute(SubmeshesRoot, "AttributeSelectable")
+ aSelAttr.SetSelectable(0)
+
+ SO = myStudyBuilder.NewObject (SubmeshesRoot)
+ anIOR = myStudyBuilder.FindOrCreateAttribute(SO, "AttributeIOR")
+ anIOR.SetValue(SM_IOR)
+ return SO.GetID()
+
+ return None
#------------------------------------------------------------
def AddSubMeshOnShape (Mesh_Entry, GeomShape_Entry, SM_IOR, ST) :
- # VSR: added temporarily - objects are published automatically by the engine
- aSO = myStudy.FindObjectIOR( SM_IOR )
- if aSO is not None:
- return aSO.GetID()
- # VSR ######################################################################
- SO_GeomShape = myStudy.FindObjectID( GeomShape_Entry )
- if SO_GeomShape != None :
- SM_Entry = AddSubMesh (Mesh_Entry,SM_IOR,ST)
- SO_SM = myStudy.FindObjectID( SM_Entry )
+ # VSR: added temporarily - objects are published automatically by the engine
+ aSO = myStudy.FindObjectIOR( SM_IOR )
+ if aSO is not None:
+ return aSO.GetID()
+ # VSR ######################################################################
+ SO_GeomShape = myStudy.FindObjectID( GeomShape_Entry )
+ if SO_GeomShape != None :
+ SM_Entry = AddSubMesh (Mesh_Entry,SM_IOR,ST)
+ SO_SM = myStudy.FindObjectID( SM_Entry )
- if SO_SM != None :
- SetShape (GeomShape_Entry, SM_Entry)
- return SM_Entry
+ if SO_SM != None :
+ SetShape (GeomShape_Entry, SM_Entry)
+ return SM_Entry
- return None
+ return None
#------------------------------------------------------------
def SetName(Entry, Name):
- SO = myStudy.FindObjectID( Entry )
- if SO != None :
- aName = myStudyBuilder.FindOrCreateAttribute(SO, "AttributeName")
- aName.SetValue(Name)
+ SO = myStudy.FindObjectID( Entry )
+ if SO != None :
+ aName = myStudyBuilder.FindOrCreateAttribute(SO, "AttributeName")
+ aName.SetValue(Name)
# export the methods of smeshBuilder
if smesh:
for k in dir( smesh ):
- if k[0] == '_': continue
- globals()[k] = getattr( smesh, k )
+ if k[0] == '_': continue
+ globals()[k] = getattr( smesh, k )
del k
pass
TODO:
The following changes in your scripts are required to avoid this message:
-replace
+replace
-------
import smesh, SMESH
you also need to modify some lines where smeshBuilder is used instead of smesh
-algo=smesh.xxxx ==> algo=smeshBuilder.xxxx
+algo=smesh.xxxx ==> algo=smeshBuilder.xxxx
See also SMESH User's Guide for more details
global created
#print "--------------- smeshbuilder __init__ ---", created
if not created:
- created = True
- SMESH._objref_SMESH_Gen.__init__(self)
+ created = True
+ SMESH._objref_SMESH_Gen.__init__(self)
## Dump component to the Python script
# This method overrides IDL function to allow default values for the parameters.
def GetSubShapesId( self, theMainObject, theListOfSubObjects ):
return SMESH._objref_SMESH_Gen.GetSubShapesId(self,theMainObject, theListOfSubObjects)
- ## Create a pattern mapper.
+ ## Create a pattern mapper.
# @return an instance of SMESH_Pattern
#
# <a href="../tui_modifying_meshes_page.html#tui_pattern_mapping">Example of Patterns usage</a>
raise TypeError, "The Threshold should be an integer or SMESH.EntityType."
pass
pass
-
+
elif CritType == FT_GroupColor:
# Check the Threshold
try:
global doLcc
engine = instance
if engine is None:
- doLcc = True
+ doLcc = True
smeshInst = smeshBuilder()
assert isinstance(smeshInst,smeshBuilder), "Smesh engine class is %s but should be smeshBuilder.smeshBuilder. Import salome.smesh.smeshBuilder before creating the instance."%smeshInst.__class__
smeshInst.init_smesh(study)
#self.mesh.UnRegister()
pass
pass
-
+
## Initialize the Mesh object from an instance of SMESH_Mesh interface
# @param theMesh a SMESH_Mesh object
# @ingroup l2_construct
# @ingroup l2_construct
def Clear(self, refresh=False):
self.mesh.Clear()
- if ( salome.sg.hasDesktop() and
+ if ( salome.sg.hasDesktop() and
salome.myStudyManager.GetStudyByID( self.mesh.GetStudyId() ) ):
smeshgui = salome.ImportComponentGUI("SMESH")
smeshgui.Init(self.mesh.GetStudyId())
# - 3D in the rest cases.<br>
# If @a autoDimension is @c False, the space dimension is always 3.
# @param fields list of GEOM fields defined on the shape to mesh.
- # @param geomAssocFields each character of this string means a need to export a
+ # @param geomAssocFields each character of this string means a need to export a
# corresponding field; correspondence between fields and characters is following:
# - 'v' stands for "_vertices _" field;
# - 'e' stands for "_edges _" field;
# ----------------------
## Create an empty mesh group
- # @param elementType the type of elements in the group; either of
+ # @param elementType the type of elements in the group; either of
# (SMESH.NODE, SMESH.EDGE, SMESH.FACE, SMESH.VOLUME)
# @param name the name of the mesh group
# @return SMESH_Group
# the name is the same as the geometrical group name
# @param grp a geometrical group, a vertex, an edge, a face or a solid
# @param name the name of the mesh group
- # @param typ the type of elements in the group; either of
+ # @param typ the type of elements in the group; either of
# (SMESH.NODE, SMESH.EDGE, SMESH.FACE, SMESH.VOLUME). If not set, it is
# automatically detected by the type of the geometry
# @return SMESH_GroupOnGeom
## Create a mesh group with given \a name based on the \a filter which
## is a special type of group dynamically updating it's contents during
## mesh modification
- # @param typ the type of elements in the group; either of
+ # @param typ the type of elements in the group; either of
# (SMESH.NODE, SMESH.EDGE, SMESH.FACE, SMESH.VOLUME).
# @param name the name of the mesh group
# @param filter the filter defining group contents
## Create a mesh group by the given ids of elements
# @param groupName the name of the mesh group
- # @param elementType the type of elements in the group; either of
+ # @param elementType the type of elements in the group; either of
# (SMESH.NODE, SMESH.EDGE, SMESH.FACE, SMESH.VOLUME).
# @param elemIDs either the list of ids, group, sub-mesh, or filter
# @return SMESH_Group
## Get the list of groups existing in the mesh in the order
# of creation (starting from the oldest one)
- # @param elemType type of elements the groups contain; either of
+ # @param elemType type of elements the groups contain; either of
# (SMESH.ALL, SMESH.NODE, SMESH.EDGE, SMESH.FACE, SMESH.VOLUME);
# by default groups of elements of all types are returned
# @return a sequence of SMESH_GroupBase
## Find groups by name and type
# @param name name of the group of interest
- # @param elemType type of elements the groups contain; either of
+ # @param elemType type of elements the groups contain; either of
# (SMESH.ALL, SMESH.NODE, SMESH.EDGE, SMESH.FACE, SMESH.VOLUME);
# by default one group of any type of elements is returned
# if elemType == SMESH.ALL then all groups of any type are returned
if group.GetName() == name:
if elemType is None:
return [group]
- if ( elemType == SMESH.ALL or
+ if ( elemType == SMESH.ALL or
group.GetType() == elemType ):
groups.append( group )
return groups
# @return an instance of SMESH_Group
# @ingroup l2_grps_operon
def UnionListOfGroups(self, groups, name):
- return self.mesh.UnionListOfGroups(groups, name)
+ return self.mesh.UnionListOfGroups(groups, name)
## Prodice an intersection of two groups.
# A new group is created. All mesh elements that are common
# @return an instance of SMESH_Group
# @ingroup l2_grps_operon
def IntersectListOfGroups(self, groups, name):
- return self.mesh.IntersectListOfGroups(groups, name)
+ return self.mesh.IntersectListOfGroups(groups, name)
## Produce a cut of two groups.
# A new group is created. All mesh elements that are present in
##
# Create a standalone group of entities basing on nodes of other groups.
# \param groups - list of reference groups, sub-meshes or filters, of any type.
- # \param elemType - a type of elements to include to the new group; either of
+ # \param elemType - a type of elements to include to the new group; either of
# (SMESH.NODE, SMESH.EDGE, SMESH.FACE, SMESH.VOLUME).
# \param name - a name of the new group.
# \param nbCommonNodes - a criterion of inclusion of an element to the new group
def Add0DElement( self, IDOfNode, DuplicateElements=True ):
return self.editor.Add0DElement( IDOfNode, DuplicateElements )
- ## Create 0D elements on all nodes of the given elements except those
+ ## Create 0D elements on all nodes of the given elements except those
# nodes on which a 0D element already exists.
# @param theObject an object on whose nodes 0D elements will be created.
# It can be mesh, sub-mesh, group, list of element IDs or a holder
# and/or found on nodes of \a theObject.
# @param DuplicateElements to add one more 0D element to a node or not
# @return an object (a new group or a temporary SMESH_IDSource) holding
- # IDs of new and/or found 0D elements. IDs of 0D elements
+ # IDs of new and/or found 0D elements. IDs of 0D elements
# can be retrieved from the returned object by calling GetIDs()
# @ingroup l2_modif_add
def Add0DElementsToAllNodes(self, theObject, theGroupName="", DuplicateElements=False):
# @param x the X coordinate of a point
# @param y the Y coordinate of a point
# @param z the Z coordinate of a point
- # @param elementType type of elements to find; either of
+ # @param elementType type of elements to find; either of
# (SMESH.NODE, SMESH.EDGE, SMESH.FACE, SMESH.VOLUME); SMESH.ALL type
# means elements of any type excluding nodes, discrete and 0D elements.
# @param meshPart a part of mesh (group, sub-mesh) to search within
if error and error.comment:
print error.comment
return error
-
+
## Convert the mesh from quadratic to ordinary,
# deletes old quadratic elements, \n replacing
# them with ordinary mesh elements with the same id.
return mesh, group
##
- # @brief Create missing boundary elements around either the whole mesh or
+ # @brief Create missing boundary elements around either the whole mesh or
# groups of elements
# @param dimension - defines type of boundary elements to create, either of
# { SMESH.BND_2DFROM3D, SMESH.BND_1DFROM3D, SMESH.BND_1DFROM2D }
# @param groupName - a name of group to store all boundary elements in,
# "" means not to create the group
- # @param meshName - a name of a new mesh, which is a copy of the initial
+ # @param meshName - a name of a new mesh, which is a copy of the initial
# mesh + created boundary elements; "" means not to create the new mesh
# @param toCopyAll - if true, the whole initial mesh will be copied into
# the new mesh else only boundary elements will be copied into the new mesh
if ( isinstance( thePoint, list )):
thePoint = PointStruct( thePoint[0], thePoint[1], thePoint[2] )
if ( isinstance( theScaleFact, float )):
- theScaleFact = [theScaleFact]
+ theScaleFact = [theScaleFact]
if ( isinstance( theScaleFact, int )):
- theScaleFact = [ float(theScaleFact)]
+ theScaleFact = [ float(theScaleFact)]
self.mesh.SetParameters(thePoint.parameters)
if ( isinstance( thePoint, list )):
thePoint = PointStruct( thePoint[0], thePoint[1], thePoint[2] )
if ( isinstance( theScaleFact, float )):
- theScaleFact = [theScaleFact]
+ theScaleFact = [theScaleFact]
if ( isinstance( theScaleFact, int )):
- theScaleFact = [ float(theScaleFact)]
+ theScaleFact = [ float(theScaleFact)]
self.mesh.SetParameters(thePoint.parameters)
mesh = self.editor.ScaleMakeMesh(theObject, thePoint, theScaleFact,
# @ingroup l2_modif_trsf
def FindCoincidentFreeBorders (self, tolerance=0.):
return self.editor.FindCoincidentFreeBorders( tolerance )
-
+
## Sew FreeBorder's of each group
# @param freeBorders either a SMESH.CoincidentFreeBorders structure or a list of lists
# where each enclosed list contains node IDs of a group of coincident free
def ClearLastCreated(self):
self.editor.ClearLastCreated()
- ## Create duplicates of given elements, i.e. create new elements based on the
+ ## Create duplicates of given elements, i.e. create new elements based on the
# same nodes as the given ones.
# @param theElements - container of elements to duplicate. It can be a Mesh,
# sub-mesh, group, filter or a list of element IDs. If \a theElements is
# @param theGroupName - a name of group to contain the generated elements.
# If a group with such a name already exists, the new elements
# are added to the existng group, else a new group is created.
- # If \a theGroupName is empty, new elements are not added
+ # If \a theGroupName is empty, new elements are not added
# in any group.
# @return a group where the new elements are added. None if theGroupName == "".
# @ingroup l2_modif_duplicat
# @return TRUE if operation has been completed successfully, FALSE otherwise
# @ingroup l2_modif_duplicat
def DoubleNodesOnGroupBoundaries(self, theDomains, createJointElems, onAllBoundaries=False ):
- return self.editor.DoubleNodesOnGroupBoundaries( theDomains, createJointElems, onAllBoundaries )
+ return self.editor.DoubleNodesOnGroupBoundaries( theDomains, createJointElems, onAllBoundaries )
## Double nodes on some external faces and create flat elements.
# Flat elements are mainly used by some types of mechanic calculations.
- #
+ #
# Each group of the list must be constituted of faces.
# Triangles are transformed in prisms, and quadrangles in hexahedrons.
# @param theGroupsOfFaces - list of groups of faces
# @ingroup l2_modif_duplicat
def CreateFlatElementsOnFacesGroups(self, theGroupsOfFaces ):
return self.editor.CreateFlatElementsOnFacesGroups( theGroupsOfFaces )
-
+
## identify all the elements around a geom shape, get the faces delimiting the hole
#
def CreateHoleSkin(self, radius, theShape, groupName, theNodesCoords):
try:
exec( "from salome.%s.%s import *" % (pluginName, pluginBuilderName))
except Exception, e:
- from salome_utils import verbose
- if verbose(): print "Exception while loading %s: %s" % ( pluginBuilderName, e )
+ from salome_utils import verbose
+ if verbose(): print "Exception while loading %s: %s" % ( pluginBuilderName, e )
continue
exec( "from salome.%s import %s" % (pluginName, pluginBuilderName))
plugin = eval( pluginBuilderName )
#
def Message (code) :
- import sys
- MessageString = { 1 : lambda x: "Successfully created \n",
- 2 : lambda x: "Fatal: Incorrect input \n",
- 3 : lambda x: "Fatal: Overlapping objects detected \n",
- 4 : lambda x: "Fatal: Incompatible object type with neighbouring objects" }[code](str(code))
- print MessageString
- #if code > 1 : sys.exit()
- return 1
-
+ import sys
+ MessageString = { 1 : lambda x: "Successfully created \n",
+ 2 : lambda x: "Fatal: Incorrect input \n",
+ 3 : lambda x: "Fatal: Overlapping objects detected \n",
+ 4 : lambda x: "Fatal: Incompatible object type with neighbouring objects" }[code](str(code))
+ print MessageString
+ #if code > 1 : sys.exit()
+ return 1
from MacObject import *
import Config, GenFunctions
-def CentralUnrefine (X0 , Y0 , DX , DY , Orientation, **args ) :
-
- DirPar = {'SN' : lambda : ['NW', 'NE', 'EW', 'NW', 'SN', 'SN', 'NE', 'WE'],
- 'NS' : lambda : ['SE', 'SW', 'WE', 'SE', 'NS', 'NS', 'SW', 'EW'],
- 'EW' : lambda : ['NW', 'SW', 'SN', 'NW', 'EW', 'EW', 'SW', 'NS'],
- 'WE' : lambda : ['SE', 'NE', 'NS', 'SE', 'WE', 'WE', 'NE', 'SN'], }[Orientation]()
-
- CoefVer = {'SN' : lambda : 1.,
- 'NS' : lambda : -1.,
- 'EW' : lambda : 0.,
- 'WE' : lambda : 0., }[Orientation]()
-
- CoefHor = {'SN' : lambda : 0.,
- 'NS' : lambda : 0.,
- 'EW' : lambda : -1.,
- 'WE' : lambda : 1., }[Orientation]()
-
-
- MacObject('CompBoxF',[(X0+CoefHor*DX/2,Y0+CoefVer*DY/2),(DX,DY)],['auto'],publish=0)
- ToLook1 = {'SN' : lambda : 2,
- 'NS' : lambda : 3,
- 'EW' : lambda : 1,
- 'WE' : lambda : 0, }[Orientation]()
-
- ToLook2 = {'SN' : lambda : 0,
- 'NS' : lambda : 0,
- 'EW' : lambda : 2,
- 'WE' : lambda : 2, }[Orientation]()
-
- ToLook3 = {'SN' : lambda : [0,1,2,3],
- 'NS' : lambda : [1,0,3,2],
- 'EW' : lambda : [3,2,1,0],
- 'WE' : lambda : [2,3,0,1], }[Orientation]()
-
- if args.__contains__('groups') :
- GroupNames = args['groups']
- else : GroupNames = [None, None, None, None, None, None]
-
- ExistingSegments = Config.ListObj[-1].DirectionalMeshParams[ToLook1]
- ObjIDs = Config.Connections[-1][ToLook1]
- RemoveLastObj()
-
- ExtensionSegments = math.ceil(ExistingSegments/12.)*12.
- Dmin = 1.E50
- Dmax = -1.E50
- for ObjID in ObjIDs :
- Boundaries = Config.ListObj[ObjID].Boundaries()
- if Boundaries[ToLook2] < Dmin : Dmin = Boundaries[ToLook2]
- if Boundaries[ToLook2+1] > Dmax : Dmax = Boundaries[ToLook2+1]
- dx = 0
- if ExtensionSegments > ExistingSegments :
- dn = (ExtensionSegments-ExistingSegments)/2.
- dx = dn*(Dmax-Dmin)/ExistingSegments
- #MacObject('CompBoxF',[(X0-CoefHor*dx/2+CoefVer*(-X0+Dmin-dx/2),Y0-CoefVer*dx/2+CoefHor*(-Y0+Dmin-dx/2)),(dx,dx)],[(dn,dn)],publish=0)
- #MacObject('CompBoxF',[(X0-CoefHor*dx/2+CoefVer*(-X0+Dmax+dx/2),Y0-CoefVer*dx/2+CoefHor*(-Y0+Dmax+dx/2)),(dx,dx)],[(dn,dn)],publish=0)
-
- BoxSide = (Dmax-Dmin+2*dx)/2.
-
- Obj = []
- Obj.append(MacObject('BoxAng32',[(X0+CoefHor*(BoxSide/2)+CoefVer*(-BoxSide/2),Y0+CoefVer*(BoxSide/2)+CoefHor*(-BoxSide/2)),(BoxSide,BoxSide)],[int(ExtensionSegments/6),DirPar[0]],groups=GroupArray(ToLook3[0],GroupNames[0])))
- Obj.append(MacObject('BoxAng32',[(X0+CoefHor*(BoxSide/2)+CoefVer*(BoxSide/2),Y0+CoefVer*(BoxSide/2)+CoefHor*(BoxSide/2)),(BoxSide,BoxSide)],[int(ExtensionSegments/6),DirPar[1]],groups=GroupArray(ToLook3[0],GroupNames[0])))
-
- NLevOpt = 0
- for NLevels in range (1,100) :
- DX1 = abs(CoefVer)*BoxSide*2.**(NLevels+1)+abs(CoefHor)*BoxSide*2.**(NLevels)
- DY1 = abs(CoefHor)*BoxSide*2.**(NLevels+1)+abs(CoefVer)*BoxSide*2.**(NLevels)
- if DX1 > DX or DY1 > DY :
- NLevOpt = NLevels-1
- DXinner = DX1/2.
- DYinner = DY1/2.
- break
-
- dummyArray = [DXinner,DYinner,DYinner,DXinner]
- D1inner = dummyArray[ToLook2] # = DXinner for SN and NS orientations
- D2inner = dummyArray[ToLook2+1] # = DYinner for SN and NS orientations
-
- dummyArray = [DX,DY,DY,DX]
- D1 = dummyArray[ToLook2] # = DX for SN and NS orientations
- D2 = dummyArray[ToLook2+1] # = DY for SN and NS orientations
-
- if D1inner < D1 :
- GN0a = GroupArray(ToLook3[0],GroupNames[1])
- GN0b = GroupArray(ToLook3[0],GroupNames[2])
- GN01 = GroupArray(ToLook3[0],GroupNames[1])
- GN02 = GroupArray(ToLook3[0],GroupNames[2])
- if D2inner < D2 :
- GN10 = [None,None,None,None]
- GN11 = [None,None,None,None]
- GN20 = [None,None,None,None]
- else :
- GN10 = GroupArray(ToLook3[1],GroupNames[3])
- GN11 = GroupArray(ToLook3[1],GroupNames[3])
- GN20 = GroupArray(ToLook3[1],GroupNames[3])
- else :
- GN0a = GroupArray(ToLook3[0],GroupNames[1])
- GN0b = GroupArray(ToLook3[0],GroupNames[2])
- GN01 = GroupArray([ToLook3[0],ToLook3[2]],[GroupNames[1],GroupNames[4]])
- GN02 = GroupArray([ToLook3[0],ToLook3[3]],[GroupNames[2],GroupNames[5]])
- if D2inner < D2 :
- GN10 = GroupArray(ToLook3[2],GroupNames[4])
- GN11 = GroupArray(ToLook3[3],GroupNames[5])
- GN20 = [None,None,None,None]
- else :
- GN10 = GroupArray([ToLook3[1],ToLook3[2]],[GroupNames[3],GroupNames[4]])
- GN11 = GroupArray([ToLook3[1],ToLook3[3]],[GroupNames[3],GroupNames[5]])
- GN20 = GroupArray(ToLook3[1],GroupNames[3])
-
- for N in range (1,NLevOpt+1):
- n=N-1
- D = BoxSide*(2.**n)
- if N < NLevOpt :
- Obj.append(MacObject('Box42' ,[(X0+D*(CoefHor*1/2-CoefVer*3/2) , Y0+D*(CoefVer*1/2-CoefHor*3/2) ) , (D,D)],['auto',DirPar[2]], groups=GN0a))
- Obj.append(MacObject('BoxAng32',[(X0+D*(CoefHor*3/2-CoefVer*3/2) , Y0+D*(CoefVer*3/2-CoefHor*3/2) ) , (D,D)],['auto',DirPar[3]]))
- Obj.append(MacObject('Box42' ,[(X0+D*(CoefHor*3/2-CoefVer*1/2) , Y0+D*(CoefVer*3/2-CoefHor*1/2) ) , (D,D)],['auto',DirPar[4]]))
- Obj.append(MacObject('Box42' ,[(X0+D*(CoefHor*3/2+CoefVer*1/2) , Y0+D*(CoefHor*1/2+CoefVer*3/2) ) , (D,D)],['auto',DirPar[5]]))
- Obj.append(MacObject('BoxAng32',[(X0+D*(CoefVer*3/2+CoefHor*3/2) , Y0+D*(CoefVer*3/2+CoefHor*3/2) ) , (D,D)],['auto',DirPar[6]]))
- Obj.append(MacObject('Box42' ,[(X0+D*(CoefVer*3/2+CoefHor*1/2) , Y0+D*(CoefHor*3/2+CoefVer*1/2) ) , (D,D)],['auto',DirPar[7]], groups=GN0b))
- else :
- Obj.append(MacObject('Box42' ,[(X0+D*(CoefHor*1/2-CoefVer*3/2) , Y0+D*(CoefVer*1/2-CoefHor*3/2) ) , (D,D)],['auto',DirPar[2]], groups=GN01))
- Obj.append(MacObject('BoxAng32',[(X0+D*(CoefHor*3/2-CoefVer*3/2) , Y0+D*(CoefVer*3/2-CoefHor*3/2) ) , (D,D)],['auto',DirPar[3]], groups=GN10))
- Obj.append(MacObject('Box42' ,[(X0+D*(CoefHor*3/2-CoefVer*1/2) , Y0+D*(CoefVer*3/2-CoefHor*1/2) ) , (D,D)],['auto',DirPar[4]], groups=GN20))
- Obj.append(MacObject('Box42' ,[(X0+D*(CoefHor*3/2+CoefVer*1/2) , Y0+D*(CoefHor*1/2+CoefVer*3/2) ) , (D,D)],['auto',DirPar[5]], groups=GN20))
- Obj.append(MacObject('BoxAng32',[(X0+D*(CoefVer*3/2+CoefHor*3/2) , Y0+D*(CoefVer*3/2+CoefHor*3/2) ) , (D,D)],['auto',DirPar[6]], groups=GN11))
- Obj.append(MacObject('Box42' ,[(X0+D*(CoefVer*3/2+CoefHor*1/2) , Y0+D*(CoefHor*3/2+CoefVer*1/2) ) , (D,D)],['auto',DirPar[7]], groups=GN02))
-
-
- if CoefVer and DX>DXinner :
- Obj.append(MacObject('CompBoxF',[(X0-CoefVer*0.25*(DX+DXinner),Y0+CoefVer*DYinner/2),((DX-DXinner)/2,DYinner)],['auto'], groups = GroupArray([ToLook3[0],ToLook3[2]],[GroupNames[1],GroupNames[4]])))
- Obj.append(MacObject('CompBoxF',[(X0+CoefVer*0.25*(DX+DXinner),Y0+CoefVer*DYinner/2),((DX-DXinner)/2,DYinner)],['auto'], groups = GroupArray([ToLook3[0],ToLook3[3]],[GroupNames[2],GroupNames[5]])))
- if DY>DYinner :
- Obj.append(MacObject('CompBoxF',[(X0-CoefVer*0.25*(DX+DXinner),Y0+CoefVer*(DY+DYinner)/2.),((DX-DXinner)/2,DY-DYinner)],['auto'], groups = GroupArray([ToLook3[1],ToLook3[2]],[GroupNames[3],GroupNames[4]])))
- Obj.append(MacObject('CompBoxF',[(X0+CoefVer*0.25*(DX+DXinner),Y0+CoefVer*(DY+DYinner)/2.),((DX-DXinner)/2,DY-DYinner)],['auto'], groups = GroupArray([ToLook3[1],ToLook3[3]],[GroupNames[3],GroupNames[5]])))
- Obj.append(MacObject('CompBoxF',[(X0,Y0+CoefVer*(DY+DYinner)/2.),(DXinner,DY-DYinner)],['auto'], groups = GroupArray(ToLook3[1],GroupNames[3])))
- elif CoefHor and DY>DYinner :
- Obj.append(MacObject('CompBoxF',[(X0+CoefHor*DXinner/2,Y0-CoefHor*0.25*(DY+DYinner)),(DXinner,(DY-DYinner)/2)],['auto'], groups = GroupArray([ToLook3[0],ToLook3[2]],[GroupNames[1],GroupNames[4]])))
- Obj.append(MacObject('CompBoxF',[(X0+CoefHor*DXinner/2,Y0+CoefHor*0.25*(DY+DYinner)),(DXinner,(DY-DYinner)/2)],['auto'], groups = GroupArray([ToLook3[0],ToLook3[3]],[GroupNames[2],GroupNames[5]])))
- if DX>DXinner :
- Obj.append(MacObject('CompBoxF',[(X0+CoefHor*(DX+DXinner)/2.,Y0-CoefHor*0.25*(DY+DYinner)),(DX-DXinner,(DY-DYinner)/2)],['auto'], groups = GroupArray([ToLook3[1],ToLook3[2]],[GroupNames[3],GroupNames[4]])))
- Obj.append(MacObject('CompBoxF',[(X0+CoefHor*(DX+DXinner)/2.,Y0+CoefHor*0.25*(DY+DYinner)),(DX-DXinner,(DY-DYinner)/2)],['auto'], groups = GroupArray([ToLook3[1],ToLook3[3]],[GroupNames[3],GroupNames[5]])))
- Obj.append(MacObject('CompBoxF',[(X0+CoefHor*(DX+DXinner)/2.,Y0),(DX-DXinner,DYinner)],['auto'], groups = GroupArray(ToLook3[1],GroupNames[3])))
- return Obj
-
-def RemoveLastObj() :
- Config.ListObj = Config.ListObj[:-1]
- Config.Connections = Config.Connections[:-1]
-
+def CentralUnrefine (X0 , Y0 , DX , DY , Orientation, **args ) :
+
+ DirPar = {'SN' : lambda : ['NW', 'NE', 'EW', 'NW', 'SN', 'SN', 'NE', 'WE'],
+ 'NS' : lambda : ['SE', 'SW', 'WE', 'SE', 'NS', 'NS', 'SW', 'EW'],
+ 'EW' : lambda : ['NW', 'SW', 'SN', 'NW', 'EW', 'EW', 'SW', 'NS'],
+ 'WE' : lambda : ['SE', 'NE', 'NS', 'SE', 'WE', 'WE', 'NE', 'SN'], }[Orientation]()
+
+ CoefVer = {'SN' : lambda : 1.,
+ 'NS' : lambda : -1.,
+ 'EW' : lambda : 0.,
+ 'WE' : lambda : 0., }[Orientation]()
+
+ CoefHor = {'SN' : lambda : 0.,
+ 'NS' : lambda : 0.,
+ 'EW' : lambda : -1.,
+ 'WE' : lambda : 1., }[Orientation]()
+
+
+ MacObject('CompBoxF',[(X0+CoefHor*DX/2,Y0+CoefVer*DY/2),(DX,DY)],['auto'],publish=0)
+ ToLook1 = {'SN' : lambda : 2,
+ 'NS' : lambda : 3,
+ 'EW' : lambda : 1,
+ 'WE' : lambda : 0, }[Orientation]()
+
+ ToLook2 = {'SN' : lambda : 0,
+ 'NS' : lambda : 0,
+ 'EW' : lambda : 2,
+ 'WE' : lambda : 2, }[Orientation]()
+
+ ToLook3 = {'SN' : lambda : [0,1,2,3],
+ 'NS' : lambda : [1,0,3,2],
+ 'EW' : lambda : [3,2,1,0],
+ 'WE' : lambda : [2,3,0,1], }[Orientation]()
+
+ if args.__contains__('groups') :
+ GroupNames = args['groups']
+ else : GroupNames = [None, None, None, None, None, None]
+
+ ExistingSegments = Config.ListObj[-1].DirectionalMeshParams[ToLook1]
+ ObjIDs = Config.Connections[-1][ToLook1]
+ RemoveLastObj()
+
+ ExtensionSegments = math.ceil(ExistingSegments/12.)*12.
+ Dmin = 1.E50
+ Dmax = -1.E50
+ for ObjID in ObjIDs :
+ Boundaries = Config.ListObj[ObjID].Boundaries()
+ if Boundaries[ToLook2] < Dmin : Dmin = Boundaries[ToLook2]
+ if Boundaries[ToLook2+1] > Dmax : Dmax = Boundaries[ToLook2+1]
+ dx = 0
+ if ExtensionSegments > ExistingSegments :
+ dn = (ExtensionSegments-ExistingSegments)/2.
+ dx = dn*(Dmax-Dmin)/ExistingSegments
+ #MacObject('CompBoxF',[(X0-CoefHor*dx/2+CoefVer*(-X0+Dmin-dx/2),Y0-CoefVer*dx/2+CoefHor*(-Y0+Dmin-dx/2)),(dx,dx)],[(dn,dn)],publish=0)
+ #MacObject('CompBoxF',[(X0-CoefHor*dx/2+CoefVer*(-X0+Dmax+dx/2),Y0-CoefVer*dx/2+CoefHor*(-Y0+Dmax+dx/2)),(dx,dx)],[(dn,dn)],publish=0)
+
+ BoxSide = (Dmax-Dmin+2*dx)/2.
+
+ Obj = []
+ Obj.append(MacObject('BoxAng32',[(X0+CoefHor*(BoxSide/2)+CoefVer*(-BoxSide/2),Y0+CoefVer*(BoxSide/2)+CoefHor*(-BoxSide/2)),(BoxSide,BoxSide)],[int(ExtensionSegments/6),DirPar[0]],groups=GroupArray(ToLook3[0],GroupNames[0])))
+ Obj.append(MacObject('BoxAng32',[(X0+CoefHor*(BoxSide/2)+CoefVer*(BoxSide/2),Y0+CoefVer*(BoxSide/2)+CoefHor*(BoxSide/2)),(BoxSide,BoxSide)],[int(ExtensionSegments/6),DirPar[1]],groups=GroupArray(ToLook3[0],GroupNames[0])))
+
+ NLevOpt = 0
+ for NLevels in range (1,100) :
+ DX1 = abs(CoefVer)*BoxSide*2.**(NLevels+1)+abs(CoefHor)*BoxSide*2.**(NLevels)
+ DY1 = abs(CoefHor)*BoxSide*2.**(NLevels+1)+abs(CoefVer)*BoxSide*2.**(NLevels)
+ if DX1 > DX or DY1 > DY :
+ NLevOpt = NLevels-1
+ DXinner = DX1/2.
+ DYinner = DY1/2.
+ break
+
+ dummyArray = [DXinner,DYinner,DYinner,DXinner]
+ D1inner = dummyArray[ToLook2] # = DXinner for SN and NS orientations
+ D2inner = dummyArray[ToLook2+1] # = DYinner for SN and NS orientations
+
+ dummyArray = [DX,DY,DY,DX]
+ D1 = dummyArray[ToLook2] # = DX for SN and NS orientations
+ D2 = dummyArray[ToLook2+1] # = DY for SN and NS orientations
+
+ if D1inner < D1 :
+ GN0a = GroupArray(ToLook3[0],GroupNames[1])
+ GN0b = GroupArray(ToLook3[0],GroupNames[2])
+ GN01 = GroupArray(ToLook3[0],GroupNames[1])
+ GN02 = GroupArray(ToLook3[0],GroupNames[2])
+ if D2inner < D2 :
+ GN10 = [None,None,None,None]
+ GN11 = [None,None,None,None]
+ GN20 = [None,None,None,None]
+ else :
+ GN10 = GroupArray(ToLook3[1],GroupNames[3])
+ GN11 = GroupArray(ToLook3[1],GroupNames[3])
+ GN20 = GroupArray(ToLook3[1],GroupNames[3])
+ else :
+ GN0a = GroupArray(ToLook3[0],GroupNames[1])
+ GN0b = GroupArray(ToLook3[0],GroupNames[2])
+ GN01 = GroupArray([ToLook3[0],ToLook3[2]],[GroupNames[1],GroupNames[4]])
+ GN02 = GroupArray([ToLook3[0],ToLook3[3]],[GroupNames[2],GroupNames[5]])
+ if D2inner < D2 :
+ GN10 = GroupArray(ToLook3[2],GroupNames[4])
+ GN11 = GroupArray(ToLook3[3],GroupNames[5])
+ GN20 = [None,None,None,None]
+ else :
+ GN10 = GroupArray([ToLook3[1],ToLook3[2]],[GroupNames[3],GroupNames[4]])
+ GN11 = GroupArray([ToLook3[1],ToLook3[3]],[GroupNames[3],GroupNames[5]])
+ GN20 = GroupArray(ToLook3[1],GroupNames[3])
+
+ for N in range (1,NLevOpt+1):
+ n=N-1
+ D = BoxSide*(2.**n)
+ if N < NLevOpt :
+ Obj.append(MacObject('Box42' ,[(X0+D*(CoefHor*1/2-CoefVer*3/2) , Y0+D*(CoefVer*1/2-CoefHor*3/2) ) , (D,D)],['auto',DirPar[2]], groups=GN0a))
+ Obj.append(MacObject('BoxAng32',[(X0+D*(CoefHor*3/2-CoefVer*3/2) , Y0+D*(CoefVer*3/2-CoefHor*3/2) ) , (D,D)],['auto',DirPar[3]]))
+ Obj.append(MacObject('Box42' ,[(X0+D*(CoefHor*3/2-CoefVer*1/2) , Y0+D*(CoefVer*3/2-CoefHor*1/2) ) , (D,D)],['auto',DirPar[4]]))
+ Obj.append(MacObject('Box42' ,[(X0+D*(CoefHor*3/2+CoefVer*1/2) , Y0+D*(CoefHor*1/2+CoefVer*3/2) ) , (D,D)],['auto',DirPar[5]]))
+ Obj.append(MacObject('BoxAng32',[(X0+D*(CoefVer*3/2+CoefHor*3/2) , Y0+D*(CoefVer*3/2+CoefHor*3/2) ) , (D,D)],['auto',DirPar[6]]))
+ Obj.append(MacObject('Box42' ,[(X0+D*(CoefVer*3/2+CoefHor*1/2) , Y0+D*(CoefHor*3/2+CoefVer*1/2) ) , (D,D)],['auto',DirPar[7]], groups=GN0b))
+ else :
+ Obj.append(MacObject('Box42' ,[(X0+D*(CoefHor*1/2-CoefVer*3/2) , Y0+D*(CoefVer*1/2-CoefHor*3/2) ) , (D,D)],['auto',DirPar[2]], groups=GN01))
+ Obj.append(MacObject('BoxAng32',[(X0+D*(CoefHor*3/2-CoefVer*3/2) , Y0+D*(CoefVer*3/2-CoefHor*3/2) ) , (D,D)],['auto',DirPar[3]], groups=GN10))
+ Obj.append(MacObject('Box42' ,[(X0+D*(CoefHor*3/2-CoefVer*1/2) , Y0+D*(CoefVer*3/2-CoefHor*1/2) ) , (D,D)],['auto',DirPar[4]], groups=GN20))
+ Obj.append(MacObject('Box42' ,[(X0+D*(CoefHor*3/2+CoefVer*1/2) , Y0+D*(CoefHor*1/2+CoefVer*3/2) ) , (D,D)],['auto',DirPar[5]], groups=GN20))
+ Obj.append(MacObject('BoxAng32',[(X0+D*(CoefVer*3/2+CoefHor*3/2) , Y0+D*(CoefVer*3/2+CoefHor*3/2) ) , (D,D)],['auto',DirPar[6]], groups=GN11))
+ Obj.append(MacObject('Box42' ,[(X0+D*(CoefVer*3/2+CoefHor*1/2) , Y0+D*(CoefHor*3/2+CoefVer*1/2) ) , (D,D)],['auto',DirPar[7]], groups=GN02))
+
+
+ if CoefVer and DX>DXinner :
+ Obj.append(MacObject('CompBoxF',[(X0-CoefVer*0.25*(DX+DXinner),Y0+CoefVer*DYinner/2),((DX-DXinner)/2,DYinner)],['auto'], groups = GroupArray([ToLook3[0],ToLook3[2]],[GroupNames[1],GroupNames[4]])))
+ Obj.append(MacObject('CompBoxF',[(X0+CoefVer*0.25*(DX+DXinner),Y0+CoefVer*DYinner/2),((DX-DXinner)/2,DYinner)],['auto'], groups = GroupArray([ToLook3[0],ToLook3[3]],[GroupNames[2],GroupNames[5]])))
+ if DY>DYinner :
+ Obj.append(MacObject('CompBoxF',[(X0-CoefVer*0.25*(DX+DXinner),Y0+CoefVer*(DY+DYinner)/2.),((DX-DXinner)/2,DY-DYinner)],['auto'], groups = GroupArray([ToLook3[1],ToLook3[2]],[GroupNames[3],GroupNames[4]])))
+ Obj.append(MacObject('CompBoxF',[(X0+CoefVer*0.25*(DX+DXinner),Y0+CoefVer*(DY+DYinner)/2.),((DX-DXinner)/2,DY-DYinner)],['auto'], groups = GroupArray([ToLook3[1],ToLook3[3]],[GroupNames[3],GroupNames[5]])))
+ Obj.append(MacObject('CompBoxF',[(X0,Y0+CoefVer*(DY+DYinner)/2.),(DXinner,DY-DYinner)],['auto'], groups = GroupArray(ToLook3[1],GroupNames[3])))
+ elif CoefHor and DY>DYinner :
+ Obj.append(MacObject('CompBoxF',[(X0+CoefHor*DXinner/2,Y0-CoefHor*0.25*(DY+DYinner)),(DXinner,(DY-DYinner)/2)],['auto'], groups = GroupArray([ToLook3[0],ToLook3[2]],[GroupNames[1],GroupNames[4]])))
+ Obj.append(MacObject('CompBoxF',[(X0+CoefHor*DXinner/2,Y0+CoefHor*0.25*(DY+DYinner)),(DXinner,(DY-DYinner)/2)],['auto'], groups = GroupArray([ToLook3[0],ToLook3[3]],[GroupNames[2],GroupNames[5]])))
+ if DX>DXinner :
+ Obj.append(MacObject('CompBoxF',[(X0+CoefHor*(DX+DXinner)/2.,Y0-CoefHor*0.25*(DY+DYinner)),(DX-DXinner,(DY-DYinner)/2)],['auto'], groups = GroupArray([ToLook3[1],ToLook3[2]],[GroupNames[3],GroupNames[4]])))
+ Obj.append(MacObject('CompBoxF',[(X0+CoefHor*(DX+DXinner)/2.,Y0+CoefHor*0.25*(DY+DYinner)),(DX-DXinner,(DY-DYinner)/2)],['auto'], groups = GroupArray([ToLook3[1],ToLook3[3]],[GroupNames[3],GroupNames[5]])))
+ Obj.append(MacObject('CompBoxF',[(X0+CoefHor*(DX+DXinner)/2.,Y0),(DX-DXinner,DYinner)],['auto'], groups = GroupArray(ToLook3[1],GroupNames[3])))
+ return Obj
+
+def RemoveLastObj() :
+ Config.ListObj = Config.ListObj[:-1]
+ Config.Connections = Config.Connections[:-1]
+
def GroupArray(indices, GroupNames) :
- if type(indices) is int :
- indices = [indices]
- GroupNames = [GroupNames]
- Output = [None,None,None,None]
- for i, ind in enumerate(indices) :
- Output[ind] = GroupNames[i]
- return Output
+ if type(indices) is int :
+ indices = [indices]
+ GroupNames = [GroupNames]
+ Output = [None,None,None,None]
+ for i, ind in enumerate(indices) :
+ Output[ind] = GroupNames[i]
+ return Output
from MacObject import *
import Config, GenFunctions
-def CompositeBox (X0 , Y0 , DX , DY , **args ) :
-
- if args.__contains__('groups') :
- GroupNames = args['groups']
- else : GroupNames = [None, None, None, None]
- # Create a full Box just to inherit, globally, the mesh parameters of bounding objects
- MacObject('CompBoxF',[(X0,Y0),(DX,DY)],['auto'],publish=0)
-
- # Save the existing number of segments on each direction
- ExistingSegments = Config.ListObj[-1].DirectionalMeshParams
-
- # Sort the connection list for the full Box
- ObjIDLists = SortObjLists(Config.Connections[-1],X0 , Y0 , DX , DY )
- RemoveLastObj()
-
- print "ObjIDLists: ", ObjIDLists
-
- RealSegments = []
- Direction = []
- flag = 0
- if not(args.__contains__('recursive')) : Config.Count = 0
- print "Config.Count : ", Config.Count
- Config.Criterion = GetCriterion(ObjIDLists)
- for index, ObjList in enumerate(ObjIDLists) :
- if not (ObjList[0] == -1 or Config.Count >= Config.Criterion):
- if len(ObjList)>1 : flag = 1
- else : flag = 0
- for ObjID in ObjList:
- ToLook0 = [2,2,0,0][index]
- ToLook1 = [3,2,1,0][index]
- CommonSide = FindCommonSide(Config.ListObj[ObjID].DirBoundaries(ToLook1),[X0-DX/2.,X0+DX/2.,Y0-DY/2.,Y0+DY/2.][ToLook0:ToLook0+2])
- ToLook2 = [1,0,3,2][index]
- RealSegments.append(Config.ListObj[ObjID].DirectionalMeshParams[ToLook2]*IntLen(CommonSide)/IntLen(Config.ListObj[ObjID].DirBoundaries(ToLook1)))
- Direction.append(ToLook0/2)
-
- if flag and Config.Count < Config.Criterion:
- if index < 2 :
- if abs(CommonSide[0] - (Y0-DY/2.))<1e-7 : SouthGR = GroupNames[0]
- else : SouthGR = None
- if abs(CommonSide[1] - (Y0+DY/2.))<1e-7 : NorthGR = GroupNames[1]
- else : NorthGR = None
- CompositeBox (X0, CommonSide[0]+IntLen(CommonSide)/2., DX,IntLen(CommonSide), recursive=1, groups = [SouthGR,NorthGR]+GroupNames[2:4])
- else :
- if abs(CommonSide[0] - (X0-DX/2.))<1e-7 : EastGR = GroupNames[2]
- else : EastGR = None
- if abs(CommonSide[1] - (X0+DX/2.))<1e-7 : WestGR = GroupNames[3]
- else : WestGR = None
- CompositeBox (CommonSide[0]+IntLen(CommonSide)/2., Y0, IntLen(CommonSide),DY, recursive=1, groups = GroupNames[0:2]+[EastGR,WestGR])
-
- if Config.Count >= Config.Criterion :
- break
- if flag == 0 and Config.Count < Config.Criterion:
- #print "Dir : ", Direction
- #print "RealSegments : ", RealSegments
-
- #Xind = Direction.index(0)
- #Yind = Direction.index(1)
- #MacObject('CompBoxF',[(X0,Y0),(DX,DY)] ,[(RealSegments[Xind],RealSegments[Yind])], groups = GroupNames)
- MacObject('CompBoxF',[(X0,Y0),(DX,DY)] ,['auto'], groups = GroupNames)
-
- Config.Count += 1
-
-
+def CompositeBox (X0 , Y0 , DX , DY , **args ) :
+
+ if args.__contains__('groups') :
+ GroupNames = args['groups']
+ else : GroupNames = [None, None, None, None]
+ # Create a full Box just to inherit, globally, the mesh parameters of bounding objects
+ MacObject('CompBoxF',[(X0,Y0),(DX,DY)],['auto'],publish=0)
+
+ # Save the existing number of segments on each direction
+ ExistingSegments = Config.ListObj[-1].DirectionalMeshParams
+
+ # Sort the connection list for the full Box
+ ObjIDLists = SortObjLists(Config.Connections[-1],X0 , Y0 , DX , DY )
+ RemoveLastObj()
+
+ print "ObjIDLists: ", ObjIDLists
+
+ RealSegments = []
+ Direction = []
+ flag = 0
+ if not(args.__contains__('recursive')) : Config.Count = 0
+ print "Config.Count : ", Config.Count
+ Config.Criterion = GetCriterion(ObjIDLists)
+ for index, ObjList in enumerate(ObjIDLists) :
+ if not (ObjList[0] == -1 or Config.Count >= Config.Criterion):
+ if len(ObjList)>1 : flag = 1
+ else : flag = 0
+ for ObjID in ObjList:
+ ToLook0 = [2,2,0,0][index]
+ ToLook1 = [3,2,1,0][index]
+ CommonSide = FindCommonSide(Config.ListObj[ObjID].DirBoundaries(ToLook1),[X0-DX/2.,X0+DX/2.,Y0-DY/2.,Y0+DY/2.][ToLook0:ToLook0+2])
+ ToLook2 = [1,0,3,2][index]
+ RealSegments.append(Config.ListObj[ObjID].DirectionalMeshParams[ToLook2]*IntLen(CommonSide)/IntLen(Config.ListObj[ObjID].DirBoundaries(ToLook1)))
+ Direction.append(ToLook0/2)
+
+ if flag and Config.Count < Config.Criterion:
+ if index < 2 :
+ if abs(CommonSide[0] - (Y0-DY/2.))<1e-7 : SouthGR = GroupNames[0]
+ else : SouthGR = None
+ if abs(CommonSide[1] - (Y0+DY/2.))<1e-7 : NorthGR = GroupNames[1]
+ else : NorthGR = None
+ CompositeBox (X0, CommonSide[0]+IntLen(CommonSide)/2., DX,IntLen(CommonSide), recursive=1, groups = [SouthGR,NorthGR]+GroupNames[2:4])
+ else :
+ if abs(CommonSide[0] - (X0-DX/2.))<1e-7 : EastGR = GroupNames[2]
+ else : EastGR = None
+ if abs(CommonSide[1] - (X0+DX/2.))<1e-7 : WestGR = GroupNames[3]
+ else : WestGR = None
+ CompositeBox (CommonSide[0]+IntLen(CommonSide)/2., Y0, IntLen(CommonSide),DY, recursive=1, groups = GroupNames[0:2]+[EastGR,WestGR])
+
+ if Config.Count >= Config.Criterion :
+ break
+ if flag == 0 and Config.Count < Config.Criterion:
+ #print "Dir : ", Direction
+ #print "RealSegments : ", RealSegments
+
+ #Xind = Direction.index(0)
+ #Yind = Direction.index(1)
+ #MacObject('CompBoxF',[(X0,Y0),(DX,DY)] ,[(RealSegments[Xind],RealSegments[Yind])], groups = GroupNames)
+ MacObject('CompBoxF',[(X0,Y0),(DX,DY)] ,['auto'], groups = GroupNames)
+
+ Config.Count += 1
+
+
def FindCommonSide (Int1, Int2) :
- if abs(min(Int1[1],Int2[1])-max(Int1[0],Int2[0])) < 1e-5: return [0,0]
- else : return [max(Int1[0],Int2[0]), min(Int1[1],Int2[1])]
-
+ if abs(min(Int1[1],Int2[1])-max(Int1[0],Int2[0])) < 1e-5: return [0,0]
+ else : return [max(Int1[0],Int2[0]), min(Int1[1],Int2[1])]
+
def IntLen (Interval) :
- return abs(Interval[1]-Interval[0])
-
-def RemoveLastObj() :
- Config.ListObj = Config.ListObj[:-1]
- Config.Connections = Config.Connections[:-1]
-
+ return abs(Interval[1]-Interval[0])
+
+def RemoveLastObj() :
+ Config.ListObj = Config.ListObj[:-1]
+ Config.Connections = Config.Connections[:-1]
+
def GetCriterion (ObjListIDs):
- return max(Config.Criterion, max(len(ObjListIDs[0]),len(ObjListIDs[1]))*max(len(ObjListIDs[2]),len(ObjListIDs[3])))
+ return max(Config.Criterion, max(len(ObjListIDs[0]),len(ObjListIDs[1]))*max(len(ObjListIDs[2]),len(ObjListIDs[3])))
def SortObjLists (List,X0,Y0,DX,DY) :
- """
- This function sorts the list of neighbouring objects on each side, according to their intersection
- with the object being created. From South to North and from East to West
- """
- Output = List
- # First find the directions where no neighbour exists
- # Important : Here we assume that exactly two directions have no neighbours !!!
- # Should we change this to allow a more general case ????
- dummy = IndexMultiOcc(List,(-1,))
-
- # dummy[0] is either 0, meaning there is no neighbour on X- (West)
- # or 1, meaning there is no neighbour on X+ (East)
- # Similarly dummy[1] can be either 2 or 3 (South and North respectively)
- # In order to get back to the formalism of groups (SNWE)
- # => we do the following to define Sense of no neighbours and then the Direction list
- # is calculated as to include uniquely the directions where we DO have neighbours
- if len(dummy) == 1 :
- # This adds a second direction where neighbours are not regarded, it is either 0 or 2
- dummy.append(2*(dummy[0]+2<4))
- print("Careful, you have neighbours on 3 or more sides of the box, we will not check if on two parallel sides the boxes are compatible !!!")
- if len(dummy) == 2 or len(dummy) == 1 :
- # Sense contains : Vertical then Horizontal
- Sense = [dummy[1]%2,dummy[0]]
- DirList = [[1,0][dummy[0]],[3,2][dummy[1]%2]]
- for index,Direction in enumerate(DirList) :
- ObjList = List[Direction]
- RankMin = []
- ToLook0 = [2,2,0,0][Direction]
- ToLook1 = [3,2,1,0][Direction]
- for index1,ObjID in enumerate(ObjList) :
- RankMin.append([-1.,1.][Sense[index]] * FindCommonSide(Config.ListObj[ObjID].DirBoundaries(ToLook1),[X0-DX/2.,X0+DX/2.,Y0-DY/2.,Y0+DY/2.][ToLook0:ToLook0+2])[Sense[index]])
- Output[Direction] = SortList(ObjList,RankMin)
-
- elif len(dummy) == 3 :
- # We find the direction where we do have neighbours and then we sort the object list along it
- Sense = dummy[0]%2
- Direction = [ i not in dummy for i in range(4) ].index(True)
- ObjList = List[Direction]
- RankMin = []
- ToLook0 = [2,2,0,0][Direction]
- ToLook1 = [3,2,1,0][Direction]
- for index1,ObjID in enumerate(ObjList) :
- RankMin.append([-1.,1.][Sense] * FindCommonSide(Config.ListObj[ObjID].DirBoundaries(ToLook1),[X0-DX/2.,X0+DX/2.,Y0-DY/2.,Y0+DY/2.][ToLook0:ToLook0+2])[Sense])
- Output[Direction] = SortList(ObjList,RankMin)
- else :
- print ("Error : the composite box being created has no neighbours, how on earth do you want us to inherit its mesh parameters!!!")
-
-
- return Output
-
+ """
+ This function sorts the list of neighbouring objects on each side, according to their intersection
+ with the object being created. From South to North and from East to West
+ """
+ Output = List
+ # First find the directions where no neighbour exists
+ # Important : Here we assume that exactly two directions have no neighbours !!!
+ # Should we change this to allow a more general case ????
+ dummy = IndexMultiOcc(List,(-1,))
+
+ # dummy[0] is either 0, meaning there is no neighbour on X- (West)
+ # or 1, meaning there is no neighbour on X+ (East)
+ # Similarly dummy[1] can be either 2 or 3 (South and North respectively)
+ # In order to get back to the formalism of groups (SNWE)
+ # => we do the following to define Sense of no neighbours and then the Direction list
+ # is calculated as to include uniquely the directions where we DO have neighbours
+ if len(dummy) == 1 :
+ # This adds a second direction where neighbours are not regarded, it is either 0 or 2
+ dummy.append(2*(dummy[0]+2<4))
+ print("Careful, you have neighbours on 3 or more sides of the box, we will not check if on two parallel sides the boxes are compatible !!!")
+ if len(dummy) == 2 or len(dummy) == 1 :
+ # Sense contains : Vertical then Horizontal
+ Sense = [dummy[1]%2,dummy[0]]
+ DirList = [[1,0][dummy[0]],[3,2][dummy[1]%2]]
+ for index,Direction in enumerate(DirList) :
+ ObjList = List[Direction]
+ RankMin = []
+ ToLook0 = [2,2,0,0][Direction]
+ ToLook1 = [3,2,1,0][Direction]
+ for index1,ObjID in enumerate(ObjList) :
+ RankMin.append([-1.,1.][Sense[index]] * FindCommonSide(Config.ListObj[ObjID].DirBoundaries(ToLook1),[X0-DX/2.,X0+DX/2.,Y0-DY/2.,Y0+DY/2.][ToLook0:ToLook0+2])[Sense[index]])
+ Output[Direction] = SortList(ObjList,RankMin)
+
+ elif len(dummy) == 3 :
+ # We find the direction where we do have neighbours and then we sort the object list along it
+ Sense = dummy[0]%2
+ Direction = [ i not in dummy for i in range(4) ].index(True)
+ ObjList = List[Direction]
+ RankMin = []
+ ToLook0 = [2,2,0,0][Direction]
+ ToLook1 = [3,2,1,0][Direction]
+ for index1,ObjID in enumerate(ObjList) :
+ RankMin.append([-1.,1.][Sense] * FindCommonSide(Config.ListObj[ObjID].DirBoundaries(ToLook1),[X0-DX/2.,X0+DX/2.,Y0-DY/2.,Y0+DY/2.][ToLook0:ToLook0+2])[Sense])
+ Output[Direction] = SortList(ObjList,RankMin)
+ else :
+ print ("Error : the composite box being created has no neighbours, how on earth do you want us to inherit its mesh parameters!!!")
+
+
+ return Output
+
def IndexMultiOcc (Array,Element) :
- """
- This functions returns the occurrences indices of Element in Array.
- As opposed to Array.index(Element) method, this allows determining
- multiple entries rather than just the first one!
- """
- Output = []
- try : Array.index(Element)
- except ValueError : print "No more occurrences"
- else : Output.append(Array.index(Element))
-
- if not(Output == []) and len(Array) > 1 :
- for index, ArrElem in enumerate(Array[Output[0]+1:]) :
- if ArrElem == Element : Output.append(index+Output[0]+1)
-
- return Output
-
-def SortList (ValList, CritList):
- Output = []
- SortedCritList = copy.copy(CritList)
- SortedCritList.sort()
- for i in range(0,len(ValList)):
- index = CritList.index(SortedCritList[i])
- Output.append(ValList[index])
- return Output
+ """
+ This functions returns the occurrences indices of Element in Array.
+ As opposed to Array.index(Element) method, this allows determining
+ multiple entries rather than just the first one!
+ """
+ Output = []
+ try : Array.index(Element)
+ except ValueError : print "No more occurrences"
+ else : Output.append(Array.index(Element))
+ if not(Output == []) and len(Array) > 1 :
+ for index, ArrElem in enumerate(Array[Output[0]+1:]) :
+ if ArrElem == Element : Output.append(index+Output[0]+1)
-
+ return Output
+
+def SortList (ValList, CritList):
+ Output = []
+ SortedCritList = copy.copy(CritList)
+ SortedCritList.sort()
+ for i in range(0,len(ValList)):
+ index = CritList.index(SortedCritList[i])
+ Output.append(ValList[index])
+ return Output
from MacObject import *
import Config, GenFunctions
-def CompositeBoxF (Pt1 , Pt2 , Pt3 , Pt4 , **args ) :
- [Pt1 , Pt2 , Pt3 , Pt4] = GenFunctions.SortPoints([Pt1 , Pt2 , Pt3 , Pt4])
- if args.__contains__('groups') :
- GroupNames = args['groups']
- else : GroupNames = [None, None, None, None]
- # Create a full NonOrtho box just to inherit, globally, the mesh parameters of bounding objects
- dummy = MacObject('NonOrtho',[Pt1,Pt2,Pt3,Pt4],['auto'],publish=0)
- # Save the existing number of segments on each direction
- ExistingSeg0 = Config.ListObj[-1].DirectionalMeshParams
- Convention = [2,3,0,1]
- ExistingSegments = [ExistingSeg0[Convention[i]] for i in range(4)]
- # Save Boundary lengths on each direction
- BoundaryLengths = [IntLen(dummy.DirBoundaries(i)) for i in range(4) ]
- # Calculate global mesh element size on each direction
- GlobalDelta = [1.*BoundaryLengths[i]/ExistingSegments[i] for i in range(4) ]
- print "GlobalDelta :",GlobalDelta
- # Sort the connection list for the full Box
- [(X0,Y0),(DX,DY)] = dummy.GeoPar
- ObjIDLists = SortObjLists(Config.Connections[-1],X0 , Y0 , DX , DY )
- [Xmin,Xmax,Ymin,Ymax] = dummy.Boundaries() # Used for groups determination
- RemoveLastObj()
-
- RealSegments = []
- Direction = []
- flag = 0
- if not(args.__contains__('recursive')) :
- Config.Count = 0
-
- Config.Criterion = GetCriterion(ObjIDLists)
- for index, ObjList in enumerate(ObjIDLists) :
- if not (ObjList[0] == -1 or Config.Count >= Config.Criterion):
- if not(args.__contains__('recursive')) :
- Config.DirIndex = index
- if index > 1 : Config.RefPts = [Pt2, Pt3]
- elif index == 0 : Config.RefPts = [Pt1, Pt2]
- else : Config.RefPts = [Pt4, Pt3]
-
- if len(ObjList)>1 : flag = 1
- else : flag = 0
- for ObjID in ObjList:
- ToLook0 = [2,3,0,1][index]
- ToLook1 = [3,2,1,0][index]
- CommonSide = FindCommonSide(Config.ListObj[ObjID].DirBoundaries(ToLook1),dummy.DirBoundaries(ToLook0))
- ToLook2 = [1,0,3,2][index]
- RealSegments = Config.ListObj[ObjID].DirectionalMeshParams[ToLook2]*IntLen(CommonSide)/IntLen(Config.ListObj[ObjID].DirBoundaries(ToLook1))
- LocalDelta = 1.*IntLen(CommonSide)/RealSegments
- print "Direction:", ["West","East","South","North"][ToLook2]
- print "IntLen(CommonSide):",IntLen(CommonSide)
- print "RealSegments:",RealSegments
- print "LocalDelta:",LocalDelta
- if flag and Config.Count < Config.Criterion:
- if index ==0 :
- if abs(CommonSide[0] - Ymin)<1e-7 : SouthGR = GroupNames[0]
- else : SouthGR = None
- if abs(CommonSide[1] - Ymax)<1e-7 : NorthGR = GroupNames[1]
- else : NorthGR = None
-
- NDelta = Config.ListObj[ObjID].DirectionalMeshParams[ToLook2]* (LocalDelta-GlobalDelta[Convention[index]])
- [Pt1,Pt2] = Config.RefPts
- Coef = [1.,-1.][index]
- Vref1 = [Coef*(Pt2[0]-Pt1[0]),Coef*(Pt2[1]-Pt1[1])]
- Vref2 = NormalizeVector([Pt2[0]-Pt3[0],Pt2[1]-Pt3[1]])
- Ptref = Config.ListObj[ObjID].PtCoor[[2,3][index]]
- NewPt = ExtrapPoint (Ptref,Vref1,Vref2,NDelta)
- CompositeBoxF (Pt1, Pt2, NewPt, Ptref, recursive=1, groups = [SouthGR,NorthGR]+GroupNames[2:4])
- elif index == 1:
- if abs(CommonSide[0] - Ymin)<1e-7 : SouthGR = GroupNames[0]
- else : SouthGR = None
- if abs(CommonSide[1] - Ymax)<1e-7 : NorthGR = GroupNames[1]
- else : NorthGR = None
-
- NDelta = Config.ListObj[ObjID].DirectionalMeshParams[ToLook2]* (LocalDelta-GlobalDelta[Convention[index]])
- [Pt4,Pt3] = Config.RefPts
- Coef = 1.
- Vref1 = [Coef*(Pt4[0]-Pt3[0]),Coef*(Pt4[1]-Pt3[1])]
- Vref2 = NormalizeVector([Pt1[0]-Pt4[0],Pt1[1]-Pt4[1]])
- Ptref = Config.ListObj[ObjID].PtCoor[0]
- NewPt = ExtrapPoint (Ptref,Vref1,Vref2,NDelta)
- CompositeBoxF (NewPt, Ptref, Pt3, Pt4, recursive=1, groups = [SouthGR,NorthGR]+GroupNames[2:4])
- else :
- if abs(CommonSide[0] - Xmin)<1e-7 : WestGR = GroupNames[2]
- else : WestGR = None
- if abs(CommonSide[1] - Xmax)<1e-7 : EastGR = GroupNames[3]
- else : EastGR = None
-
- NDelta = Config.ListObj[ObjID].DirectionalMeshParams[ToLook2]* (LocalDelta-GlobalDelta[Convention[index]])
- [Pt2,Pt3] = Config.RefPts
- Coef = [1.,-1.][index-2]
- Vref1 = [Coef*(Pt3[0]-Pt2[0]),Coef*(Pt3[1]-Pt2[1])]
- Vref2 = NormalizeVector([Pt3[0]-Pt4[0],Pt3[1]-Pt4[1]])
- Ptref = Config.ListObj[ObjID].PtCoor[[3,0][index-2]]
- NewPt = ExtrapPoint (Ptref,Vref1,Vref2,NDelta)
- CompositeBoxF (Ptref, Pt2, Pt3, NewPt, recursive=1, groups = GroupNames[0:2] + [WestGR,EastGR])
-
- if Config.Count >= Config.Criterion :
- break
- if flag == 0 and Config.Count < Config.Criterion:
- print "Creating NonOrtho object with the points:", Pt1,Pt2,Pt3,Pt4
- MacObject('NonOrtho',[Pt1,Pt2,Pt3,Pt4] ,['auto'], groups = GroupNames)
-
- Config.Count += 1
- if Config.DirIndex > 1 : Config.RefPts = [Pt1, Pt4]
- elif Config.DirIndex==0 : Config.RefPts = [Pt4, Pt3]
- else : Config.RefPts = [Pt1, Pt2]
-
+def CompositeBoxF (Pt1 , Pt2 , Pt3 , Pt4 , **args ) :
+ [Pt1 , Pt2 , Pt3 , Pt4] = GenFunctions.SortPoints([Pt1 , Pt2 , Pt3 , Pt4])
+ if args.__contains__('groups') :
+ GroupNames = args['groups']
+ else : GroupNames = [None, None, None, None]
+ # Create a full NonOrtho box just to inherit, globally, the mesh parameters of bounding objects
+ dummy = MacObject('NonOrtho',[Pt1,Pt2,Pt3,Pt4],['auto'],publish=0)
+ # Save the existing number of segments on each direction
+ ExistingSeg0 = Config.ListObj[-1].DirectionalMeshParams
+ Convention = [2,3,0,1]
+ ExistingSegments = [ExistingSeg0[Convention[i]] for i in range(4)]
+ # Save Boundary lengths on each direction
+ BoundaryLengths = [IntLen(dummy.DirBoundaries(i)) for i in range(4) ]
+ # Calculate global mesh element size on each direction
+ GlobalDelta = [1.*BoundaryLengths[i]/ExistingSegments[i] for i in range(4) ]
+ print "GlobalDelta :",GlobalDelta
+ # Sort the connection list for the full Box
+ [(X0,Y0),(DX,DY)] = dummy.GeoPar
+ ObjIDLists = SortObjLists(Config.Connections[-1],X0 , Y0 , DX , DY )
+ [Xmin,Xmax,Ymin,Ymax] = dummy.Boundaries() # Used for groups determination
+ RemoveLastObj()
+
+ RealSegments = []
+ Direction = []
+ flag = 0
+ if not(args.__contains__('recursive')) :
+ Config.Count = 0
+
+ Config.Criterion = GetCriterion(ObjIDLists)
+ for index, ObjList in enumerate(ObjIDLists) :
+ if not (ObjList[0] == -1 or Config.Count >= Config.Criterion):
+ if not(args.__contains__('recursive')) :
+ Config.DirIndex = index
+ if index > 1 : Config.RefPts = [Pt2, Pt3]
+ elif index == 0 : Config.RefPts = [Pt1, Pt2]
+ else : Config.RefPts = [Pt4, Pt3]
+
+ if len(ObjList)>1 : flag = 1
+ else : flag = 0
+ for ObjID in ObjList:
+ ToLook0 = [2,3,0,1][index]
+ ToLook1 = [3,2,1,0][index]
+ CommonSide = FindCommonSide(Config.ListObj[ObjID].DirBoundaries(ToLook1),dummy.DirBoundaries(ToLook0))
+ ToLook2 = [1,0,3,2][index]
+ RealSegments = Config.ListObj[ObjID].DirectionalMeshParams[ToLook2]*IntLen(CommonSide)/IntLen(Config.ListObj[ObjID].DirBoundaries(ToLook1))
+ LocalDelta = 1.*IntLen(CommonSide)/RealSegments
+ print "Direction:", ["West","East","South","North"][ToLook2]
+ print "IntLen(CommonSide):",IntLen(CommonSide)
+ print "RealSegments:",RealSegments
+ print "LocalDelta:",LocalDelta
+ if flag and Config.Count < Config.Criterion:
+ if index ==0 :
+ if abs(CommonSide[0] - Ymin)<1e-7 : SouthGR = GroupNames[0]
+ else : SouthGR = None
+ if abs(CommonSide[1] - Ymax)<1e-7 : NorthGR = GroupNames[1]
+ else : NorthGR = None
+
+ NDelta = Config.ListObj[ObjID].DirectionalMeshParams[ToLook2]* (LocalDelta-GlobalDelta[Convention[index]])
+ [Pt1,Pt2] = Config.RefPts
+ Coef = [1.,-1.][index]
+ Vref1 = [Coef*(Pt2[0]-Pt1[0]),Coef*(Pt2[1]-Pt1[1])]
+ Vref2 = NormalizeVector([Pt2[0]-Pt3[0],Pt2[1]-Pt3[1]])
+ Ptref = Config.ListObj[ObjID].PtCoor[[2,3][index]]
+ NewPt = ExtrapPoint (Ptref,Vref1,Vref2,NDelta)
+ CompositeBoxF (Pt1, Pt2, NewPt, Ptref, recursive=1, groups = [SouthGR,NorthGR]+GroupNames[2:4])
+ elif index == 1:
+ if abs(CommonSide[0] - Ymin)<1e-7 : SouthGR = GroupNames[0]
+ else : SouthGR = None
+ if abs(CommonSide[1] - Ymax)<1e-7 : NorthGR = GroupNames[1]
+ else : NorthGR = None
+
+ NDelta = Config.ListObj[ObjID].DirectionalMeshParams[ToLook2]* (LocalDelta-GlobalDelta[Convention[index]])
+ [Pt4,Pt3] = Config.RefPts
+ Coef = 1.
+ Vref1 = [Coef*(Pt4[0]-Pt3[0]),Coef*(Pt4[1]-Pt3[1])]
+ Vref2 = NormalizeVector([Pt1[0]-Pt4[0],Pt1[1]-Pt4[1]])
+ Ptref = Config.ListObj[ObjID].PtCoor[0]
+ NewPt = ExtrapPoint (Ptref,Vref1,Vref2,NDelta)
+ CompositeBoxF (NewPt, Ptref, Pt3, Pt4, recursive=1, groups = [SouthGR,NorthGR]+GroupNames[2:4])
+ else :
+ if abs(CommonSide[0] - Xmin)<1e-7 : WestGR = GroupNames[2]
+ else : WestGR = None
+ if abs(CommonSide[1] - Xmax)<1e-7 : EastGR = GroupNames[3]
+ else : EastGR = None
+
+ NDelta = Config.ListObj[ObjID].DirectionalMeshParams[ToLook2]* (LocalDelta-GlobalDelta[Convention[index]])
+ [Pt2,Pt3] = Config.RefPts
+ Coef = [1.,-1.][index-2]
+ Vref1 = [Coef*(Pt3[0]-Pt2[0]),Coef*(Pt3[1]-Pt2[1])]
+ Vref2 = NormalizeVector([Pt3[0]-Pt4[0],Pt3[1]-Pt4[1]])
+ Ptref = Config.ListObj[ObjID].PtCoor[[3,0][index-2]]
+ NewPt = ExtrapPoint (Ptref,Vref1,Vref2,NDelta)
+ CompositeBoxF (Ptref, Pt2, Pt3, NewPt, recursive=1, groups = GroupNames[0:2] + [WestGR,EastGR])
+
+ if Config.Count >= Config.Criterion :
+ break
+ if flag == 0 and Config.Count < Config.Criterion:
+ print "Creating NonOrtho object with the points:", Pt1,Pt2,Pt3,Pt4
+ MacObject('NonOrtho',[Pt1,Pt2,Pt3,Pt4] ,['auto'], groups = GroupNames)
+
+ Config.Count += 1
+ if Config.DirIndex > 1 : Config.RefPts = [Pt1, Pt4]
+ elif Config.DirIndex==0 : Config.RefPts = [Pt4, Pt3]
+ else : Config.RefPts = [Pt1, Pt2]
+
def FindCommonSide (Int1, Int2) :
- if max(Int1[0],Int2[0])<min(Int1[1],Int2[1]): return [max(Int1[0],Int2[0]), min(Int1[1],Int2[1])]
- else :
- print "Can not find interval intersection, returning [0,0]..."
- return [0,0]
-
+ if max(Int1[0],Int2[0])<min(Int1[1],Int2[1]): return [max(Int1[0],Int2[0]), min(Int1[1],Int2[1])]
+ else :
+ print "Can not find interval intersection, returning [0,0]..."
+ return [0,0]
+
def IntLen (Interval) :
- return float(abs(Interval[1]-Interval[0]))
-
-def RemoveLastObj() :
- Config.ListObj = Config.ListObj[:-1]
- Config.Connections = Config.Connections[:-1]
-
+ return float(abs(Interval[1]-Interval[0]))
+
+def RemoveLastObj() :
+ Config.ListObj = Config.ListObj[:-1]
+ Config.Connections = Config.Connections[:-1]
+
def NormalizeVector(V):
- Magnitude = math.sqrt(GenFunctions.DotProd(V,V))
- return [ V[i]/Magnitude for i in range(len(V))]
-
+ Magnitude = math.sqrt(GenFunctions.DotProd(V,V))
+ return [ V[i]/Magnitude for i in range(len(V))]
+
def GetCriterion (ObjListIDs):
- return max(Config.Criterion, max(len(ObjListIDs[0]),len(ObjListIDs[1]))*max(len(ObjListIDs[2]),len(ObjListIDs[3])))
+ return max(Config.Criterion, max(len(ObjListIDs[0]),len(ObjListIDs[1]))*max(len(ObjListIDs[2]),len(ObjListIDs[3])))
def SortObjLists (List,X0,Y0,DX,DY) :
- """
- This function sorts the list of neighbouring objects on each side, according to their intersection
- with the object being created. From South to North and from East to West
- """
- Output = List
- # First find the directions where no neighbour exists
- # Important : Here we assume that exactly two directions have no neighbours !!!
- # Should we change this to allow a more general case ????
- dummy = IndexMultiOcc(List,(-1,))
-
- # dummy[0] is either 0, meaning there is no neighbour on X- (West)
- # or 1, meaning there is no neighbour on X+ (East)
- # Similarly dummy[1] can be either 2 or 3 (South and North respectively)
- # In order to get back to the formalism of groups (SNWE)
- # => we do the following to define Sense of no neighbours and then the Direction list
- # is calculated as to include uniquely the directions where we DO have neighbours
- if len(dummy) == 1 :
- # This adds a second direction where neighbours are not regarded, it is either 0 or 2
- dummy.append(2*(dummy[0]+2<4))
- print("Careful, you have neighbours on 3 or more sides of the box, we will not check if on two parallel sides the boxes are compatible !!!")
- if len(dummy) == 2 or len(dummy) == 1 :
- # Sense contains : Vertical then Horizontal
- Sense = [dummy[1]%2,dummy[0]]
- DirList = [[1,0][dummy[0]],[3,2][dummy[1]%2]]
- for index,Direction in enumerate(DirList) :
- ObjList = List[Direction]
- RankMin = []
- ToLook0 = [2,2,0,0][Direction]
- ToLook1 = [3,2,1,0][Direction]
- for index1,ObjID in enumerate(ObjList) :
- RankMin.append([-1.,1.][Sense[index]] * FindCommonSide(Config.ListObj[ObjID].DirBoundaries(ToLook1),[X0-DX/2.,X0+DX/2.,Y0-DY/2.,Y0+DY/2.][ToLook0:ToLook0+2])[Sense[index]])
- Output[Direction] = SortList(ObjList,RankMin)
-
- elif len(dummy) == 3 :
- # We find the direction where we do have neighbours and then we sort the object list along it
- Sense = dummy[0]%2
- Direction = [ i not in dummy for i in range(4) ].index(True)
- ObjList = List[Direction]
- RankMin = []
- ToLook0 = [2,2,0,0][Direction]
- ToLook1 = [3,2,1,0][Direction]
- for index1,ObjID in enumerate(ObjList) :
- RankMin.append([-1.,1.][Sense] * FindCommonSide(Config.ListObj[ObjID].DirBoundaries(ToLook1),[X0-DX/2.,X0+DX/2.,Y0-DY/2.,Y0+DY/2.][ToLook0:ToLook0+2])[Sense])
- Output[Direction] = SortList(ObjList,RankMin)
- else :
- print ("Error : the composite box being created has no neighbours, how on earth do you want us to inherit its mesh parameters!!!")
-
-
- return Output
-
+ """
+ This function sorts the list of neighbouring objects on each side, according to their intersection
+ with the object being created. From South to North and from East to West
+ """
+ Output = List
+ # First find the directions where no neighbour exists
+ # Important : Here we assume that exactly two directions have no neighbours !!!
+ # Should we change this to allow a more general case ????
+ dummy = IndexMultiOcc(List,(-1,))
+
+ # dummy[0] is either 0, meaning there is no neighbour on X- (West)
+ # or 1, meaning there is no neighbour on X+ (East)
+ # Similarly dummy[1] can be either 2 or 3 (South and North respectively)
+ # In order to get back to the formalism of groups (SNWE)
+ # => we do the following to define Sense of no neighbours and then the Direction list
+ # is calculated as to include uniquely the directions where we DO have neighbours
+ if len(dummy) == 1 :
+ # This adds a second direction where neighbours are not regarded, it is either 0 or 2
+ dummy.append(2*(dummy[0]+2<4))
+ print("Careful, you have neighbours on 3 or more sides of the box, we will not check if on two parallel sides the boxes are compatible !!!")
+ if len(dummy) == 2 or len(dummy) == 1 :
+ # Sense contains : Vertical then Horizontal
+ Sense = [dummy[1]%2,dummy[0]]
+ DirList = [[1,0][dummy[0]],[3,2][dummy[1]%2]]
+ for index,Direction in enumerate(DirList) :
+ ObjList = List[Direction]
+ RankMin = []
+ ToLook0 = [2,2,0,0][Direction]
+ ToLook1 = [3,2,1,0][Direction]
+ for index1,ObjID in enumerate(ObjList) :
+ RankMin.append([-1.,1.][Sense[index]] * FindCommonSide(Config.ListObj[ObjID].DirBoundaries(ToLook1),[X0-DX/2.,X0+DX/2.,Y0-DY/2.,Y0+DY/2.][ToLook0:ToLook0+2])[Sense[index]])
+ Output[Direction] = SortList(ObjList,RankMin)
+
+ elif len(dummy) == 3 :
+ # We find the direction where we do have neighbours and then we sort the object list along it
+ Sense = dummy[0]%2
+ Direction = [ i not in dummy for i in range(4) ].index(True)
+ ObjList = List[Direction]
+ RankMin = []
+ ToLook0 = [2,2,0,0][Direction]
+ ToLook1 = [3,2,1,0][Direction]
+ for index1,ObjID in enumerate(ObjList) :
+ RankMin.append([-1.,1.][Sense] * FindCommonSide(Config.ListObj[ObjID].DirBoundaries(ToLook1),[X0-DX/2.,X0+DX/2.,Y0-DY/2.,Y0+DY/2.][ToLook0:ToLook0+2])[Sense])
+ Output[Direction] = SortList(ObjList,RankMin)
+ else :
+ print ("Error : the composite box being created has no neighbours, how on earth do you want us to inherit its mesh parameters!!!")
+
+
+ return Output
+
def IndexMultiOcc (Array,Element) :
- """
- This functions returns the occurrences indices of Element in Array.
- As opposed to Array.index(Element) method, this allows determining
- multiple entries rather than just the first one!
- """
- Output = []
- try : Array.index(Element)
- except ValueError : print "No more occurrences"
- else : Output.append(Array.index(Element))
-
- if not(Output == []) and len(Array) > 1 :
- for index, ArrElem in enumerate(Array[Output[0]+1:]) :
- if ArrElem == Element : Output.append(index+Output[0]+1)
-
- return Output
-
+ """
+ This functions returns the occurrences indices of Element in Array.
+ As opposed to Array.index(Element) method, this allows determining
+ multiple entries rather than just the first one!
+ """
+ Output = []
+ try : Array.index(Element)
+ except ValueError : print "No more occurrences"
+ else : Output.append(Array.index(Element))
+
+ if not(Output == []) and len(Array) > 1 :
+ for index, ArrElem in enumerate(Array[Output[0]+1:]) :
+ if ArrElem == Element : Output.append(index+Output[0]+1)
+
+ return Output
+
def SortList (ValList, CritList):
- Output = []
- SortedCritList = copy.copy(CritList)
- SortedCritList.sort()
- for i in range(0,len(ValList)):
- index = CritList.index(SortedCritList[i])
- Output.append(ValList[index])
- return Output
+ Output = []
+ SortedCritList = copy.copy(CritList)
+ SortedCritList.sort()
+ for i in range(0,len(ValList)):
+ index = CritList.index(SortedCritList[i])
+ Output.append(ValList[index])
+ return Output
def ExtrapPoint (Ptref,Vref1,Vref2,Delta):
- """
- This function allows determining the absolute coordinates of an extrapolation point
- as shown in the following :
-
-
- ExtrapPoint x---Vref2->--------o
- / delta_glob |Vref1
- / |
- Ptref x---------------------+
- delta_loc * Nseg
-
- Delta = (delta_loc - delta_glob) * Nseg
- """
-
- X = Ptref[0] + Vref1[0] + Delta*Vref2[0]
- Y = Ptref[1] + Vref1[1] + Delta*Vref2[1]
- return (X,Y,)
-
+ """
+ This function allows determining the absolute coordinates of an extrapolation point
+ as shown in the following :
+
+
+ ExtrapPoint x---Vref2->--------o
+ / delta_glob |Vref1
+ / |
+ Ptref x---------------------+
+ delta_loc * Nseg
+
+ Delta = (delta_loc - delta_glob) * Nseg
+ """
+
+ X = Ptref[0] + Vref1[0] + Delta*Vref2[0]
+ Y = Ptref[1] + Vref1[1] + Delta*Vref2[1]
+ return (X,Y,)
def Go(GeoObj, CutPlnLst, OutLvlLst, PrefixLst, Publish):
- """
- This function cuts any geometry (with infinite trim !) into several subgeometries that are cleanly saved inside the navigation tree. (Check GoTrim for the same functionality with custom trim size)
- - GeoObj is the geometrical object to be cut and grouped
- - CutPlnLst is a list of plane definitions. Each plane is a 6-tuple (contains 6 values). The first three represent the coordinates of the origin point and the second three represent the coordinates of the normal vector to the plane
- Example 1: [(0,0,0,1,0,0)]: cut along a plane passing through the origin and normal to the x-axis
- Example 2: [(0,0,0,1,0,0),(50,0,0,0,1,0)]: in addition to the first plane cut, cut through a plane passing by (50,0,0) and normal to the y axis.
- Note that the plane size us determined automatically from the size of the geometry in question (using a very big trim size = 100 x length of geometry!)
- - OutLvlLst is a list containing integers that represent the inner sectioning level with respect to the original geometry type
- A value of 1 means that the section will provide elements of one level lower than the original type. For example a solid sectioned at level 1 will produce faces. A Face sectioned at level 1 will produce edges.
- A value of 2 means that a deeper sectioning will be applied. A solid sectioned with level 2 will give faces and edges. A face will give edges and vertices. An edge will give only vertices
- The number of elements in this list should be (this is verified in the code) equal to the number of elements in the plane cut list. This is logical.
- Example 1: [1]
- Example 2: [1, 2], This means that the cut over the second plane will produce two types of elements unlike the first cut which will only output the first level objects.
- - PrefixLst is a list of strings that contains the naming Prefixes that are used by the script to generate the subshape names. This is very useful for relating the results to the sectioning requested.
- Example 1: ['Entry']
- Example 2: ['Entry','Exit'] The resulting groups from the sectioning with plane no.1 will then be saved as "Entry_FACE" and/or "Entry_EDGE" according to the original geometry object type and the cutting level
-
- Imagine that we have a solid called ExampleSolid, an example command will be:
- CutnGroup.Go(ExampleSolid,[(0,0,0,1,0,0),(50,0,0,0,1,0)],[1, 2],['Entry','Exit'])
- """
-
- NumCuts = CheckInput(CutPlnLst, OutLvlLst, PrefixLst, 1)
- OrigType = FindStandType(GeoObj,0)
- InvDictionary = dict((v,k) for k, v in geompy.ShapeType.iteritems()) # Give geometry type name as a function of standard type numbering, ex: 4=FACE, 6=EDGE, 7=VERTEX
- TrimSize = geompy.BasicProperties(GeoObj)[0]*100
- CutPlane = [] ; Sections = [] ; Parts = []
-
- if NumCuts:
- for i in range(0, NumCuts): # Loop over the cutting planes to create them one by one
- CutPlane.append(CreatePlane(CutPlnLst[i],TrimSize))
- OutFather = geompy.MakePartition([GeoObj],CutPlane, [], [],FindStandType(GeoObj,1), 0, [], 0) #Creating the partition object
- if Publish: geompy.addToStudy(OutFather,'SectionedObject')
- for i in range(0, NumCuts):
- for j in range(OrigType+1+2, OrigType+1+2*(OutLvlLst[i]+1),2):
- if j == 8 : j = 7; # Exception for the vertex case (=7)
- PossSubShapesID = geompy.SubShapeAllIDs(OutFather,j) # List of subshape IDs than correspond to the required cutting level (section type : face/wire/vertex)
- PossSubShapes = geompy.ExtractShapes(OutFather,j) # and the corresponding objects
- Accepted = []
- for k in range(0,len(PossSubShapesID)): # Loop over all the subshapes checking if they belong to the cutting plane! if yes add them to current list
- if IsOnPlane(PossSubShapes[k], CutPlnLst[i], 1e-7):
- Accepted.append(PossSubShapesID[k])
- if Accepted : # If some element is found, save it as a group with the prescribed Prefix
- dummyObj = geompy.CreateGroup(OutFather, j)
- geompy.UnionIDs(dummyObj, Accepted)
- Sections.append(dummyObj)
- if Publish:geompy.addToStudyInFather(OutFather, dummyObj, PrefixLst[i]+"_"+InvDictionary[j][0:2])
- else :
- print "Warning: For the section no.", i, ", No intersection of type " + InvDictionary[j] + " was found. Hence, no corresponding groups were created"
-
- SubShapesID = geompy.SubShapeAllIDs(OutFather,OrigType+1) # Saving also the groups corresponding to the sectioned item of the same type: ex. A solid into n sub-solids due to the sections
- for i in range(0,len(SubShapesID)):
- dummyObj = geompy.CreateGroup(OutFather, OrigType+1)
- geompy.UnionIDs(dummyObj, [SubShapesID[i]])
- Parts.append(dummyObj)
- if Publish: geompy.addToStudyInFather(OutFather, dummyObj, "SB"+"_"+InvDictionary[OrigType+1][0:3]+"_"+str(i+1))
-
- return OutFather, Sections, Parts
- else:
- print("Fatal error, the routine cannot continue any further, check your input variables")
- return -1
+ """
+ This function cuts any geometry (with infinite trim !) into several subgeometries that are cleanly saved inside the navigation tree. (Check GoTrim for the same functionality with custom trim size)
+ - GeoObj is the geometrical object to be cut and grouped
+ - CutPlnLst is a list of plane definitions. Each plane is a 6-tuple (contains 6 values). The first three represent the coordinates of the origin point and the second three represent the coordinates of the normal vector to the plane
+ Example 1: [(0,0,0,1,0,0)]: cut along a plane passing through the origin and normal to the x-axis
+ Example 2: [(0,0,0,1,0,0),(50,0,0,0,1,0)]: in addition to the first plane cut, cut through a plane passing by (50,0,0) and normal to the y axis.
+ Note that the plane size us determined automatically from the size of the geometry in question (using a very big trim size = 100 x length of geometry!)
+ - OutLvlLst is a list containing integers that represent the inner sectioning level with respect to the original geometry type
+ A value of 1 means that the section will provide elements of one level lower than the original type. For example a solid sectioned at level 1 will produce faces. A Face sectioned at level 1 will produce edges.
+ A value of 2 means that a deeper sectioning will be applied. A solid sectioned with level 2 will give faces and edges. A face will give edges and vertices. An edge will give only vertices
+ The number of elements in this list should be (this is verified in the code) equal to the number of elements in the plane cut list. This is logical.
+ Example 1: [1]
+ Example 2: [1, 2], This means that the cut over the second plane will produce two types of elements unlike the first cut which will only output the first level objects.
+ - PrefixLst is a list of strings that contains the naming Prefixes that are used by the script to generate the subshape names. This is very useful for relating the results to the sectioning requested.
+ Example 1: ['Entry']
+ Example 2: ['Entry','Exit'] The resulting groups from the sectioning with plane no.1 will then be saved as "Entry_FACE" and/or "Entry_EDGE" according to the original geometry object type and the cutting level
+
+ Imagine that we have a solid called ExampleSolid, an example command will be:
+ CutnGroup.Go(ExampleSolid,[(0,0,0,1,0,0),(50,0,0,0,1,0)],[1, 2],['Entry','Exit'])
+ """
+
+ NumCuts = CheckInput(CutPlnLst, OutLvlLst, PrefixLst, 1)
+ OrigType = FindStandType(GeoObj,0)
+ InvDictionary = dict((v,k) for k, v in geompy.ShapeType.iteritems()) # Give geometry type name as a function of standard type numbering, ex: 4=FACE, 6=EDGE, 7=VERTEX
+ TrimSize = geompy.BasicProperties(GeoObj)[0]*100
+ CutPlane = [] ; Sections = [] ; Parts = []
+
+ if NumCuts:
+ for i in range(0, NumCuts): # Loop over the cutting planes to create them one by one
+ CutPlane.append(CreatePlane(CutPlnLst[i],TrimSize))
+ OutFather = geompy.MakePartition([GeoObj],CutPlane, [], [],FindStandType(GeoObj,1), 0, [], 0) #Creating the partition object
+ if Publish: geompy.addToStudy(OutFather,'SectionedObject')
+ for i in range(0, NumCuts):
+ for j in range(OrigType+1+2, OrigType+1+2*(OutLvlLst[i]+1),2):
+ if j == 8 : j = 7; # Exception for the vertex case (=7)
+ PossSubShapesID = geompy.SubShapeAllIDs(OutFather,j) # List of subshape IDs than correspond to the required cutting level (section type : face/wire/vertex)
+ PossSubShapes = geompy.ExtractShapes(OutFather,j) # and the corresponding objects
+ Accepted = []
+ for k in range(0,len(PossSubShapesID)): # Loop over all the subshapes checking if they belong to the cutting plane! if yes add them to current list
+ if IsOnPlane(PossSubShapes[k], CutPlnLst[i], 1e-7):
+ Accepted.append(PossSubShapesID[k])
+ if Accepted : # If some element is found, save it as a group with the prescribed Prefix
+ dummyObj = geompy.CreateGroup(OutFather, j)
+ geompy.UnionIDs(dummyObj, Accepted)
+ Sections.append(dummyObj)
+ if Publish:geompy.addToStudyInFather(OutFather, dummyObj, PrefixLst[i]+"_"+InvDictionary[j][0:2])
+ else :
+ print "Warning: For the section no.", i, ", No intersection of type " + InvDictionary[j] + " was found. Hence, no corresponding groups were created"
+
+ SubShapesID = geompy.SubShapeAllIDs(OutFather,OrigType+1) # Saving also the groups corresponding to the sectioned item of the same type: ex. A solid into n sub-solids due to the sections
+ for i in range(0,len(SubShapesID)):
+ dummyObj = geompy.CreateGroup(OutFather, OrigType+1)
+ geompy.UnionIDs(dummyObj, [SubShapesID[i]])
+ Parts.append(dummyObj)
+ if Publish: geompy.addToStudyInFather(OutFather, dummyObj, "SB"+"_"+InvDictionary[OrigType+1][0:3]+"_"+str(i+1))
+
+ return OutFather, Sections, Parts
+ else:
+ print("Fatal error, the routine cannot continue any further, check your input variables")
+ return -1
def GoTrim(GeoObj, CutPlnLst, OutLvlLst, PrefixLst, Publish):
- """
- This function cuts any geometry into several subgeometries that are cleanly saved inside the navigation tree with a fully customizable trim size.
- - GeoObj is the geometrical object to be cut and grouped
- - CutPlnLst is a list of plane definitions. Each plane is a 7-tuple (contains 7 values). The first three represent the coordinates of the origin point and the second three represent the coordinates of the normal vector to the plane, the last value corresponds to the trim size of the planes
- Example 1: [(0,0,0,1,0,0,5)]: cut along a plane passing through the origin and normal to the x-axis with a trim size of 5
- Example 2: [(0,0,0,1,0,0,5),(50,0,0,0,1,0,10)]: in addition to the first plane cut, cut through a plane passing by (50,0,0) and normal to the y axis with a trim size of 10
- - OutLvlLst is a list containing integers that represent the inner sectioning level with respect to the original geometry type
- A value of 1 means that the section will provide elements of one level lower than the original type. For example a solid sectioned at level 1 will produce faces. A Face sectioned at level 1 will produce edges.
- A value of 2 means that a deeper sectioning will be applied. A solid sectioned with level 2 will give faces and edges. A face will give edges and vertices. An edge will give only vertices
- The number of elements in this list should be (this is verified in the code) equal to the number of elements in the plane cut list. This is logical.
- Example 1: [1]
- Example 2: [1, 2], This means that the cut over the second plane will produce two types of elements unlike the first cut which will only output the first level objects.
- - PrefixLst is a list of strings that contains the naming Prefixes that are used by the script to generate the subshape names. This is very useful for relating the results to the sectioning requested.
- Example 1: ['Entry']
- Example 2: ['Entry','Exit'] The resulting groups from the sectioning with plane no.1 will then be saved as "Entry_FACE" and/or "Entry_EDGE" according to the original geometry object type and the cutting level
-
- Imagine that we have a solid called ExampleSolid, an example command will be:
- CutnGroup.Go(ExampleSolid,[(0,0,0,1,0,0,5),(50,0,0,0,1,0,10)],[1, 2],['Entry','Exit'])
- """
-
- NumCuts = CheckInput(CutPlnLst, OutLvlLst, PrefixLst, 0)
- OrigType = FindStandType(GeoObj,0)
- InvDictionary = dict((v,k) for k, v in geompy.ShapeType.iteritems()) # Give geometry type name as a function of standard type numbering, ex: 4=FACE, 6=EDGE, 7=VERTEX
- CutPlane = [] ; Sections = [] ; Parts = []
- if NumCuts:
- for i in range(0, NumCuts): # Loop over the cutting planes to create them one by one
- CutPlane.append(CreatePlane(CutPlnLst[i][0:6],CutPlnLst[i][6]))
- OutFather = geompy.MakePartition([GeoObj],CutPlane, [], [],FindStandType(GeoObj,1), 0, [], 0) #Creating the partition object
- if Publish: geompy.addToStudy(OutFather,'SectionedObject')
- for i in range(0, NumCuts):
- for j in range(OrigType+1+2, OrigType+1+2*(OutLvlLst[i]+1),2):
- if j == 8 : j = 7; # Exception for the vertex case (=7)
- PossSubShapesID = geompy.SubShapeAllIDs(OutFather,j) # List of subshape IDs than correspond to the required cutting level (section type : face/wire/vertex)
- PossSubShapes = geompy.ExtractShapes(OutFather,j) # and the corresponding objects
- Accepted = []
- for k in range(0,len(PossSubShapesID)): # Loop over all the subshapes checking if they belong to the cutting plane WITH THE TRIM SIZE CONDITION! if yes add them to current list
- if IsOnPlane(PossSubShapes[k], CutPlnLst[i], 1e-7) and Distance2Pt(geompy.PointCoordinates(geompy.MakeCDG(PossSubShapes[k])),CutPlnLst[i][0:3])<=CutPlnLst[i][-1]:
- Accepted.append(PossSubShapesID[k])
- if Accepted : # If some element is found, save it as a group with the prescribed Prefix
- dummyObj = geompy.CreateGroup(OutFather, j)
- geompy.UnionIDs(dummyObj, Accepted)
- Sections.append(dummyObj)
- if Publish: geompy.addToStudyInFather(OutFather, dummyObj, PrefixLst[i]+"_"+InvDictionary[j][0:2])
- else :
- print "Warning: For the section no.", i, ", No intersection of type " + InvDictionary[j] + " was found. Hence, no corresponding groups were created"
-
- SubShapesID = geompy.SubShapeAllIDs(OutFather,OrigType+1) # Saving also the groups corresponding to the sectioned item of the same type: ex. A solid into n sub-solids due to the sections
- for i in range(0,len(SubShapesID)):
- dummyObj = geompy.CreateGroup(OutFather, OrigType+1)
- geompy.UnionIDs(dummyObj, [SubShapesID[i]])
- Parts.append(dummyObj)
- if Publish: geompy.addToStudyInFather(OutFather, dummyObj, "SB"+"_"+InvDictionary[OrigType+1][0:3]+"_"+str(i+1))
-
- return OutFather, Sections, Parts
- else:
- print("Fatal error, the routine cannot continue any further, check your input variables")
- return -1
+ """
+ This function cuts any geometry into several subgeometries that are cleanly saved inside the navigation tree with a fully customizable trim size.
+ - GeoObj is the geometrical object to be cut and grouped
+ - CutPlnLst is a list of plane definitions. Each plane is a 7-tuple (contains 7 values). The first three represent the coordinates of the origin point and the second three represent the coordinates of the normal vector to the plane, the last value corresponds to the trim size of the planes
+ Example 1: [(0,0,0,1,0,0,5)]: cut along a plane passing through the origin and normal to the x-axis with a trim size of 5
+ Example 2: [(0,0,0,1,0,0,5),(50,0,0,0,1,0,10)]: in addition to the first plane cut, cut through a plane passing by (50,0,0) and normal to the y axis with a trim size of 10
+ - OutLvlLst is a list containing integers that represent the inner sectioning level with respect to the original geometry type
+ A value of 1 means that the section will provide elements of one level lower than the original type. For example a solid sectioned at level 1 will produce faces. A Face sectioned at level 1 will produce edges.
+ A value of 2 means that a deeper sectioning will be applied. A solid sectioned with level 2 will give faces and edges. A face will give edges and vertices. An edge will give only vertices
+ The number of elements in this list should be (this is verified in the code) equal to the number of elements in the plane cut list. This is logical.
+ Example 1: [1]
+ Example 2: [1, 2], This means that the cut over the second plane will produce two types of elements unlike the first cut which will only output the first level objects.
+ - PrefixLst is a list of strings that contains the naming Prefixes that are used by the script to generate the subshape names. This is very useful for relating the results to the sectioning requested.
+ Example 1: ['Entry']
+ Example 2: ['Entry','Exit'] The resulting groups from the sectioning with plane no.1 will then be saved as "Entry_FACE" and/or "Entry_EDGE" according to the original geometry object type and the cutting level
+
+ Imagine that we have a solid called ExampleSolid, an example command will be:
+ CutnGroup.Go(ExampleSolid,[(0,0,0,1,0,0,5),(50,0,0,0,1,0,10)],[1, 2],['Entry','Exit'])
+ """
+
+ NumCuts = CheckInput(CutPlnLst, OutLvlLst, PrefixLst, 0)
+ OrigType = FindStandType(GeoObj,0)
+ InvDictionary = dict((v,k) for k, v in geompy.ShapeType.iteritems()) # Give geometry type name as a function of standard type numbering, ex: 4=FACE, 6=EDGE, 7=VERTEX
+ CutPlane = [] ; Sections = [] ; Parts = []
+ if NumCuts:
+ for i in range(0, NumCuts): # Loop over the cutting planes to create them one by one
+ CutPlane.append(CreatePlane(CutPlnLst[i][0:6],CutPlnLst[i][6]))
+ OutFather = geompy.MakePartition([GeoObj],CutPlane, [], [],FindStandType(GeoObj,1), 0, [], 0) #Creating the partition object
+ if Publish: geompy.addToStudy(OutFather,'SectionedObject')
+ for i in range(0, NumCuts):
+ for j in range(OrigType+1+2, OrigType+1+2*(OutLvlLst[i]+1),2):
+ if j == 8 : j = 7; # Exception for the vertex case (=7)
+ PossSubShapesID = geompy.SubShapeAllIDs(OutFather,j) # List of subshape IDs than correspond to the required cutting level (section type : face/wire/vertex)
+ PossSubShapes = geompy.ExtractShapes(OutFather,j) # and the corresponding objects
+ Accepted = []
+ for k in range(0,len(PossSubShapesID)): # Loop over all the subshapes checking if they belong to the cutting plane WITH THE TRIM SIZE CONDITION! if yes add them to current list
+ if IsOnPlane(PossSubShapes[k], CutPlnLst[i], 1e-7) and Distance2Pt(geompy.PointCoordinates(geompy.MakeCDG(PossSubShapes[k])),CutPlnLst[i][0:3])<=CutPlnLst[i][-1]:
+ Accepted.append(PossSubShapesID[k])
+ if Accepted : # If some element is found, save it as a group with the prescribed Prefix
+ dummyObj = geompy.CreateGroup(OutFather, j)
+ geompy.UnionIDs(dummyObj, Accepted)
+ Sections.append(dummyObj)
+ if Publish: geompy.addToStudyInFather(OutFather, dummyObj, PrefixLst[i]+"_"+InvDictionary[j][0:2])
+ else :
+ print "Warning: For the section no.", i, ", No intersection of type " + InvDictionary[j] + " was found. Hence, no corresponding groups were created"
+
+ SubShapesID = geompy.SubShapeAllIDs(OutFather,OrigType+1) # Saving also the groups corresponding to the sectioned item of the same type: ex. A solid into n sub-solids due to the sections
+ for i in range(0,len(SubShapesID)):
+ dummyObj = geompy.CreateGroup(OutFather, OrigType+1)
+ geompy.UnionIDs(dummyObj, [SubShapesID[i]])
+ Parts.append(dummyObj)
+ if Publish: geompy.addToStudyInFather(OutFather, dummyObj, "SB"+"_"+InvDictionary[OrigType+1][0:3]+"_"+str(i+1))
+
+ return OutFather, Sections, Parts
+ else:
+ print("Fatal error, the routine cannot continue any further, check your input variables")
+ return -1
def FindStandType(GeoObj, method):
- """
- Find the standard index for the Geometrical object/compound type input, see dictionary in geompy.ShapeType
- """
- TopType = GeoObj.GetMaxShapeType().__str__()
- UnModType = geompy.ShapeType[TopType]
- if method == 0 :
- StandType = UnModType-int(not(UnModType%2)) # So that wires and edges and considered the same, faces and shells, and so on
- else :
- StandType = UnModType
-
- return(StandType)
+ """
+ Find the standard index for the Geometrical object/compound type input, see dictionary in geompy.ShapeType
+ """
+ TopType = GeoObj.GetMaxShapeType().__str__()
+ UnModType = geompy.ShapeType[TopType]
+ if method == 0 :
+ StandType = UnModType-int(not(UnModType%2)) # So that wires and edges and considered the same, faces and shells, and so on
+ else :
+ StandType = UnModType
+
+ return(StandType)
def CreatePlane(CutPlnVar,Trim):
- """
- Creates a temporary point and vector in salome in order to build the sectioning planes needed
- """
- Temp_Vtx = geompy.MakeVertex(CutPlnVar[0], CutPlnVar[1], CutPlnVar[2])
- Temp_Vec = geompy.MakeVectorDXDYDZ(CutPlnVar[3], CutPlnVar[4], CutPlnVar[5])
- CutPlane = geompy.MakePlane(Temp_Vtx, Temp_Vec, Trim)
- return(CutPlane)
+ """
+ Creates a temporary point and vector in salome in order to build the sectioning planes needed
+ """
+ Temp_Vtx = geompy.MakeVertex(CutPlnVar[0], CutPlnVar[1], CutPlnVar[2])
+ Temp_Vec = geompy.MakeVectorDXDYDZ(CutPlnVar[3], CutPlnVar[4], CutPlnVar[5])
+ CutPlane = geompy.MakePlane(Temp_Vtx, Temp_Vec, Trim)
+ return(CutPlane)
def CheckInput(CutPlnLst, OutLvlLst, PrefixLst, AutoTrim):
- """
- Checks the user input specifically if all needed parameters are provided
- """
- if not ((len(CutPlnLst) == len(OutLvlLst)) and (len(CutPlnLst) == len(PrefixLst))):
- print("Missing information about one or more of the cut planes")
- return 0
- elif not ((len(CutPlnLst[0]) == 6+int(not AutoTrim))):
- print("For each cutting plane you need to specify 6 parameters = 2 x 3 coordinates")
- return 0
- else:
- return len(CutPlnLst)
+ """
+ Checks the user input specifically if all needed parameters are provided
+ """
+ if not ((len(CutPlnLst) == len(OutLvlLst)) and (len(CutPlnLst) == len(PrefixLst))):
+ print("Missing information about one or more of the cut planes")
+ return 0
+ elif not ((len(CutPlnLst[0]) == 6+int(not AutoTrim))):
+ print("For each cutting plane you need to specify 6 parameters = 2 x 3 coordinates")
+ return 0
+ else:
+ return len(CutPlnLst)
def IsOnPlane(GeoSubObj, CutPlnVar, tolerance):
- """
- Checks whether a geometry (vertex, segment, or face) belongs *completely* to the plane defined as a point and a normal vector
- """
- # lambda function that represents the plane equation, function = 0 <=> Pt defined with Coor belongs to plane
- PlaneEq = lambda Coor: CutPlnVar[3]*(Coor[0]-CutPlnVar[0])+CutPlnVar[4]*(Coor[1]-CutPlnVar[1])+CutPlnVar[5]*(Coor[2]-CutPlnVar[2])
- OrigType = FindStandType(GeoSubObj,0)
- if (OrigType >= 7): # Vertex
- NonTrimDecision = abs(PlaneEq(geompy.PointCoordinates(GeoSubObj))) < tolerance
- if len(CutPlnVar) == 6 : return NonTrimDecision # No trim condition used
- else : return (NonTrimDecision and Distance2Pt(CutPlnVar[0:3],geompy.PointCoordinates(GeoSubObj))<=CutPlnVar[6]/2)
- elif (OrigType >= 5): # Line, decompose into two points then call recursively IsOnPlane function!
- Verdict = True
- for i in range(0,2):
- Verdict = Verdict and IsOnPlane(geompy.GetVertexByIndex(GeoSubObj,i), CutPlnVar, tolerance)
- return Verdict
- elif (OrigType >= 3): # Face, decompose into three points then call recursively IsOnPlane function!
- if IsOnPlane(geompy.MakeCDG(GeoSubObj),CutPlnVar, tolerance) : # Center of gravity belongs to plane, check if normal is parallel to plane
- NormalP1Coor = geompy.PointCoordinates(geompy.GetVertexByIndex(geompy.GetNormal(GeoSubObj),0))
- NormalP2Coor = geompy.PointCoordinates(geompy.GetVertexByIndex(geompy.GetNormal(GeoSubObj),1))
- Normal = [NormalP1Coor[0]-NormalP2Coor[0], NormalP1Coor[1]-NormalP2Coor[1], NormalP1Coor[2]-NormalP2Coor[2]]
- CrossP = CrossProd(CutPlnVar[3:6],Normal) # Checks whether normals (of section plane and of face) are parallel or not
- if (abs(CrossP[0])<tolerance and abs(CrossP[1])<tolerance and abs(CrossP[2])<tolerance): # meaning zero cross product => parallel
- return True
- else :
- return False
- else :
- return False
+ """
+ Checks whether a geometry (vertex, segment, or face) belongs *completely* to the plane defined as a point and a normal vector
+ """
+ # lambda function that represents the plane equation, function = 0 <=> Pt defined with Coor belongs to plane
+ PlaneEq = lambda Coor: CutPlnVar[3]*(Coor[0]-CutPlnVar[0])+CutPlnVar[4]*(Coor[1]-CutPlnVar[1])+CutPlnVar[5]*(Coor[2]-CutPlnVar[2])
+ OrigType = FindStandType(GeoSubObj,0)
+ if (OrigType >= 7): # Vertex
+ NonTrimDecision = abs(PlaneEq(geompy.PointCoordinates(GeoSubObj))) < tolerance
+ if len(CutPlnVar) == 6 : return NonTrimDecision # No trim condition used
+ else : return (NonTrimDecision and Distance2Pt(CutPlnVar[0:3],geompy.PointCoordinates(GeoSubObj))<=CutPlnVar[6]/2)
+ elif (OrigType >= 5): # Line, decompose into two points then call recursively IsOnPlane function!
+ Verdict = True
+ for i in range(0,2):
+ Verdict = Verdict and IsOnPlane(geompy.GetVertexByIndex(GeoSubObj,i), CutPlnVar, tolerance)
+ return Verdict
+ elif (OrigType >= 3): # Face, decompose into three points then call recursively IsOnPlane function!
+ if IsOnPlane(geompy.MakeCDG(GeoSubObj),CutPlnVar, tolerance) : # Center of gravity belongs to plane, check if normal is parallel to plane
+ NormalP1Coor = geompy.PointCoordinates(geompy.GetVertexByIndex(geompy.GetNormal(GeoSubObj),0))
+ NormalP2Coor = geompy.PointCoordinates(geompy.GetVertexByIndex(geompy.GetNormal(GeoSubObj),1))
+ Normal = [NormalP1Coor[0]-NormalP2Coor[0], NormalP1Coor[1]-NormalP2Coor[1], NormalP1Coor[2]-NormalP2Coor[2]]
+ CrossP = CrossProd(CutPlnVar[3:6],Normal) # Checks whether normals (of section plane and of face) are parallel or not
+ if (abs(CrossP[0])<tolerance and abs(CrossP[1])<tolerance and abs(CrossP[2])<tolerance): # meaning zero cross product => parallel
+ return True
+ else :
+ return False
+ else :
+ return False
def CrossProd(V1,V2):
- """
- Determines the cross product of two 3D vectors
- """
- return ([V1[1]*V2[2]-V1[2]*V2[1], V1[2]*V2[0]-V1[0]*V2[2], V1[0]*V2[1]-V1[1]*V2[0]])
+ """
+ Determines the cross product of two 3D vectors
+ """
+ return ([V1[1]*V2[2]-V1[2]*V2[1], V1[2]*V2[0]-V1[0]*V2[2], V1[0]*V2[1]-V1[1]*V2[0]])
def Distance2Pt(P1,P2):
- """
- Returns the distance between two points
- """
- return (math.sqrt((P1[0]-P2[0])**2+(P1[1]-P2[1])**2+(P1[2]-P2[2])**2))
+ """
+ Returns the distance between two points
+ """
+ return (math.sqrt((P1[0]-P2[0])**2+(P1[1]-P2[1])**2+(P1[2]-P2[2])**2))
-# This is an automation of the cylinder-box object, defined with the coordinates of its center, its radius, and the box's
+# This is an automation of the cylinder-box object, defined with the coordinates of its center, its radius, and the box's
# boundary size.
# The pitch ratio is calculated automatically from the minimum of the box dimensions on x and y.
# This functions can take a groups input containing the group names of 4 sides in addition to the internal circular boundary
from MacObject import *
import Config, GenFunctions
-def Cylinder (X0 , Y0 , D , DX , DY , LocalMeshing , **args) :
- if args.__contains__('DLocal') : DLocal = float(args['DLocal'])
- else : DLocal = float(min(DX,DY))
-
- # K is the pitch ratio
- K = float(D)/(DLocal-D)
- print "A local pitch ratio of K =", K ," will be used. "
- NumCuts = 2*GenFunctions.QuarCylParam(K)
- InternalMeshing = int(math.ceil(math.pi*D/(4*NumCuts*LocalMeshing)))
- if InternalMeshing == 0 : InternalMeshing = 1 # This sets a minimum meshing condition in order to avoid an error. The user is notified of the value considered for the local meshing
- print "Possible Local meshing is :", math.pi*D/(4*NumCuts*InternalMeshing), "\nThis value is returned by this function for your convenience.\n"
- if args.__contains__('groups') :
- GroupNames = args['groups']
- else : GroupNames = [None, None, None, None, None]
-
- if DY == DLocal :
- if DX == DLocal:
- GN1 = [None,GroupNames[1],None,GroupNames[3],GroupNames[4]]
- GN2 = [None,GroupNames[1],GroupNames[2],None,GroupNames[4]]
- GN3 = [GroupNames[0],None,GroupNames[2],None,GroupNames[4]]
- GN4 = [GroupNames[0],None,None,GroupNames[3],GroupNames[4]]
- else :
- GN1 = [None,GroupNames[1],None,None,GroupNames[4]]
- GN2 = [None,GroupNames[1],None,None,GroupNames[4]]
- GN3 = [GroupNames[0],None,None,None,GroupNames[4]]
- GN4 = [GroupNames[0],None,None,None,GroupNames[4]]
-
- GN5 = [GroupNames[0],GroupNames[1],None,GroupNames[3]]
- GN6 = [GroupNames[0],GroupNames[1],GroupNames[2],None]
+def Cylinder (X0 , Y0 , D , DX , DY , LocalMeshing , **args) :
+ if args.__contains__('DLocal') : DLocal = float(args['DLocal'])
+ else : DLocal = float(min(DX,DY))
+
+ # K is the pitch ratio
+ K = float(D)/(DLocal-D)
+ print "A local pitch ratio of K =", K ," will be used. "
+ NumCuts = 2*GenFunctions.QuarCylParam(K)
+ InternalMeshing = int(math.ceil(math.pi*D/(4*NumCuts*LocalMeshing)))
+ if InternalMeshing == 0 : InternalMeshing = 1 # This sets a minimum meshing condition in order to avoid an error. The user is notified of the value considered for the local meshing
+ print "Possible Local meshing is :", math.pi*D/(4*NumCuts*InternalMeshing), "\nThis value is returned by this function for your convenience.\n"
+ if args.__contains__('groups') :
+ GroupNames = args['groups']
+ else : GroupNames = [None, None, None, None, None]
+
+ if DY == DLocal :
+ if DX == DLocal:
+ GN1 = [None,GroupNames[1],None,GroupNames[3],GroupNames[4]]
+ GN2 = [None,GroupNames[1],GroupNames[2],None,GroupNames[4]]
+ GN3 = [GroupNames[0],None,GroupNames[2],None,GroupNames[4]]
+ GN4 = [GroupNames[0],None,None,GroupNames[3],GroupNames[4]]
+ else :
+ GN1 = [None,GroupNames[1],None,None,GroupNames[4]]
+ GN2 = [None,GroupNames[1],None,None,GroupNames[4]]
+ GN3 = [GroupNames[0],None,None,None,GroupNames[4]]
+ GN4 = [GroupNames[0],None,None,None,GroupNames[4]]
+
+ GN5 = [GroupNames[0],GroupNames[1],None,GroupNames[3]]
+ GN6 = [GroupNames[0],GroupNames[1],GroupNames[2],None]
+ else :
+ if DX == DLocal:
+ GN1 = [None,None,None,GroupNames[3],GroupNames[4]]
+ GN2 = [None,None,GroupNames[2],None,GroupNames[4]]
+ GN3 = [None,None,GroupNames[2],None,GroupNames[4]]
+ GN4 = [None,None,None,GroupNames[3],GroupNames[4]]
+ GN7 = [GroupNames[0],None,GroupNames[2],GroupNames[3]]
+ GN8 = [None,GroupNames[1],GroupNames[2],GroupNames[3]]
else :
- if DX == DLocal:
- GN1 = [None,None,None,GroupNames[3],GroupNames[4]]
- GN2 = [None,None,GroupNames[2],None,GroupNames[4]]
- GN3 = [None,None,GroupNames[2],None,GroupNames[4]]
- GN4 = [None,None,None,GroupNames[3],GroupNames[4]]
- GN7 = [GroupNames[0],None,GroupNames[2],GroupNames[3]]
- GN8 = [None,GroupNames[1],GroupNames[2],GroupNames[3]]
- else :
- GN1 = [None,None,None,None,GroupNames[4]]
- GN2 = [None,None,None,None,GroupNames[4]]
- GN3 = [None,None,None,None,GroupNames[4]]
- GN4 = [None,None,None,None,GroupNames[4]]
-
- GN5 = [None,None,None,GroupNames[3]]
- GN6 = [None,None,GroupNames[2],None]
-
- GN9 = [GroupNames[0],None,None,GroupNames[3]]
- GN10 = [GroupNames[0],None,None,None]
- GN11 = [GroupNames[0],None,GroupNames[2],None]
-
- GN12 = [None,GroupNames[1],None,GroupNames[3]]
- GN13 = [None,GroupNames[1],None,None]
- GN14 = [None,GroupNames[1],GroupNames[2],None]
-
- Obj = []
-
- Obj.append(MacObject('QuartCyl',[(X0+DLocal/4.,Y0+DLocal/4.),(DLocal/2.,DLocal/2.)],[InternalMeshing,'NE',K], groups = GN1))
- Obj.append(MacObject('QuartCyl',[(X0-DLocal/4.,Y0+DLocal/4.),(DLocal/2.,DLocal/2.)],['auto','NW',K], groups = GN2))
- Obj.append(MacObject('QuartCyl',[(X0-DLocal/4.,Y0-DLocal/4.),(DLocal/2.,DLocal/2.)],['auto','SW',K], groups = GN3))
- Obj.append(MacObject('QuartCyl',[(X0+DLocal/4.,Y0-DLocal/4.),(DLocal/2.,DLocal/2.)],['auto','SE',K], groups = GN4))
-
- if DX > DLocal :
- dX = (DX - DLocal)/2.
- Obj.append(MacObject('CompBoxF',[(X0+DLocal/2.+dX/2.,Y0),(dX,DLocal)],['auto'], groups = GN5))
- Obj.append(MacObject('CompBoxF',[(X0-DLocal/2.-dX/2.,Y0),(dX,DLocal)],['auto'], groups = GN6))
-
- if DY > DLocal :
- dY = (DY - DLocal)/2.
- if DX > DLocal :
- Obj.append(MacObject('CompBoxF',[(X0+DLocal/2.+dX/2.,Y0-DLocal/2.-dY/2.),(dX,dY)],['auto'], groups = GN9))
- Obj.append(MacObject('CompBoxF',[(X0,Y0-DLocal/2.-dY/2.),(DLocal,dY)],['auto'], groups = GN10))
- Obj.append(MacObject('CompBoxF',[(X0-DLocal/2.-dX/2.,Y0-DLocal/2.-dY/2.),(dX,dY)],['auto'], groups = GN11))
- Obj.append(MacObject('CompBoxF',[(X0+DLocal/2.+dX/2.,Y0+DLocal/2.+dY/2.),(dX,dY)],['auto'], groups = GN12))
- Obj.append(MacObject('CompBoxF',[(X0,Y0+DLocal/2.+dY/2.),(DLocal,dY)],['auto'], groups = GN13))
- Obj.append(MacObject('CompBoxF',[(X0-DLocal/2.-dX/2.,Y0+DLocal/2.+dY/2.),(dX,dY)],['auto'], groups = GN14))
- else:
- Obj.append(MacObject('CompBoxF',[(X0,Y0-DLocal/2.-dY/2.),(DLocal,dY)],['auto'], groups = GN7))
- Obj.append(MacObject('CompBoxF',[(X0,Y0+DLocal/2.+dY/2.),(DLocal,dY)],['auto'], groups = GN8))
-
- return Obj
+ GN1 = [None,None,None,None,GroupNames[4]]
+ GN2 = [None,None,None,None,GroupNames[4]]
+ GN3 = [None,None,None,None,GroupNames[4]]
+ GN4 = [None,None,None,None,GroupNames[4]]
+
+ GN5 = [None,None,None,GroupNames[3]]
+ GN6 = [None,None,GroupNames[2],None]
+
+ GN9 = [GroupNames[0],None,None,GroupNames[3]]
+ GN10 = [GroupNames[0],None,None,None]
+ GN11 = [GroupNames[0],None,GroupNames[2],None]
+
+ GN12 = [None,GroupNames[1],None,GroupNames[3]]
+ GN13 = [None,GroupNames[1],None,None]
+ GN14 = [None,GroupNames[1],GroupNames[2],None]
+
+ Obj = []
+
+ Obj.append(MacObject('QuartCyl',[(X0+DLocal/4.,Y0+DLocal/4.),(DLocal/2.,DLocal/2.)],[InternalMeshing,'NE',K], groups = GN1))
+ Obj.append(MacObject('QuartCyl',[(X0-DLocal/4.,Y0+DLocal/4.),(DLocal/2.,DLocal/2.)],['auto','NW',K], groups = GN2))
+ Obj.append(MacObject('QuartCyl',[(X0-DLocal/4.,Y0-DLocal/4.),(DLocal/2.,DLocal/2.)],['auto','SW',K], groups = GN3))
+ Obj.append(MacObject('QuartCyl',[(X0+DLocal/4.,Y0-DLocal/4.),(DLocal/2.,DLocal/2.)],['auto','SE',K], groups = GN4))
+
+ if DX > DLocal :
+ dX = (DX - DLocal)/2.
+ Obj.append(MacObject('CompBoxF',[(X0+DLocal/2.+dX/2.,Y0),(dX,DLocal)],['auto'], groups = GN5))
+ Obj.append(MacObject('CompBoxF',[(X0-DLocal/2.-dX/2.,Y0),(dX,DLocal)],['auto'], groups = GN6))
+
+ if DY > DLocal :
+ dY = (DY - DLocal)/2.
+ if DX > DLocal :
+ Obj.append(MacObject('CompBoxF',[(X0+DLocal/2.+dX/2.,Y0-DLocal/2.-dY/2.),(dX,dY)],['auto'], groups = GN9))
+ Obj.append(MacObject('CompBoxF',[(X0,Y0-DLocal/2.-dY/2.),(DLocal,dY)],['auto'], groups = GN10))
+ Obj.append(MacObject('CompBoxF',[(X0-DLocal/2.-dX/2.,Y0-DLocal/2.-dY/2.),(dX,dY)],['auto'], groups = GN11))
+ Obj.append(MacObject('CompBoxF',[(X0+DLocal/2.+dX/2.,Y0+DLocal/2.+dY/2.),(dX,dY)],['auto'], groups = GN12))
+ Obj.append(MacObject('CompBoxF',[(X0,Y0+DLocal/2.+dY/2.),(DLocal,dY)],['auto'], groups = GN13))
+ Obj.append(MacObject('CompBoxF',[(X0-DLocal/2.-dX/2.,Y0+DLocal/2.+dY/2.),(dX,dY)],['auto'], groups = GN14))
+ else:
+ Obj.append(MacObject('CompBoxF',[(X0,Y0-DLocal/2.-dY/2.),(DLocal,dY)],['auto'], groups = GN7))
+ Obj.append(MacObject('CompBoxF',[(X0,Y0+DLocal/2.+dY/2.),(DLocal,dY)],['auto'], groups = GN8))
+
+ return Obj
##########################################################################################################
def Box11 (MacObject):
- if Config.debug : print "Generating regular box"
+ if Config.debug : print "Generating regular box"
- dummy1 = geompy.MakeScaleAlongAxes( ElemBox11 (), None , MacObject.GeoPar[1][0], MacObject.GeoPar[1][1], 1)
- RectFace = geompy.MakeTranslation(dummy1, MacObject.GeoPar[0][0], MacObject.GeoPar[0][1], 0)
+ dummy1 = geompy.MakeScaleAlongAxes( ElemBox11 (), None , MacObject.GeoPar[1][0], MacObject.GeoPar[1][1], 1)
+ RectFace = geompy.MakeTranslation(dummy1, MacObject.GeoPar[0][0], MacObject.GeoPar[0][1], 0)
- MacObject.GeoChildren.append(RectFace)
- MacObject.GeoChildrenNames.append("Box_"+ str(len(Config.ListObj)+1))
-
- if Config.debug : Publish (MacObject.GeoChildren,MacObject.GeoChildrenNames)
+ MacObject.GeoChildren.append(RectFace)
+ MacObject.GeoChildrenNames.append("Box_"+ str(len(Config.ListObj)+1))
- if Config.publish :
- MacObject.Mesh.append(smesh.Mesh(RectFace)) # Creation of a new mesh
- Quad2D = MacObject.Mesh[0].Quadrangle() # Applying a quadrangle hypothesis
+ if Config.debug : Publish (MacObject.GeoChildren,MacObject.GeoChildrenNames)
- EdgeIDs = geompy.SubShapeAllSorted(RectFace,6) # List of Edge IDs belonging to RectFace, 6 = Edge in salome dictionary
- Reg1D = MacObject.Mesh[0].Segment()
- Reg1D.NumberOfSegments(MacObject.MeshPar[0])
+ if Config.publish :
+ MacObject.Mesh.append(smesh.Mesh(RectFace)) # Creation of a new mesh
+ Quad2D = MacObject.Mesh[0].Quadrangle() # Applying a quadrangle hypothesis
- MacObject.Mesh[0].Compute() # Generates the mesh
-
- MacObject.DirectionalMeshParams = [MacObject.MeshPar[0],MacObject.MeshPar[0],MacObject.MeshPar[0],MacObject.MeshPar[0]]
+ EdgeIDs = geompy.SubShapeAllSorted(RectFace,6) # List of Edge IDs belonging to RectFace, 6 = Edge in salome dictionary
+ Reg1D = MacObject.Mesh[0].Segment()
+ Reg1D.NumberOfSegments(MacObject.MeshPar[0])
- MacObject.status = 1
- Config.ListObj.append(MacObject)
- return MacObject
+ MacObject.Mesh[0].Compute() # Generates the mesh
+
+ MacObject.DirectionalMeshParams = [MacObject.MeshPar[0],MacObject.MeshPar[0],MacObject.MeshPar[0],MacObject.MeshPar[0]]
+
+ MacObject.status = 1
+ Config.ListObj.append(MacObject)
+ return MacObject
##########################################################################################################
def Box42 (MacObject):
- if Config.debug : print "Generating box 4-2 reducer"
+ if Config.debug : print "Generating box 4-2 reducer"
+
+ Z_Axis = geompy.MakeVectorDXDYDZ(0., 0., 1.)
+ RotAngle = {'SN' : lambda : 0,
+ 'NS' : lambda : math.pi,
+ 'EW' : lambda : math.pi/2,
+ 'WE' : lambda : -math.pi/2, }[MacObject.MeshPar[1]]()
+ dummy0 = geompy.MakeRotation( ElemBox42 () , Z_Axis, RotAngle )
+ dummy1 = geompy.MakeScaleAlongAxes( dummy0, None , MacObject.GeoPar[1][0], MacObject.GeoPar[1][1], 1)
+ RectFace = geompy.MakeTranslation(dummy1, MacObject.GeoPar[0][0], MacObject.GeoPar[0][1], 0)
- Z_Axis = geompy.MakeVectorDXDYDZ(0., 0., 1.)
- RotAngle = {'SN' : lambda : 0,
- 'NS' : lambda : math.pi,
- 'EW' : lambda : math.pi/2,
- 'WE' : lambda : -math.pi/2, }[MacObject.MeshPar[1]]()
- dummy0 = geompy.MakeRotation( ElemBox42 () , Z_Axis, RotAngle )
- dummy1 = geompy.MakeScaleAlongAxes( dummy0, None , MacObject.GeoPar[1][0], MacObject.GeoPar[1][1], 1)
- RectFace = geompy.MakeTranslation(dummy1, MacObject.GeoPar[0][0], MacObject.GeoPar[0][1], 0)
+ MacObject.GeoChildren.append(RectFace)
+ MacObject.GeoChildrenNames.append("Box_"+ str(len(Config.ListObj)+1))
- MacObject.GeoChildren.append(RectFace)
- MacObject.GeoChildrenNames.append("Box_"+ str(len(Config.ListObj)+1))
-
- if Config.debug : Publish (MacObject.GeoChildren,MacObject.GeoChildrenNames)
+ if Config.debug : Publish (MacObject.GeoChildren,MacObject.GeoChildrenNames)
- if Config.publish :
- MacObject.Mesh.append(smesh.Mesh(RectFace)) # Creation of a new mesh
- Quad2D = MacObject.Mesh[0].Quadrangle() # Applying a quadrangle hypothesis
+ if Config.publish :
+ MacObject.Mesh.append(smesh.Mesh(RectFace)) # Creation of a new mesh
+ Quad2D = MacObject.Mesh[0].Quadrangle() # Applying a quadrangle hypothesis
- EdgeIDs = geompy.SubShapeAllSorted(RectFace,6) # List of Edge IDs belonging to RectFace, 6 = Edge in salome dictionary
- Reg1D = MacObject.Mesh[0].Segment()
- Reg1D.NumberOfSegments(MacObject.MeshPar[0])
+ EdgeIDs = geompy.SubShapeAllSorted(RectFace,6) # List of Edge IDs belonging to RectFace, 6 = Edge in salome dictionary
+ Reg1D = MacObject.Mesh[0].Segment()
+ Reg1D.NumberOfSegments(MacObject.MeshPar[0])
- MacObject.Mesh[0].Compute() # Generates the mesh
+ MacObject.Mesh[0].Compute() # Generates the mesh
- MacObject.status = 1
+ MacObject.status = 1
- x = MacObject.MeshPar[0]
- MacObject.DirectionalMeshParams = {'SN' : lambda : [3*x, 3*x, 4*x, 2*x],
- 'NS' : lambda : [3*x, 3*x, 2*x, 4*x],
- 'EW' : lambda : [2*x, 4*x, 3*x, 3*x],
- 'WE' : lambda : [4*x, 2*x, 3*x, 3*x], }[MacObject.MeshPar[1]]()
+ x = MacObject.MeshPar[0]
+ MacObject.DirectionalMeshParams = {'SN' : lambda : [3*x, 3*x, 4*x, 2*x],
+ 'NS' : lambda : [3*x, 3*x, 2*x, 4*x],
+ 'EW' : lambda : [2*x, 4*x, 3*x, 3*x],
+ 'WE' : lambda : [4*x, 2*x, 3*x, 3*x], }[MacObject.MeshPar[1]]()
+
+ Config.ListObj.append(MacObject)
+ return MacObject
- Config.ListObj.append(MacObject)
- return MacObject
-
##########################################################################################################
def BoxAng32 (MacObject):
- if Config.debug : print "Generating sharp angle"
- Z_Axis = geompy.MakeVectorDXDYDZ(0., 0., 1.)
- RotAngle = {'NE' : lambda : 0,
- 'NW' : lambda : math.pi/2,
- 'SW' : lambda : math.pi,
- 'SE' : lambda : -math.pi/2, }[MacObject.MeshPar[1]]()
- dummy0 = geompy.MakeRotation( ElemEdge32 () , Z_Axis, RotAngle )
- dummy1 = geompy.MakeScaleAlongAxes( dummy0, None , MacObject.GeoPar[1][0], MacObject.GeoPar[1][1], 1)
- RectFace = geompy.MakeTranslation(dummy1, MacObject.GeoPar[0][0], MacObject.GeoPar[0][1], 0)
-
- MacObject.GeoChildren.append(RectFace)
- MacObject.GeoChildrenNames.append("Box_"+ str(len(Config.ListObj)+1))
-
- if Config.debug : Publish (MacObject.GeoChildren,MacObject.GeoChildrenNames)
-
- if Config.publish :
- MacObject.Mesh.append(smesh.Mesh(RectFace)) # Creation of a new mesh
- Quad2D = MacObject.Mesh[0].Quadrangle() # Applying a quadrangle hypothesis
-
- EdgeIDs = geompy.SubShapeAllSorted(RectFace,6) # List of Edge IDs belonging to RectFace, 6 = Edge in salome dictionary
- Reg1D = MacObject.Mesh[0].Segment()
- Reg1D.NumberOfSegments(MacObject.MeshPar[0])
-
- MacObject.Mesh[0].Compute() # Generates the mesh
-
- MacObject.status = 1
-
- x = MacObject.MeshPar[0]
- MacObject.DirectionalMeshParams = {'NE' : lambda : [3*x, 2*x, 3*x, 2*x],
- 'NW' : lambda : [2*x, 3*x, 3*x, 2*x],
- 'SW' : lambda : [2*x, 3*x, 2*x, 3*x],
- 'SE' : lambda : [3*x, 2*x, 2*x, 3*x], }[MacObject.MeshPar[1]]()
-
- Config.ListObj.append(MacObject)
- return MacObject
+ if Config.debug : print "Generating sharp angle"
+ Z_Axis = geompy.MakeVectorDXDYDZ(0., 0., 1.)
+ RotAngle = {'NE' : lambda : 0,
+ 'NW' : lambda : math.pi/2,
+ 'SW' : lambda : math.pi,
+ 'SE' : lambda : -math.pi/2, }[MacObject.MeshPar[1]]()
+ dummy0 = geompy.MakeRotation( ElemEdge32 () , Z_Axis, RotAngle )
+ dummy1 = geompy.MakeScaleAlongAxes( dummy0, None , MacObject.GeoPar[1][0], MacObject.GeoPar[1][1], 1)
+ RectFace = geompy.MakeTranslation(dummy1, MacObject.GeoPar[0][0], MacObject.GeoPar[0][1], 0)
+
+ MacObject.GeoChildren.append(RectFace)
+ MacObject.GeoChildrenNames.append("Box_"+ str(len(Config.ListObj)+1))
+
+ if Config.debug : Publish (MacObject.GeoChildren,MacObject.GeoChildrenNames)
+
+ if Config.publish :
+ MacObject.Mesh.append(smesh.Mesh(RectFace)) # Creation of a new mesh
+ Quad2D = MacObject.Mesh[0].Quadrangle() # Applying a quadrangle hypothesis
+
+ EdgeIDs = geompy.SubShapeAllSorted(RectFace,6) # List of Edge IDs belonging to RectFace, 6 = Edge in salome dictionary
+ Reg1D = MacObject.Mesh[0].Segment()
+ Reg1D.NumberOfSegments(MacObject.MeshPar[0])
+
+ MacObject.Mesh[0].Compute() # Generates the mesh
+
+ MacObject.status = 1
+
+ x = MacObject.MeshPar[0]
+ MacObject.DirectionalMeshParams = {'NE' : lambda : [3*x, 2*x, 3*x, 2*x],
+ 'NW' : lambda : [2*x, 3*x, 3*x, 2*x],
+ 'SW' : lambda : [2*x, 3*x, 2*x, 3*x],
+ 'SE' : lambda : [3*x, 2*x, 2*x, 3*x], }[MacObject.MeshPar[1]]()
+
+ Config.ListObj.append(MacObject)
+ return MacObject
##########################################################################################################
def CompBox (MacObject):
- if Config.debug : print "Generating composite box"
+ if Config.debug : print "Generating composite box"
+
+ dummy1 = geompy.MakeScaleAlongAxes( ElemBox11 (), None , MacObject.GeoPar[1][0], MacObject.GeoPar[1][1], 1)
+ RectFace = geompy.MakeTranslation(dummy1, MacObject.GeoPar[0][0], MacObject.GeoPar[0][1], 0)
- dummy1 = geompy.MakeScaleAlongAxes( ElemBox11 (), None , MacObject.GeoPar[1][0], MacObject.GeoPar[1][1], 1)
- RectFace = geompy.MakeTranslation(dummy1, MacObject.GeoPar[0][0], MacObject.GeoPar[0][1], 0)
+ MacObject.GeoChildren.append(RectFace)
+ MacObject.GeoChildrenNames.append("Box_"+ str(len(Config.ListObj)+1))
- MacObject.GeoChildren.append(RectFace)
- MacObject.GeoChildrenNames.append("Box_"+ str(len(Config.ListObj)+1))
-
- if Config.debug : Publish (MacObject.GeoChildren,MacObject.GeoChildrenNames)
+ if Config.debug : Publish (MacObject.GeoChildren,MacObject.GeoChildrenNames)
- if Config.publish :
- MacObject.Mesh.append(smesh.Mesh(RectFace)) # Creation of a new mesh
- Quad2D = MacObject.Mesh[0].Quadrangle() # Applying a quadrangle hypothesis
+ if Config.publish :
+ MacObject.Mesh.append(smesh.Mesh(RectFace)) # Creation of a new mesh
+ Quad2D = MacObject.Mesh[0].Quadrangle() # Applying a quadrangle hypothesis
- EdgeIDs = geompy.SubShapeAllSorted(RectFace,6) # List of Edge IDs belonging to RectFace, 6 = Edge in salome dictionary
+ EdgeIDs = geompy.SubShapeAllSorted(RectFace,6) # List of Edge IDs belonging to RectFace, 6 = Edge in salome dictionary
- ReducedRatio = ReduceRatio(MacObject.GeoPar[1][0],MacObject.GeoPar[1][1])
+ ReducedRatio = ReduceRatio(MacObject.GeoPar[1][0],MacObject.GeoPar[1][1])
- Reference = [0,0,0]
- Vec = [(1,0,0),(0,1,0)]
- for Edge in EdgeIDs:
- for i in range(0,2):
- if IsParallel(Edge,Vec[i]):
- if not Reference[i]: # If this is the first found edge to be parallel to this direction, apply user preferences for meshing
- Reference[i] = Edge
- ApplyConstant1DMesh(MacObject.Mesh[0],Edge,int(round(ReducedRatio[i]*MacObject.MeshPar[0])))
- break
- else: # If there already exists an edge parallel to this direction, then use a 1D projection
- Apply1DProjMesh(MacObject.Mesh[0],Edge,Reference[i])
- break
+ Reference = [0,0,0]
+ Vec = [(1,0,0),(0,1,0)]
+ for Edge in EdgeIDs:
+ for i in range(0,2):
+ if IsParallel(Edge,Vec[i]):
+ if not Reference[i]: # If this is the first found edge to be parallel to this direction, apply user preferences for meshing
+ Reference[i] = Edge
+ ApplyConstant1DMesh(MacObject.Mesh[0],Edge,int(round(ReducedRatio[i]*MacObject.MeshPar[0])))
+ break
+ else: # If there already exists an edge parallel to this direction, then use a 1D projection
+ Apply1DProjMesh(MacObject.Mesh[0],Edge,Reference[i])
+ break
- MacObject.Mesh[0].Compute() # Generates the mesh
-
- MacObject.DirectionalMeshParams = [MacObject.MeshPar[0]*ReducedRatio[1],MacObject.MeshPar[0]*ReducedRatio[1],MacObject.MeshPar[0]*ReducedRatio[0],MacObject.MeshPar[0]*ReducedRatio[0]]
+ MacObject.Mesh[0].Compute() # Generates the mesh
- MacObject.status = 1
- Config.ListObj.append(MacObject)
- return MacObject
+ MacObject.DirectionalMeshParams = [MacObject.MeshPar[0]*ReducedRatio[1],MacObject.MeshPar[0]*ReducedRatio[1],MacObject.MeshPar[0]*ReducedRatio[0],MacObject.MeshPar[0]*ReducedRatio[0]]
+
+ MacObject.status = 1
+ Config.ListObj.append(MacObject)
+ return MacObject
##########################################################################################################
def CompBoxF (MacObject):
- if Config.debug : print "Generating composite box"
-
- dummy1 = geompy.MakeScaleAlongAxes( ElemBox11 (), None , MacObject.GeoPar[1][0], MacObject.GeoPar[1][1], 1)
- RectFace = geompy.MakeTranslation(dummy1, MacObject.GeoPar[0][0], MacObject.GeoPar[0][1], 0)
-
- MacObject.GeoChildren.append(RectFace)
- MacObject.GeoChildrenNames.append("Box_"+ str(len(Config.ListObj)+1))
-
- if Config.debug : Publish (MacObject.GeoChildren,MacObject.GeoChildrenNames)
-
- if Config.publish :
- MacObject.Mesh.append(smesh.Mesh(RectFace)) # Creation of a new mesh
- Quad2D = MacObject.Mesh[0].Quadrangle() # Applying a quadrangle hypothesis
-
- EdgeIDs = geompy.SubShapeAllSorted(RectFace,6) # List of Edge IDs belonging to RectFace, 6 = Edge in salome dictionary
-
- #ReducedRatio = ReduceRatio(MacObject.GeoPar[1][0],MacObject.GeoPar[1][1])
-
- Reference = [0,0,0]
- Vec = [(1,0,0),(0,1,0)]
- for Edge in EdgeIDs:
- for i in range(0,2):
- if IsParallel(Edge,Vec[i]):
- if not Reference[i]: # If this is the first found edge to be parallel to this direction, apply user preferences for meshing
- Reference[i] = Edge
- ApplyConstant1DMesh(MacObject.Mesh[0],Edge,int(round(MacObject.MeshPar[0][i])))
- break
- else: # If there already exists an edge parallel to this direction, then use a 1D projection
- Apply1DProjMesh(MacObject.Mesh[0],Edge,Reference[i])
- break
-
- MacObject.Mesh[0].Compute() # Generates the mesh
-
- MacObject.DirectionalMeshParams = [MacObject.MeshPar[0][1],MacObject.MeshPar[0][1],MacObject.MeshPar[0][0],MacObject.MeshPar[0][0]]
-
- MacObject.status = 1
- Config.ListObj.append(MacObject)
- return MacObject
+ if Config.debug : print "Generating composite box"
+
+ dummy1 = geompy.MakeScaleAlongAxes( ElemBox11 (), None , MacObject.GeoPar[1][0], MacObject.GeoPar[1][1], 1)
+ RectFace = geompy.MakeTranslation(dummy1, MacObject.GeoPar[0][0], MacObject.GeoPar[0][1], 0)
+
+ MacObject.GeoChildren.append(RectFace)
+ MacObject.GeoChildrenNames.append("Box_"+ str(len(Config.ListObj)+1))
+
+ if Config.debug : Publish (MacObject.GeoChildren,MacObject.GeoChildrenNames)
+
+ if Config.publish :
+ MacObject.Mesh.append(smesh.Mesh(RectFace)) # Creation of a new mesh
+ Quad2D = MacObject.Mesh[0].Quadrangle() # Applying a quadrangle hypothesis
+
+ EdgeIDs = geompy.SubShapeAllSorted(RectFace,6) # List of Edge IDs belonging to RectFace, 6 = Edge in salome dictionary
+
+ #ReducedRatio = ReduceRatio(MacObject.GeoPar[1][0],MacObject.GeoPar[1][1])
+
+ Reference = [0,0,0]
+ Vec = [(1,0,0),(0,1,0)]
+ for Edge in EdgeIDs:
+ for i in range(0,2):
+ if IsParallel(Edge,Vec[i]):
+ if not Reference[i]: # If this is the first found edge to be parallel to this direction, apply user preferences for meshing
+ Reference[i] = Edge
+ ApplyConstant1DMesh(MacObject.Mesh[0],Edge,int(round(MacObject.MeshPar[0][i])))
+ break
+ else: # If there already exists an edge parallel to this direction, then use a 1D projection
+ Apply1DProjMesh(MacObject.Mesh[0],Edge,Reference[i])
+ break
+
+ MacObject.Mesh[0].Compute() # Generates the mesh
+
+ MacObject.DirectionalMeshParams = [MacObject.MeshPar[0][1],MacObject.MeshPar[0][1],MacObject.MeshPar[0][0],MacObject.MeshPar[0][0]]
+
+ MacObject.status = 1
+ Config.ListObj.append(MacObject)
+ return MacObject
##########################################################################################################
def NonOrtho (MacObject):
- if Config.debug : print "Generating Non-orthogonal quadrangle"
-
- RectFace = Quadrangler (MacObject.PtCoor)
-
- MacObject.GeoChildren.append(RectFace)
- MacObject.GeoChildrenNames.append("Quad_"+ str(len(Config.ListObj)+1))
-
-
- if Config.debug : Publish (MacObject.GeoChildren,MacObject.GeoChildrenNames)
-
- if Config.publish :
- MacObject.Mesh.append(smesh.Mesh(RectFace)) # Creation of a new mesh
- Quad2D = MacObject.Mesh[0].Quadrangle() # Applying a quadrangle hypothesis
-
- EdgeIDs = geompy.SubShapeAllSorted(RectFace,6) # List of Edge IDs belonging to RectFace, 6 = Edge in salome dictionary
-
- #ReducedRatio = ReduceRatio(MacObject.GeoPar[1][0],MacObject.GeoPar[1][1])
-
- Vec = [MacObject.DirVectors(i) for i in range(4)]
- for Edge in EdgeIDs:
- Dir = [IsParallel(Edge,Vec[j]) for j in range(4)].index(True)
- DirConv = [0,0,1,1][Dir]
- ApplyConstant1DMesh(MacObject.Mesh[0],Edge,int(round(MacObject.MeshPar[0][DirConv])))
-
- MacObject.Mesh[0].Compute() # Generates the mesh
-
- MacObject.DirectionalMeshParams = [MacObject.MeshPar[0][1],MacObject.MeshPar[0][1],MacObject.MeshPar[0][0],MacObject.MeshPar[0][0]]
-
- MacObject.status = 1
- Config.ListObj.append(MacObject)
- return MacObject
+ if Config.debug : print "Generating Non-orthogonal quadrangle"
+
+ RectFace = Quadrangler (MacObject.PtCoor)
+
+ MacObject.GeoChildren.append(RectFace)
+ MacObject.GeoChildrenNames.append("Quad_"+ str(len(Config.ListObj)+1))
+
+
+ if Config.debug : Publish (MacObject.GeoChildren,MacObject.GeoChildrenNames)
+
+ if Config.publish :
+ MacObject.Mesh.append(smesh.Mesh(RectFace)) # Creation of a new mesh
+ Quad2D = MacObject.Mesh[0].Quadrangle() # Applying a quadrangle hypothesis
+
+ EdgeIDs = geompy.SubShapeAllSorted(RectFace,6) # List of Edge IDs belonging to RectFace, 6 = Edge in salome dictionary
+
+ #ReducedRatio = ReduceRatio(MacObject.GeoPar[1][0],MacObject.GeoPar[1][1])
+
+ Vec = [MacObject.DirVectors(i) for i in range(4)]
+ for Edge in EdgeIDs:
+ Dir = [IsParallel(Edge,Vec[j]) for j in range(4)].index(True)
+ DirConv = [0,0,1,1][Dir]
+ ApplyConstant1DMesh(MacObject.Mesh[0],Edge,int(round(MacObject.MeshPar[0][DirConv])))
+
+ MacObject.Mesh[0].Compute() # Generates the mesh
+
+ MacObject.DirectionalMeshParams = [MacObject.MeshPar[0][1],MacObject.MeshPar[0][1],MacObject.MeshPar[0][0],MacObject.MeshPar[0][0]]
+
+ MacObject.status = 1
+ Config.ListObj.append(MacObject)
+ return MacObject
##########################################################################################################
def QuartCyl (MacObject):
- if Config.debug : print "Generating quarter cylinder"
- Z_Axis = geompy.MakeVectorDXDYDZ(0., 0., 1.)
- RotAngle = {'NE' : lambda : 0,
- 'NW' : lambda : math.pi/2,
- 'SW' : lambda : math.pi,
- 'SE' : lambda : -math.pi/2, }[MacObject.MeshPar[1]]()
- dummy0 = geompy.MakeRotation( ElemQuartCyl(MacObject.MeshPar[2]) , Z_Axis, RotAngle )
- dummy1 = geompy.MakeScaleAlongAxes( dummy0, None , MacObject.GeoPar[1][0]/10., MacObject.GeoPar[1][1]/10., 1)
- RectFace = geompy.MakeTranslation(dummy1, MacObject.GeoPar[0][0], MacObject.GeoPar[0][1], 0)
-
- MacObject.GeoChildren.append(RectFace)
- MacObject.GeoChildrenNames.append("Box_"+ str(len(Config.ListObj)+1))
-
- if Config.debug : Publish (MacObject.GeoChildren,MacObject.GeoChildrenNames)
-
- if Config.publish :
- MacObject.Mesh.append(smesh.Mesh(RectFace)) # Creation of a new mesh
- Quad2D = MacObject.Mesh[0].Quadrangle() # Applying a quadrangle hypothesis
-
- EdgeIDs = geompy.SubShapeAllSorted(RectFace,6) # List of Edge IDs belonging to RectFace, 6 = Edge in salome dictionary
- Reg1D = MacObject.Mesh[0].Segment()
-
- #if MacObject.MeshPar[0] == 2 and MacObject.MeshPar[2] <= 2.:
- # print("Due to a bug in Salome 6.3, we are forced to either increase or decrease the local refinement by 50%, we choose in this case to increase the model's refinement.")
- # MacObject.MeshPar[0] = 3
-
- Reg1D.NumberOfSegments(MacObject.MeshPar[0])
-
- MacObject.Mesh[0].Compute() # Generates the mesh
-
- MacObject.status = 1
-
- x = MacObject.MeshPar[0]
- N = QuarCylParam(MacObject.MeshPar[2])+1
-
- MacObject.DirectionalMeshParams = {'NE' : lambda : [2*x, N*x, 2*x, N*x],
- 'NW' : lambda : [N*x, 2*x, 2*x, N*x],
- 'SW' : lambda : [N*x, 2*x, N*x, 2*x],
- 'SE' : lambda : [2*x, N*x, N*x, 2*x], }[MacObject.MeshPar[1]]()
-
- Config.ListObj.append(MacObject)
- return MacObject
-
+ if Config.debug : print "Generating quarter cylinder"
+ Z_Axis = geompy.MakeVectorDXDYDZ(0., 0., 1.)
+ RotAngle = {'NE' : lambda : 0,
+ 'NW' : lambda : math.pi/2,
+ 'SW' : lambda : math.pi,
+ 'SE' : lambda : -math.pi/2, }[MacObject.MeshPar[1]]()
+ dummy0 = geompy.MakeRotation( ElemQuartCyl(MacObject.MeshPar[2]) , Z_Axis, RotAngle )
+ dummy1 = geompy.MakeScaleAlongAxes( dummy0, None , MacObject.GeoPar[1][0]/10., MacObject.GeoPar[1][1]/10., 1)
+ RectFace = geompy.MakeTranslation(dummy1, MacObject.GeoPar[0][0], MacObject.GeoPar[0][1], 0)
+
+ MacObject.GeoChildren.append(RectFace)
+ MacObject.GeoChildrenNames.append("Box_"+ str(len(Config.ListObj)+1))
+
+ if Config.debug : Publish (MacObject.GeoChildren,MacObject.GeoChildrenNames)
+
+ if Config.publish :
+ MacObject.Mesh.append(smesh.Mesh(RectFace)) # Creation of a new mesh
+ Quad2D = MacObject.Mesh[0].Quadrangle() # Applying a quadrangle hypothesis
+
+ EdgeIDs = geompy.SubShapeAllSorted(RectFace,6) # List of Edge IDs belonging to RectFace, 6 = Edge in salome dictionary
+ Reg1D = MacObject.Mesh[0].Segment()
+
+ #if MacObject.MeshPar[0] == 2 and MacObject.MeshPar[2] <= 2.:
+ # print("Due to a bug in Salome 6.3, we are forced to either increase or decrease the local refinement by 50%, we choose in this case to increase the model's refinement.")
+ # MacObject.MeshPar[0] = 3
+
+ Reg1D.NumberOfSegments(MacObject.MeshPar[0])
+
+ MacObject.Mesh[0].Compute() # Generates the mesh
+
+ MacObject.status = 1
+
+ x = MacObject.MeshPar[0]
+ N = QuarCylParam(MacObject.MeshPar[2])+1
+
+ MacObject.DirectionalMeshParams = {'NE' : lambda : [2*x, N*x, 2*x, N*x],
+ 'NW' : lambda : [N*x, 2*x, 2*x, N*x],
+ 'SW' : lambda : [N*x, 2*x, N*x, 2*x],
+ 'SE' : lambda : [2*x, N*x, N*x, 2*x], }[MacObject.MeshPar[1]]()
+
+ Config.ListObj.append(MacObject)
+ return MacObject
+
##########################################################################################################
-# Below this are the elementary calculation/visualization functions
+# Below this are the elementary calculation/visualization functions
##########################################################################################################
def Publish (ObjToPublish,NamesToPublish):
- i = 0
- for GeoObj in ObjToPublish :
- geompy.addToStudy(GeoObj,NamesToPublish[i])
- i = i+1
+ i = 0
+ for GeoObj in ObjToPublish :
+ geompy.addToStudy(GeoObj,NamesToPublish[i])
+ i = i+1
def IsParallel (Edge, Vector):
- """
- Function checks whether a given edge object is parallel to a reference vector.
- Output can be 0 (not parallel) or 1 (parallel and same sense) or 2 (parallel and opposite sense).
- If the reference vector is null, the function returns 0
- """
- if Vector == (0,0,0) : return 0
- else :
- P1 = geompy.PointCoordinates(geompy.GetVertexByIndex(Edge,0))
- P2 = geompy.PointCoordinates(geompy.GetVertexByIndex(Edge,1))
- V0 = [ P1[0] - P2[0], P1[1] - P2[1], P1[2] - P2[2] ]
- if Distance2Pt((0,0,0),CrossProd(V0,Vector))<1e-7 and DotProd(V0,Vector) > 0 : return 1
- elif Distance2Pt((0,0,0),CrossProd(V0,Vector))<1e-7 and DotProd(V0,Vector) < 0 : return 2
- else : return 0
+ """
+ Function checks whether a given edge object is parallel to a reference vector.
+ Output can be 0 (not parallel) or 1 (parallel and same sense) or 2 (parallel and opposite sense).
+ If the reference vector is null, the function returns 0
+ """
+ if Vector == (0,0,0) : return 0
+ else :
+ P1 = geompy.PointCoordinates(geompy.GetVertexByIndex(Edge,0))
+ P2 = geompy.PointCoordinates(geompy.GetVertexByIndex(Edge,1))
+ V0 = [ P1[0] - P2[0], P1[1] - P2[1], P1[2] - P2[2] ]
+ if Distance2Pt((0,0,0),CrossProd(V0,Vector))<1e-7 and DotProd(V0,Vector) > 0 : return 1
+ elif Distance2Pt((0,0,0),CrossProd(V0,Vector))<1e-7 and DotProd(V0,Vector) < 0 : return 2
+ else : return 0
def IsOnCircle (Edge, Center, Radius):
- """
- Function checks whether a given edge object belong to the periphery of a circle defined by its
- center and radius.
- Output can be 0 (does not belong) or 1 (belongs).
- If the reference Radius is null, the function returns 0
- Note that this function is basic in the sense that it only checks if the two border points of a
- given edge belong to the arc of reference.
- """
- if Radius == 0 : return 0
- else :
- P1 = geompy.PointCoordinates(geompy.GetVertexByIndex(Edge,0))
- P2 = geompy.PointCoordinates(geompy.GetVertexByIndex(Edge,1))
- if abs(Distance2Pt(Center,P1)-Radius) < 1e-6 and abs(Distance2Pt(Center,P2)-Radius) < 1e-6:
- return 1
- else :
- return 0
-
+ """
+ Function checks whether a given edge object belong to the periphery of a circle defined by its
+ center and radius.
+ Output can be 0 (does not belong) or 1 (belongs).
+ If the reference Radius is null, the function returns 0
+ Note that this function is basic in the sense that it only checks if the two border points of a
+ given edge belong to the arc of reference.
+ """
+ if Radius == 0 : return 0
+ else :
+ P1 = geompy.PointCoordinates(geompy.GetVertexByIndex(Edge,0))
+ P2 = geompy.PointCoordinates(geompy.GetVertexByIndex(Edge,1))
+ if abs(Distance2Pt(Center,P1)-Radius) < 1e-6 and abs(Distance2Pt(Center,P2)-Radius) < 1e-6:
+ return 1
+ else :
+ return 0
+
def CrossProd(V1,V2):
- """
- Determines the cross product of two 3D vectors
- """
- return ([V1[1]*V2[2]-V1[2]*V2[1], V1[2]*V2[0]-V1[0]*V2[2], V1[0]*V2[1]-V1[1]*V2[0]])
+ """
+ Determines the cross product of two 3D vectors
+ """
+ return ([V1[1]*V2[2]-V1[2]*V2[1], V1[2]*V2[0]-V1[0]*V2[2], V1[0]*V2[1]-V1[1]*V2[0]])
def QuarCylParam(PitchRatio):
- R = float(PitchRatio)/(PitchRatio+1)
- Eps = 1. - R
- X = (R+Eps/2.)*math.sin(math.pi/4)+Eps/2.
- N = int(math.floor((math.pi*R/4.)/(Eps/2.)))
- return N
+ R = float(PitchRatio)/(PitchRatio+1)
+ Eps = 1. - R
+ X = (R+Eps/2.)*math.sin(math.pi/4)+Eps/2.
+ N = int(math.floor((math.pi*R/4.)/(Eps/2.)))
+ return N
def DotProd(V1,V2):
- """
- Determines the dot product of two 3D vectors
- """
- if len(V1)==2 : V1.append(0)
- if len(V2)==2 : V2.append(0)
-
- return (V1[0]*V2[0]+V1[1]*V2[1]+V1[2]*V2[2])
+ """
+ Determines the dot product of two 3D vectors
+ """
+ if len(V1)==2 : V1.append(0)
+ if len(V2)==2 : V2.append(0)
+
+ return (V1[0]*V2[0]+V1[1]*V2[1]+V1[2]*V2[2])
def Distance2Pt(P1,P2):
- """
- Returns the distance between two points
- """
- return (math.sqrt((P1[0]-P2[0])**2+(P1[1]-P2[1])**2+(P1[2]-P2[2])**2))
+ """
+ Returns the distance between two points
+ """
+ return (math.sqrt((P1[0]-P2[0])**2+(P1[1]-P2[1])**2+(P1[2]-P2[2])**2))
def ApplyConstant1DMesh (ParentMsh, Edge, Nseg):
- Reg1D = ParentMsh.Segment(geom=Edge)
- Len = Reg1D.NumberOfSegments(Nseg)
+ Reg1D = ParentMsh.Segment(geom=Edge)
+ Len = Reg1D.NumberOfSegments(Nseg)
def Apply1DProjMesh (ParentMsh, Edge, Ref):
- Proj1D = ParentMsh.Projection1D(geom=Edge)
- SrcEdge = Proj1D.SourceEdge(Ref,None,None,None)
+ Proj1D = ParentMsh.Projection1D(geom=Edge)
+ SrcEdge = Proj1D.SourceEdge(Ref,None,None,None)
def EdgeLength (Edge):
- """
- This function returns the edge object length.
- """
- P1 = geompy.PointCoordinates(geompy.GetVertexByIndex(Edge,0))
- P2 = geompy.PointCoordinates(geompy.GetVertexByIndex(Edge,1))
- return Distance2Pt(P1,P2)
+ """
+ This function returns the edge object length.
+ """
+ P1 = geompy.PointCoordinates(geompy.GetVertexByIndex(Edge,0))
+ P2 = geompy.PointCoordinates(geompy.GetVertexByIndex(Edge,1))
+ return Distance2Pt(P1,P2)
def D2R (Angle):
- return Angle*math.pi/180
+ return Angle*math.pi/180
def R2D (Angle):
- return Angle*180/math.pi
+ return Angle*180/math.pi
def F2D (FloatNumber):
- return round(FloatNumber*100.)/100.
+ return round(FloatNumber*100.)/100.
def BezierGen (PointA, PointB, AngleA, AngleB):
- if AngleA == 0 and AngleB == 0 : return (geompy.MakeEdge(PointA, PointB))
- else :
- A = geompy.PointCoordinates(PointA)
- B = geompy.PointCoordinates(PointB)
- dAB = Distance2Pt(A,B)
- dAC = dAB * (math.tan(AngleA)*math.tan(AngleB)) / (math.sin(AngleA) * ( math.tan(AngleA)+math.tan(AngleB) ) )
- AngleOX_AB = math.acos((B[0]-A[0])/dAB)
- PointC = geompy.MakeVertex(A[0]+math.cos(AngleA+AngleOX_AB)*dAC,A[1]+math.sin(AngleA+AngleOX_AB)*dAC,0)
- CurveACB = geompy.MakeBezier([PointA,PointC,PointB])
- return CurveACB
+ if AngleA == 0 and AngleB == 0 : return (geompy.MakeEdge(PointA, PointB))
+ else :
+ A = geompy.PointCoordinates(PointA)
+ B = geompy.PointCoordinates(PointB)
+ dAB = Distance2Pt(A,B)
+ dAC = dAB * (math.tan(AngleA)*math.tan(AngleB)) / (math.sin(AngleA) * ( math.tan(AngleA)+math.tan(AngleB) ) )
+ AngleOX_AB = math.acos((B[0]-A[0])/dAB)
+ PointC = geompy.MakeVertex(A[0]+math.cos(AngleA+AngleOX_AB)*dAC,A[1]+math.sin(AngleA+AngleOX_AB)*dAC,0)
+ CurveACB = geompy.MakeBezier([PointA,PointC,PointB])
+ return CurveACB
def GetSideAngleForBezier (PointA , PointB):
- """
- This function takes for input two points A and B where the bezier line is needed. It calculates the incident
- angle needed at point A so that the final curve is either at 0 or 90 degrees from the x'Ox axis
- """
- A = geompy.PointCoordinates(PointA)
- B = geompy.PointCoordinates(PointB)
- ABx = B[0]-A[0]
- dAB = Distance2Pt(A,B)
- Alpha = math.acos(ABx/dAB)
- #print "New angle request"
- #print ABx, dAB, R2D(Alpha)
- if Alpha < math.pi/4 :
- #print "returning", R2D(-Alpha)
- return -Alpha
- elif Alpha < 3*math.pi/4 :
- #print "returning", R2D(-(Alpha-math.pi/2))
- return -(Alpha-math.pi/2)
- else :
- #print "returning", R2D(-(Alpha-math.pi))
- return -(Alpha-math.pi)
+ """
+ This function takes for input two points A and B where the bezier line is needed. It calculates the incident
+ angle needed at point A so that the final curve is either at 0 or 90 degrees from the x'Ox axis
+ """
+ A = geompy.PointCoordinates(PointA)
+ B = geompy.PointCoordinates(PointB)
+ ABx = B[0]-A[0]
+ dAB = Distance2Pt(A,B)
+ Alpha = math.acos(ABx/dAB)
+ #print "New angle request"
+ #print ABx, dAB, R2D(Alpha)
+ if Alpha < math.pi/4 :
+ #print "returning", R2D(-Alpha)
+ return -Alpha
+ elif Alpha < 3*math.pi/4 :
+ #print "returning", R2D(-(Alpha-math.pi/2))
+ return -(Alpha-math.pi/2)
+ else :
+ #print "returning", R2D(-(Alpha-math.pi))
+ return -(Alpha-math.pi)
def VecDivRatio (Vec1, Vec2):
- """
- This function tries to find the ratio of Vec1 on Vec2 while neglecting any zero term in Vec1. This is used afterwards
- for determining the global mesh parameter from automatically detected directional mesh params. If no compatibility is
- possible, the function returns -1
- """
- Vec3 = []
- for i in range(len(Vec1)) :
- Vec3.append(float(Vec1[i])/Vec2[i])
- Ratio=[]
- for i in Vec3 :
- if not (abs(i)<1e-7) : Ratio.append(i)
- if Ratio :
- if min(Ratio) == max(Ratio) and min(Ratio)==int(min(Ratio)) : return(min(Ratio))
- else : return -1
- else :
- return -2
-
-
+ """
+ This function tries to find the ratio of Vec1 on Vec2 while neglecting any zero term in Vec1. This is used afterwards
+ for determining the global mesh parameter from automatically detected directional mesh params. If no compatibility is
+ possible, the function returns -1
+ """
+ Vec3 = []
+ for i in range(len(Vec1)) :
+ Vec3.append(float(Vec1[i])/Vec2[i])
+ Ratio=[]
+ for i in Vec3 :
+ if not (abs(i)<1e-7) : Ratio.append(i)
+ if Ratio :
+ if min(Ratio) == max(Ratio) and min(Ratio)==int(min(Ratio)) : return(min(Ratio))
+ else : return -1
+ else :
+ return -2
+
+
def ReduceRatio (dx, dy):
- """
- This function transforms a decimal ratio into a scale between two integers, for example : [0.2,0.05] --> [4,1] ;
- """
- Output = [0,0]
- ratio = float(dy)/dx
- if isinteger(ratio) : return [1,ratio]
- elif dx == 1 : # when this function is called recursively!
- for i in range(1,20) : # searches over 20 decimals
- if isinteger(ratio * (10**i) ) :
- Output = GetScale((10**i),int(round(ratio * (10**i) ) ) )
- break
- else :
- for n in range(0,i) :
- if isinteger(ratio * ( 10**(i)-10**(n) )) :
- Output = GetScale( 10**(i)-10**(n) , int(round(ratio * ( 10**(i)-10**(n) ) ) ) )
- break
- if not (Output==[0,0]) : break
- return Output
- else :
- for i in range(1,10) : # searches over 10 decimals
- if isinteger(ratio * (10**i) ) :
- Output = GetScale((10**i),int(round(ratio * (10**i) ) ) )
- break
- else :
- for n in range(0,i) :
- if isinteger(ratio * ( 10**(i)-10**(n) )) :
- Output = GetScale( 10**(i)-10**(n) , int(round(ratio * ( 10**(i)-10**(n) ) ) ) )
- break
- if not (Output==[0,0]) : break
-
- if Output == [0,0] :
- print "We are having some trouble while interpreting the following ratio: ",ratio, "\nWe will try a recursive method which may in some cases take some time..."
- if dy > dx :
- A = ReduceRatio (dx, dy-dx)
- return ([A[0],A[1]+A[0]])
- else :
- A = ReduceRatio (dy, dx-dy)
- return ([A[1]+A[0],A[0]])
-
- else : return Output
-
+ """
+ This function transforms a decimal ratio into a scale between two integers, for example : [0.2,0.05] --> [4,1] ;
+ """
+ Output = [0,0]
+ ratio = float(dy)/dx
+ if isinteger(ratio) : return [1,ratio]
+ elif dx == 1 : # when this function is called recursively!
+ for i in range(1,20) : # searches over 20 decimals
+ if isinteger(ratio * (10**i) ) :
+ Output = GetScale((10**i),int(round(ratio * (10**i) ) ) )
+ break
+ else :
+ for n in range(0,i) :
+ if isinteger(ratio * ( 10**(i)-10**(n) )) :
+ Output = GetScale( 10**(i)-10**(n) , int(round(ratio * ( 10**(i)-10**(n) ) ) ) )
+ break
+ if not (Output==[0,0]) : break
+ return Output
+ else :
+ for i in range(1,10) : # searches over 10 decimals
+ if isinteger(ratio * (10**i) ) :
+ Output = GetScale((10**i),int(round(ratio * (10**i) ) ) )
+ break
+ else :
+ for n in range(0,i) :
+ if isinteger(ratio * ( 10**(i)-10**(n) )) :
+ Output = GetScale( 10**(i)-10**(n) , int(round(ratio * ( 10**(i)-10**(n) ) ) ) )
+ break
+ if not (Output==[0,0]) : break
+
+ if Output == [0,0] :
+ print "We are having some trouble while interpreting the following ratio: ",ratio, "\nWe will try a recursive method which may in some cases take some time..."
+ if dy > dx :
+ A = ReduceRatio (dx, dy-dx)
+ return ([A[0],A[1]+A[0]])
+ else :
+ A = ReduceRatio (dy, dx-dy)
+ return ([A[1]+A[0],A[0]])
+
+ else : return Output
+
def GetScale (X,Y):
- """
- This function is called within ReduceRatio and aims to reduce down two integers X and Y by dividing them with their common divisors;
- Example: 25 and 5 ---> 5 and 1 / 63 and 12 ---> 21 and 4
- """
- MaxDiv = max(X,Y)
- Divisor = 2 # Initializing the divisor
- while MaxDiv >= Divisor :
- X0 = 0
- Y0 = 0
- if not(X%Divisor) :
- X0 = X/Divisor
- MaxDiv = max(MaxDiv,X0)
- if not(Y%Divisor) :
- Y0 = Y/Divisor
- MaxDiv = max(MaxDiv,Y0)
- if (X0*Y0) :
- X = X0
- Y = Y0
- else :
- Divisor = Divisor + 1
- return [X,Y]
+ """
+ This function is called within ReduceRatio and aims to reduce down two integers X and Y by dividing them with their common divisors;
+ Example: 25 and 5 ---> 5 and 1 / 63 and 12 ---> 21 and 4
+ """
+ MaxDiv = max(X,Y)
+ Divisor = 2 # Initializing the divisor
+ while MaxDiv >= Divisor :
+ X0 = 0
+ Y0 = 0
+ if not(X%Divisor) :
+ X0 = X/Divisor
+ MaxDiv = max(MaxDiv,X0)
+ if not(Y%Divisor) :
+ Y0 = Y/Divisor
+ MaxDiv = max(MaxDiv,Y0)
+ if (X0*Y0) :
+ X = X0
+ Y = Y0
+ else :
+ Divisor = Divisor + 1
+ return [X,Y]
def isinteger (x) :
- """
- This functions applies a simple check if the entered value is an integer
- """
- x = float('%.5f' % (x)) #Truncate x to 5 digits after the decimal point
- if math.ceil(x) == math.floor(x) : return True
- else : return False
+ """
+ This functions applies a simple check if the entered value is an integer
+ """
+ x = float('%.5f' % (x)) #Truncate x to 5 digits after the decimal point
+ if math.ceil(x) == math.floor(x) : return True
+ else : return False
##########################################################################################
# Below this are the functions that create the elementary forms for the macro objects
##########################################################################################
def ElemBox11 ():
- """
- This function returns a simple square face of 1 side length
- """
- RectFace = geompy.MakeFaceHW(1, 1, 1)
- return RectFace
+ """
+ This function returns a simple square face of 1 side length
+ """
+ RectFace = geompy.MakeFaceHW(1, 1, 1)
+ return RectFace
def ElemBox42 ():
- """
- This function returns a square face of 1 side length, partitioned
- according to the elementary 4 to 2 reductor method
- """
- OrigRectFace = geompy.MakeFaceHW(1, 1, 1)
-
- SouthPt1 = geompy.MakeVertex (-.25, -.5, 0)
- SouthPt2 = geompy.MakeVertex (0, -.5, 0)
- SouthPt3 = geompy.MakeVertex (.25, -.5, 0)
- WestPt1 = geompy.MakeVertex (-.5, -.5+1./3, 0)
- WestPt2 = geompy.MakeVertex (-.5, -.5+2./3, 0)
- EastPt1 = geompy.MakeVertex (.5, -.5+1./3, 0)
- EastPt2 = geompy.MakeVertex (.5, -.5+2./3, 0)
- NorthPt = geompy.MakeVertex (0, .5, 0)
- MidPt1 = geompy.MakeVertex (0, .05, 0)
- MidPt2 = geompy.MakeVertex (.2, -.18, 0)
- MidPt3 = geompy.MakeVertex (0, -.28, 0)
- MidPt4 = geompy.MakeVertex (-.2, -.18, 0)
-
- Cutter = []
- Cutter.append(geompy.MakeEdge(SouthPt2, MidPt3))
- Cutter.append(geompy.MakeEdge(MidPt1, NorthPt))
- Cutter.append(BezierGen(SouthPt1, MidPt4, GetSideAngleForBezier(SouthPt1,MidPt4), D2R(15)))
- Cutter.append(BezierGen(SouthPt3, MidPt2, GetSideAngleForBezier(SouthPt3,MidPt2), D2R(-15)))
- Cutter.append(BezierGen(WestPt1, MidPt4, GetSideAngleForBezier(WestPt1,MidPt4), D2R(-10)))
- Cutter.append(BezierGen(EastPt1, MidPt2, GetSideAngleForBezier(EastPt1,MidPt2), D2R(10)))
- Cutter.append(BezierGen(WestPt2, MidPt1, GetSideAngleForBezier(WestPt2,MidPt1), D2R(-10)))
- Cutter.append(BezierGen(EastPt2, MidPt1, GetSideAngleForBezier(EastPt2,MidPt1), D2R(10)))
- Cutter.append(BezierGen(MidPt2, MidPt1, D2R(-15), D2R(-15)))
- Cutter.append(BezierGen(MidPt3, MidPt2, D2R(10), D2R(15)))
- Cutter.append(BezierGen(MidPt3, MidPt4, D2R(-10), D2R(-15)))
- Cutter.append(BezierGen(MidPt4, MidPt1, D2R(15), D2R(15)))
-
- RectFace = geompy.MakePartition([OrigRectFace],Cutter, [], [],4, 0, [], 0) #Creating the partition object
- #i=1
- #for SingleCut in Cutter :
- # geompy.addToStudy(SingleCut,'Cutter'+str(i))
- # i = i+1
- #geompy.addToStudy(RectFace,'RectFace')
- return RectFace
+ """
+ This function returns a square face of 1 side length, partitioned
+ according to the elementary 4 to 2 reductor method
+ """
+ OrigRectFace = geompy.MakeFaceHW(1, 1, 1)
+
+ SouthPt1 = geompy.MakeVertex (-.25, -.5, 0)
+ SouthPt2 = geompy.MakeVertex (0, -.5, 0)
+ SouthPt3 = geompy.MakeVertex (.25, -.5, 0)
+ WestPt1 = geompy.MakeVertex (-.5, -.5+1./3, 0)
+ WestPt2 = geompy.MakeVertex (-.5, -.5+2./3, 0)
+ EastPt1 = geompy.MakeVertex (.5, -.5+1./3, 0)
+ EastPt2 = geompy.MakeVertex (.5, -.5+2./3, 0)
+ NorthPt = geompy.MakeVertex (0, .5, 0)
+ MidPt1 = geompy.MakeVertex (0, .05, 0)
+ MidPt2 = geompy.MakeVertex (.2, -.18, 0)
+ MidPt3 = geompy.MakeVertex (0, -.28, 0)
+ MidPt4 = geompy.MakeVertex (-.2, -.18, 0)
+
+ Cutter = []
+ Cutter.append(geompy.MakeEdge(SouthPt2, MidPt3))
+ Cutter.append(geompy.MakeEdge(MidPt1, NorthPt))
+ Cutter.append(BezierGen(SouthPt1, MidPt4, GetSideAngleForBezier(SouthPt1,MidPt4), D2R(15)))
+ Cutter.append(BezierGen(SouthPt3, MidPt2, GetSideAngleForBezier(SouthPt3,MidPt2), D2R(-15)))
+ Cutter.append(BezierGen(WestPt1, MidPt4, GetSideAngleForBezier(WestPt1,MidPt4), D2R(-10)))
+ Cutter.append(BezierGen(EastPt1, MidPt2, GetSideAngleForBezier(EastPt1,MidPt2), D2R(10)))
+ Cutter.append(BezierGen(WestPt2, MidPt1, GetSideAngleForBezier(WestPt2,MidPt1), D2R(-10)))
+ Cutter.append(BezierGen(EastPt2, MidPt1, GetSideAngleForBezier(EastPt2,MidPt1), D2R(10)))
+ Cutter.append(BezierGen(MidPt2, MidPt1, D2R(-15), D2R(-15)))
+ Cutter.append(BezierGen(MidPt3, MidPt2, D2R(10), D2R(15)))
+ Cutter.append(BezierGen(MidPt3, MidPt4, D2R(-10), D2R(-15)))
+ Cutter.append(BezierGen(MidPt4, MidPt1, D2R(15), D2R(15)))
+
+ RectFace = geompy.MakePartition([OrigRectFace],Cutter, [], [],4, 0, [], 0) #Creating the partition object
+ #i=1
+ #for SingleCut in Cutter :
+ # geompy.addToStudy(SingleCut,'Cutter'+str(i))
+ # i = i+1
+ #geompy.addToStudy(RectFace,'RectFace')
+ return RectFace
def ElemEdge32 ():
- """
- This function returns a square face of 1 side length, partitioned
- according to the elementary edge with 3 to 2 reductor
- """
- OrigRectFace = geompy.MakeFaceHW(1., 1., 1)
-
- SouthPt1 = geompy.MakeVertex (-1./6, -0.5, 0.)
- SouthPt2 = geompy.MakeVertex ( 1./6, -0.5, 0.)
- WestPt1 = geompy.MakeVertex (-0.5, -1./6, 0.)
- WestPt2 = geompy.MakeVertex (-0.5, 1./6, 0.)
- EastPt = geompy.MakeVertex ( 0.5, 0., 0.)
- NorthPt = geompy.MakeVertex (0., 0.5, 0.)
-
- MidPt1 = geompy.MakeVertex (-0.2, -0.2, 0.)
- MidPt2 = geompy.MakeVertex ( -0.02, -0.02, 0.)
-
- Cutter = []
- Cutter.append(BezierGen(SouthPt1, MidPt1, GetSideAngleForBezier(SouthPt1,MidPt1) , D2R(-5)))
- Cutter.append(BezierGen( WestPt1, MidPt1, GetSideAngleForBezier(WestPt1 ,MidPt1) , D2R(-5)))
- Cutter.append(BezierGen(SouthPt2, MidPt2, GetSideAngleForBezier(SouthPt2,MidPt2) , D2R(-10)))
- Cutter.append(BezierGen( EastPt, MidPt2, GetSideAngleForBezier(EastPt ,MidPt2) , D2R(5)))
- Cutter.append(BezierGen( WestPt2, MidPt2, GetSideAngleForBezier(WestPt2 ,MidPt2) , D2R(-10)))
- Cutter.append(BezierGen( MidPt2, NorthPt, GetSideAngleForBezier(NorthPt ,MidPt2) , D2R(-5)))
-
- Cutter.append(geompy.MakeEdge(MidPt1, MidPt2))
-
- RectFace = geompy.MakePartition([OrigRectFace],Cutter, [], [],4, 0, [], 0) #Creating the partition object
- #i=1
- #for SingleCut in Cutter :
- # geompy.addToStudy(SingleCut,'Cutter'+str(i))
- # i = i+1
- #geompy.addToStudy(RectFace,'RectFace')
- return RectFace
+ """
+ This function returns a square face of 1 side length, partitioned
+ according to the elementary edge with 3 to 2 reductor
+ """
+ OrigRectFace = geompy.MakeFaceHW(1., 1., 1)
+
+ SouthPt1 = geompy.MakeVertex (-1./6, -0.5, 0.)
+ SouthPt2 = geompy.MakeVertex ( 1./6, -0.5, 0.)
+ WestPt1 = geompy.MakeVertex (-0.5, -1./6, 0.)
+ WestPt2 = geompy.MakeVertex (-0.5, 1./6, 0.)
+ EastPt = geompy.MakeVertex ( 0.5, 0., 0.)
+ NorthPt = geompy.MakeVertex (0., 0.5, 0.)
+
+ MidPt1 = geompy.MakeVertex (-0.2, -0.2, 0.)
+ MidPt2 = geompy.MakeVertex ( -0.02, -0.02, 0.)
+
+ Cutter = []
+ Cutter.append(BezierGen(SouthPt1, MidPt1, GetSideAngleForBezier(SouthPt1,MidPt1) , D2R(-5)))
+ Cutter.append(BezierGen( WestPt1, MidPt1, GetSideAngleForBezier(WestPt1 ,MidPt1) , D2R(-5)))
+ Cutter.append(BezierGen(SouthPt2, MidPt2, GetSideAngleForBezier(SouthPt2,MidPt2) , D2R(-10)))
+ Cutter.append(BezierGen( EastPt, MidPt2, GetSideAngleForBezier(EastPt ,MidPt2) , D2R(5)))
+ Cutter.append(BezierGen( WestPt2, MidPt2, GetSideAngleForBezier(WestPt2 ,MidPt2) , D2R(-10)))
+ Cutter.append(BezierGen( MidPt2, NorthPt, GetSideAngleForBezier(NorthPt ,MidPt2) , D2R(-5)))
+
+ Cutter.append(geompy.MakeEdge(MidPt1, MidPt2))
+
+ RectFace = geompy.MakePartition([OrigRectFace],Cutter, [], [],4, 0, [], 0) #Creating the partition object
+ #i=1
+ #for SingleCut in Cutter :
+ # geompy.addToStudy(SingleCut,'Cutter'+str(i))
+ # i = i+1
+ #geompy.addToStudy(RectFace,'RectFace')
+ return RectFace
def Quadrangler (Points):
- """
- This function returns a quadranglar face based on four points, non of which 3 are non-colinear.
- The points are defined by their 2D [(x1,y1),(x2,y2)..] coordinates.
- Note that the list of points is already arranged upon the creation in MacObject
- """
- Pt = []
- for Point in Points: Pt.append(geompy.MakeVertex(Point[0], Point[1], 0))
- # The first point is added at the end of the list in order to facilitate the line creation
- Pt.append(Pt[0])
- #Draw the lines in order to form the 4 side polygon
- Ln=[]
- for i in range(4) : Ln.append(geompy.MakeLineTwoPnt(Pt[i],Pt[i+1]))
- RectFace = geompy.MakeQuad (Ln[0],Ln[1],Ln[2],Ln[3])
- return RectFace
+ """
+ This function returns a quadranglar face based on four points, non of which 3 are non-colinear.
+ The points are defined by their 2D [(x1,y1),(x2,y2)..] coordinates.
+ Note that the list of points is already arranged upon the creation in MacObject
+ """
+ Pt = []
+ for Point in Points: Pt.append(geompy.MakeVertex(Point[0], Point[1], 0))
+ # The first point is added at the end of the list in order to facilitate the line creation
+ Pt.append(Pt[0])
+ #Draw the lines in order to form the 4 side polygon
+ Ln=[]
+ for i in range(4) : Ln.append(geompy.MakeLineTwoPnt(Pt[i],Pt[i+1]))
+ RectFace = geompy.MakeQuad (Ln[0],Ln[1],Ln[2],Ln[3])
+ return RectFace
def ElemQuartCyl(K):
- """
- This function returns a quarter cylinder to box relay of 1 side length, partitioned
- with a pitch ratio of K, In other words the side of the box is R*(1+(1/K))
- """
- R = 10.*float(K)/(K+1)
- Eps = 10.- R
-
- Config.theStudy.SetReal("R" , R)
- Config.theStudy.SetReal("minusR" , -R)
- Config.theStudy.SetReal("Eps", Eps)
-
- CylWire = geompy.MakeSketcher("Sketcher:F 'R' 0:R 0:L 'Eps':TT 10. 10.0:R 90:L 10.0:R 90:L 'Eps':R 90:C 'minusR' 90.0:WW", [0, 0, 0, 0, 0, 1, 1, 0, -0])
- CylFace = geompy.MakeFace(CylWire, 1)
-
- SouthPt = geompy.MakeVertex (R+Eps/2., 0., 0)
- SouthWestPt = geompy.MakeVertex ( 0.,0., 0) #The origin can be used for practical partionning objectifs
- WestPt = geompy.MakeVertex (0., R+Eps/2., 0)
-
- N = int(math.floor((math.pi*R/4.)/(Eps/2.)))
- X = 10.*(1.-1./(N+1))
-
-
- EastPt = geompy.MakeVertex (10.0, X, 0.)
- NorthPt = geompy.MakeVertex ( X, 10.0, 0.)
-
- DivFactor = 8./(F2D(math.log(K))-0.223)
- #MidPt = geompy.MakeVertex ((R+Eps)*math.cos(math.pi/4), (R+Eps)*math.sin(math.pi/4), 0.)
- MidPt = geompy.MakeVertex (X-Eps/DivFactor, X-Eps/DivFactor, 0.)
-
- Cutter = []
- Cutter.append(BezierGen(SouthWestPt, MidPt, GetSideAngleForBezier(SouthWestPt,MidPt) , D2R(-5)))
- Cutter.append(BezierGen( EastPt, MidPt, GetSideAngleForBezier(EastPt,MidPt) , D2R(5)))
- Cutter.append(BezierGen( MidPt, NorthPt, (-1)**((K<1.25)*1)*D2R(-5), GetSideAngleForBezier(NorthPt,MidPt)))
- SMBezier = BezierGen( SouthPt, MidPt, GetSideAngleForBezier(SouthPt ,MidPt) , D2R((K<1.25)*180-5))
- WMBezier = BezierGen( WestPt, MidPt, GetSideAngleForBezier(WestPt, MidPt) , D2R(-5))
- Cutter.append(WMBezier)
- Cutter.append(SMBezier)
-
- for i in range(1,N) :
- # Determining intermediate points on the bezier lines and then performing additional cuts
-
- TempAnglePlus = (math.pi/4)*(1+float(i)/N)
- SectionResult = CutnGroup.Go(WMBezier, [(0,0,0,math.sin(TempAnglePlus),-math.cos(TempAnglePlus),0)], [1], ['Dummy'], 0)
- TempPt1 = SectionResult[1][0]
- TempPt11 = geompy.MakeVertex ((N-i)*X/N, 10., 0)
-
- TempAngleMinus = (math.pi/4)*(1-float(i)/N)
- SectionResult = CutnGroup.Go(SMBezier, [(0,0,0,math.sin(TempAngleMinus),-math.cos(TempAngleMinus),0)], [1], ['Dummy'], 0)
- TempPt2 = SectionResult[1][0]
- TempPt21 = geompy.MakeVertex (10., (N-i)*X/N, 0)
-
- Cutter.append(geompy.MakeEdge(SouthWestPt, TempPt1))
- Cutter.append(geompy.MakeEdge(SouthWestPt, TempPt2))
- Cutter.append(geompy.MakeEdge(TempPt1, TempPt11))
- Cutter.append(geompy.MakeEdge(TempPt2, TempPt21))
-
- CylFace = geompy.MakePartition([CylFace],Cutter, [], [],4, 0, [], 0) #Creating the partition object
- CylFace = geompy.MakeTranslation(CylFace, -5., -5., 0.0)
-
- return CylFace
-
+ """
+ This function returns a quarter cylinder to box relay of 1 side length, partitioned
+ with a pitch ratio of K, In other words the side of the box is R*(1+(1/K))
+ """
+ R = 10.*float(K)/(K+1)
+ Eps = 10.- R
+
+ Config.theStudy.SetReal("R" , R)
+ Config.theStudy.SetReal("minusR" , -R)
+ Config.theStudy.SetReal("Eps", Eps)
+
+ CylWire = geompy.MakeSketcher("Sketcher:F 'R' 0:R 0:L 'Eps':TT 10. 10.0:R 90:L 10.0:R 90:L 'Eps':R 90:C 'minusR' 90.0:WW", [0, 0, 0, 0, 0, 1, 1, 0, -0])
+ CylFace = geompy.MakeFace(CylWire, 1)
+
+ SouthPt = geompy.MakeVertex (R+Eps/2., 0., 0)
+ SouthWestPt = geompy.MakeVertex ( 0.,0., 0) #The origin can be used for practical partionning objectifs
+ WestPt = geompy.MakeVertex (0., R+Eps/2., 0)
+
+ N = int(math.floor((math.pi*R/4.)/(Eps/2.)))
+ X = 10.*(1.-1./(N+1))
+
+
+ EastPt = geompy.MakeVertex (10.0, X, 0.)
+ NorthPt = geompy.MakeVertex ( X, 10.0, 0.)
+
+ DivFactor = 8./(F2D(math.log(K))-0.223)
+ #MidPt = geompy.MakeVertex ((R+Eps)*math.cos(math.pi/4), (R+Eps)*math.sin(math.pi/4), 0.)
+ MidPt = geompy.MakeVertex (X-Eps/DivFactor, X-Eps/DivFactor, 0.)
+
+ Cutter = []
+ Cutter.append(BezierGen(SouthWestPt, MidPt, GetSideAngleForBezier(SouthWestPt,MidPt) , D2R(-5)))
+ Cutter.append(BezierGen( EastPt, MidPt, GetSideAngleForBezier(EastPt,MidPt) , D2R(5)))
+ Cutter.append(BezierGen( MidPt, NorthPt, (-1)**((K<1.25)*1)*D2R(-5), GetSideAngleForBezier(NorthPt,MidPt)))
+ SMBezier = BezierGen( SouthPt, MidPt, GetSideAngleForBezier(SouthPt ,MidPt) , D2R((K<1.25)*180-5))
+ WMBezier = BezierGen( WestPt, MidPt, GetSideAngleForBezier(WestPt, MidPt) , D2R(-5))
+ Cutter.append(WMBezier)
+ Cutter.append(SMBezier)
+
+ for i in range(1,N) :
+ # Determining intermediate points on the bezier lines and then performing additional cuts
+
+ TempAnglePlus = (math.pi/4)*(1+float(i)/N)
+ SectionResult = CutnGroup.Go(WMBezier, [(0,0,0,math.sin(TempAnglePlus),-math.cos(TempAnglePlus),0)], [1], ['Dummy'], 0)
+ TempPt1 = SectionResult[1][0]
+ TempPt11 = geompy.MakeVertex ((N-i)*X/N, 10., 0)
+
+ TempAngleMinus = (math.pi/4)*(1-float(i)/N)
+ SectionResult = CutnGroup.Go(SMBezier, [(0,0,0,math.sin(TempAngleMinus),-math.cos(TempAngleMinus),0)], [1], ['Dummy'], 0)
+ TempPt2 = SectionResult[1][0]
+ TempPt21 = geompy.MakeVertex (10., (N-i)*X/N, 0)
+
+ Cutter.append(geompy.MakeEdge(SouthWestPt, TempPt1))
+ Cutter.append(geompy.MakeEdge(SouthWestPt, TempPt2))
+ Cutter.append(geompy.MakeEdge(TempPt1, TempPt11))
+ Cutter.append(geompy.MakeEdge(TempPt2, TempPt21))
+
+ CylFace = geompy.MakePartition([CylFace],Cutter, [], [],4, 0, [], 0) #Creating the partition object
+ CylFace = geompy.MakeTranslation(CylFace, -5., -5., 0.0)
+
+ return CylFace
+
def CompatibilityTest(MacObject):
- Type = MacObject.Type
- if Type == 'Box11' :
- BaseDirPar = [1,1,1,1]
- return int(VecDivRatio(MacObject.DirectionalMeshParams, BaseDirPar))
- elif Type == 'Box42' :
- BaseDirPar = {'SN' : lambda : [3, 3, 4, 2],
- 'NS' : lambda : [3, 3, 2, 4],
- 'EW' : lambda : [2, 4, 3, 3],
- 'WE' : lambda : [4, 2, 3, 3], }[MacObject.MeshPar[1]]()
- return int(VecDivRatio(MacObject.DirectionalMeshParams, BaseDirPar))
- elif Type == 'BoxAng32' :
- BaseDirPar = {'NE' : lambda : [3, 2, 3, 2],
- 'NW' : lambda : [2, 3, 3, 2],
- 'SW' : lambda : [2, 3, 2, 3],
- 'SE' : lambda : [3, 2, 2, 3], }[MacObject.MeshPar[1]]()
- return int(VecDivRatio(MacObject.DirectionalMeshParams, BaseDirPar))
- elif Type == 'CompBox' :
- #print "dx is: ", MacObject.GeoPar[1][1], ". dy is: ",MacObject.GeoPar[1][0]
- ReducedRatio = ReduceRatio(MacObject.GeoPar[1][0], MacObject.GeoPar[1][1])
- #print ReducedRatio
- BaseDirPar = [ReducedRatio[1], ReducedRatio[1], ReducedRatio[0], ReducedRatio[0]]
- return int(VecDivRatio(MacObject.DirectionalMeshParams, BaseDirPar))
-
- elif Type == 'QuartCyl' :
- N = QuarCylParam(MacObject.MeshPar[2])+1
- BaseDirPar = {'NE' : lambda : [2, N, 2, N],
- 'NW' : lambda : [N, 2, 2, N],
- 'SW' : lambda : [N, 2, N, 2],
- 'SE' : lambda : [2, N, N, 2], }[MacObject.MeshPar[1]]()
- return int(VecDivRatio(MacObject.DirectionalMeshParams, BaseDirPar))
- elif Type == 'CompBoxF' :
- RealRatio = MacObject.GeoPar[1][1]/MacObject.GeoPar[1][0]
- Xd = 0
- Yd = 0
- if MacObject.DirectionalMeshParams[2]+MacObject.DirectionalMeshParams[3] :
- A = int(max(MacObject.DirectionalMeshParams[2:4]))
- Xd = int(VecDivRatio([A,0,0,0], [1,1,1,1]))
- if MacObject.DirectionalMeshParams[0]+MacObject.DirectionalMeshParams[1] :
- A = int(max(MacObject.DirectionalMeshParams[0:2]))
- Yd = int(VecDivRatio([0,0,A,0], [1,1,1,1]))
-
- if Xd == 0 and Yd : Xd = int(round(Yd/RealRatio))
- elif Yd == 0 : Yd = int(round(RealRatio*Xd))
-
- return [Xd,Yd]
- elif Type == 'NonOrtho' :
- MeanDX = 0.5*(IntLen(MacObject.DirBoundaries(0))+IntLen(MacObject.DirBoundaries(1)))
- MeanDY = 0.5*(IntLen(MacObject.DirBoundaries(2))+IntLen(MacObject.DirBoundaries(3)))
- RealRatio = MeanDY/MeanDX
- Xd = 0
- Yd = 0
- if MacObject.DirectionalMeshParams[2]+MacObject.DirectionalMeshParams[3] :
- A = int(max(MacObject.DirectionalMeshParams[2:4]))
- Xd = int(VecDivRatio([A,0,0,0], [1,1,1,1]))
- if MacObject.DirectionalMeshParams[0]+MacObject.DirectionalMeshParams[1] :
- A = int(max(MacObject.DirectionalMeshParams[0:2]))
- Yd = int(VecDivRatio([0,0,A,0], [1,1,1,1]))
-
- if Xd == 0 and Yd : Xd = int(round(Yd/RealRatio))
- elif Yd == 0 : Yd = int(round(RealRatio*Xd))
-
- return [Xd,Yd]
+ Type = MacObject.Type
+ if Type == 'Box11' :
+ BaseDirPar = [1,1,1,1]
+ return int(VecDivRatio(MacObject.DirectionalMeshParams, BaseDirPar))
+ elif Type == 'Box42' :
+ BaseDirPar = {'SN' : lambda : [3, 3, 4, 2],
+ 'NS' : lambda : [3, 3, 2, 4],
+ 'EW' : lambda : [2, 4, 3, 3],
+ 'WE' : lambda : [4, 2, 3, 3], }[MacObject.MeshPar[1]]()
+ return int(VecDivRatio(MacObject.DirectionalMeshParams, BaseDirPar))
+ elif Type == 'BoxAng32' :
+ BaseDirPar = {'NE' : lambda : [3, 2, 3, 2],
+ 'NW' : lambda : [2, 3, 3, 2],
+ 'SW' : lambda : [2, 3, 2, 3],
+ 'SE' : lambda : [3, 2, 2, 3], }[MacObject.MeshPar[1]]()
+ return int(VecDivRatio(MacObject.DirectionalMeshParams, BaseDirPar))
+ elif Type == 'CompBox' :
+ #print "dx is: ", MacObject.GeoPar[1][1], ". dy is: ",MacObject.GeoPar[1][0]
+ ReducedRatio = ReduceRatio(MacObject.GeoPar[1][0], MacObject.GeoPar[1][1])
+ #print ReducedRatio
+ BaseDirPar = [ReducedRatio[1], ReducedRatio[1], ReducedRatio[0], ReducedRatio[0]]
+ return int(VecDivRatio(MacObject.DirectionalMeshParams, BaseDirPar))
+
+ elif Type == 'QuartCyl' :
+ N = QuarCylParam(MacObject.MeshPar[2])+1
+ BaseDirPar = {'NE' : lambda : [2, N, 2, N],
+ 'NW' : lambda : [N, 2, 2, N],
+ 'SW' : lambda : [N, 2, N, 2],
+ 'SE' : lambda : [2, N, N, 2], }[MacObject.MeshPar[1]]()
+ return int(VecDivRatio(MacObject.DirectionalMeshParams, BaseDirPar))
+ elif Type == 'CompBoxF' :
+ RealRatio = MacObject.GeoPar[1][1]/MacObject.GeoPar[1][0]
+ Xd = 0
+ Yd = 0
+ if MacObject.DirectionalMeshParams[2]+MacObject.DirectionalMeshParams[3] :
+ A = int(max(MacObject.DirectionalMeshParams[2:4]))
+ Xd = int(VecDivRatio([A,0,0,0], [1,1,1,1]))
+ if MacObject.DirectionalMeshParams[0]+MacObject.DirectionalMeshParams[1] :
+ A = int(max(MacObject.DirectionalMeshParams[0:2]))
+ Yd = int(VecDivRatio([0,0,A,0], [1,1,1,1]))
+
+ if Xd == 0 and Yd : Xd = int(round(Yd/RealRatio))
+ elif Yd == 0 : Yd = int(round(RealRatio*Xd))
+
+ return [Xd,Yd]
+ elif Type == 'NonOrtho' :
+ MeanDX = 0.5*(IntLen(MacObject.DirBoundaries(0))+IntLen(MacObject.DirBoundaries(1)))
+ MeanDY = 0.5*(IntLen(MacObject.DirBoundaries(2))+IntLen(MacObject.DirBoundaries(3)))
+ RealRatio = MeanDY/MeanDX
+ Xd = 0
+ Yd = 0
+ if MacObject.DirectionalMeshParams[2]+MacObject.DirectionalMeshParams[3] :
+ A = int(max(MacObject.DirectionalMeshParams[2:4]))
+ Xd = int(VecDivRatio([A,0,0,0], [1,1,1,1]))
+ if MacObject.DirectionalMeshParams[0]+MacObject.DirectionalMeshParams[1] :
+ A = int(max(MacObject.DirectionalMeshParams[0:2]))
+ Yd = int(VecDivRatio([0,0,A,0], [1,1,1,1]))
+
+ if Xd == 0 and Yd : Xd = int(round(Yd/RealRatio))
+ elif Yd == 0 : Yd = int(round(RealRatio*Xd))
+
+ return [Xd,Yd]
def IntLen (Interval) :
- """
- This function returns the length of a given interval even if the latter is not sorted correctly.
- """
- return abs(Interval[1]-Interval[0])
-
+ """
+ This function returns the length of a given interval even if the latter is not sorted correctly.
+ """
+ return abs(Interval[1]-Interval[0])
+
def NextTo (RefBox, Direction, Extension):
- """
- This functions returns geometrical parameters for easy positioning of neighbouring objects.
- The input (RefBox) and output are in the form : [(X0,Y0),(DX,DY)]
- """
- X0_0 = RefBox[0][0]
- Y0_0 = RefBox[0][1]
- DX_0 = RefBox[1][0]
- DY_0 = RefBox[1][1]
-
- DirectionalCoef = {'Above' : lambda : [ 0, 1],
- 'Below' : lambda : [ 0,-1],
- 'Right' : lambda : [ 1, 0],
- 'Left ' : lambda : [-1, 0], }[Direction]()
-
- X0_1 = X0_0+ DirectionalCoef[0] * (DX_0/2.+Extension/2.)
- DX_1 = abs(DirectionalCoef[0]) * (Extension) + abs(DirectionalCoef[1])*DX_0
- Y0_1 = Y0_0+ DirectionalCoef[1] * (DY_0/2.+Extension/2.)
- DY_1 = abs(DirectionalCoef[1]) * (Extension) + abs(DirectionalCoef[0])*DY_0
-
- return [(X0_1,Y0_1),(DX_1,DY_1)]
-
+ """
+ This functions returns geometrical parameters for easy positioning of neighbouring objects.
+ The input (RefBox) and output are in the form : [(X0,Y0),(DX,DY)]
+ """
+ X0_0 = RefBox[0][0]
+ Y0_0 = RefBox[0][1]
+ DX_0 = RefBox[1][0]
+ DY_0 = RefBox[1][1]
+
+ DirectionalCoef = {'Above' : lambda : [ 0, 1],
+ 'Below' : lambda : [ 0,-1],
+ 'Right' : lambda : [ 1, 0],
+ 'Left ' : lambda : [-1, 0], }[Direction]()
+
+ X0_1 = X0_0+ DirectionalCoef[0] * (DX_0/2.+Extension/2.)
+ DX_1 = abs(DirectionalCoef[0]) * (Extension) + abs(DirectionalCoef[1])*DX_0
+ Y0_1 = Y0_0+ DirectionalCoef[1] * (DY_0/2.+Extension/2.)
+ DY_1 = abs(DirectionalCoef[1]) * (Extension) + abs(DirectionalCoef[0])*DY_0
+
+ return [(X0_1,Y0_1),(DX_1,DY_1)]
+
def GeomMinMax (PtA, PtB):
- """
- This function returns geometrical parameters in the format [(X0,Y0),(DX,DY)]. The input being
- the coordinates of two points (Xa,Ya), (Xb,Yb).
- """
- # First test that the vector relying the two points is oblique
- AB = [PtB[0]- PtA[0],PtB[1]- PtA[1]]
- if 0 in AB :
- print ("Error: the two points are not correctly defined. In the orthonormal system XOY, it is impossible to define a rectangle with these two points")
- return -1
- else:
- X0 = 0.5*(PtA[0]+PtB[0])
- Y0 = 0.5*(PtA[1]+PtB[1])
- DX = abs(AB[0])
- DY = abs(AB[1])
- return [(X0,Y0),(DX,DY)]
+ """
+ This function returns geometrical parameters in the format [(X0,Y0),(DX,DY)]. The input being
+ the coordinates of two points (Xa,Ya), (Xb,Yb).
+ """
+ # First test that the vector relying the two points is oblique
+ AB = [PtB[0]- PtA[0],PtB[1]- PtA[1]]
+ if 0 in AB :
+ print ("Error: the two points are not correctly defined. In the orthonormal system XOY, it is impossible to define a rectangle with these two points")
+ return -1
+ else:
+ X0 = 0.5*(PtA[0]+PtB[0])
+ Y0 = 0.5*(PtA[1]+PtB[1])
+ DX = abs(AB[0])
+ DY = abs(AB[1])
+ return [(X0,Y0),(DX,DY)]
def AddIfDifferent (List, Element):
- if not(Element in List):
- List = List+(Element,)
- return List
+ if not(Element in List):
+ List = List+(Element,)
+ return List
def IndexMultiOcc (Array,Element) :
- """
- This functions returns the occurrences indices of Element in Array.
- As opposed to Array.index(Element) method, this allows determining
- multiple entries rather than just the first one!
- """
- Output = []
- try : Array.index(Element)
- except ValueError : print "No more occurrences"
- else : Output.append(Array.index(Element))
-
- if not(Output == []) and len(Array) > 1 :
- for index, ArrElem in enumerate(Array[Output[0]+1:]) :
- if ArrElem == Element : Output.append(index+Output[0]+1)
-
- return Output
-
+ """
+ This functions returns the occurrences indices of Element in Array.
+ As opposed to Array.index(Element) method, this allows determining
+ multiple entries rather than just the first one!
+ """
+ Output = []
+ try : Array.index(Element)
+ except ValueError : print "No more occurrences"
+ else : Output.append(Array.index(Element))
+
+ if not(Output == []) and len(Array) > 1 :
+ for index, ArrElem in enumerate(Array[Output[0]+1:]) :
+ if ArrElem == Element : Output.append(index+Output[0]+1)
+
+ return Output
+
def SortList (ValList, CritList):
- Output = []
- SortedCritList = copy.copy(CritList)
- SortedCritList.sort()
- for i in range(0,len(ValList)):
- if i > 0 :
- if not(SortedCritList[i]==SortedCritList[i-1]):
- index = IndexMultiOcc(CritList,SortedCritList[i])
- Output= Output + [ValList[j] for j in index]
- else :
- index = IndexMultiOcc(CritList,SortedCritList[i])
- Output= Output + [ValList[j] for j in index]
-
- return Output
+ Output = []
+ SortedCritList = copy.copy(CritList)
+ SortedCritList.sort()
+ for i in range(0,len(ValList)):
+ if i > 0 :
+ if not(SortedCritList[i]==SortedCritList[i-1]):
+ index = IndexMultiOcc(CritList,SortedCritList[i])
+ Output= Output + [ValList[j] for j in index]
+ else :
+ index = IndexMultiOcc(CritList,SortedCritList[i])
+ Output= Output + [ValList[j] for j in index]
+
+ return Output
def SortPoints(Points):
- """
- This function sorts a list of the coordinates of N points as to start at
- an origin that represents Xmin and Xmax and then proceed in a counter
- clock-wise sense
- """
- NbPts = len(Points)
- Xmin = min([Points[i][0] for i in range(NbPts)])
- Ymin = min([Points[i][1] for i in range(NbPts)])
- Xmax = max([Points[i][0] for i in range(NbPts)])
- Ymax = max([Points[i][1] for i in range(NbPts)])
- Crit = [(abs(Point[0]-Xmin)+0.1*(Xmax-Xmin))*(abs(Point[1]-Ymin)+0.1*(Ymax-Ymin)) for Point in Points]
- #print "Input Points : ", Points
- #print "Sorting Criterion : ", Crit
- Order = SortList (range(NbPts), Crit)
- #print "Sorted Results : ", Order
- Output = []
- Output.append(Points[Order[0]])
-
- Point0 = Points[Order[0]]
- #print "Reference point :", Point0
-
- V = [[Point1[0]-Point0[0],Point1[1]-Point0[1]] for Point1 in Points]
- Cosines = [-(vec[0]-1E-10)/(math.sqrt(DotProd(vec,vec)+1e-25)) for vec in V]
- #print "Cosines criterion :", Cosines
- Order = SortList(range(NbPts),Cosines)
- #print "Ordered points:", Order
- for PtIndex in Order[:-1]: Output.append(Points[PtIndex])
-
- return Output
-
+ """
+ This function sorts a list of the coordinates of N points as to start at
+ an origin that represents Xmin and Xmax and then proceed in a counter
+ clock-wise sense
+ """
+ NbPts = len(Points)
+ Xmin = min([Points[i][0] for i in range(NbPts)])
+ Ymin = min([Points[i][1] for i in range(NbPts)])
+ Xmax = max([Points[i][0] for i in range(NbPts)])
+ Ymax = max([Points[i][1] for i in range(NbPts)])
+ Crit = [(abs(Point[0]-Xmin)+0.1*(Xmax-Xmin))*(abs(Point[1]-Ymin)+0.1*(Ymax-Ymin)) for Point in Points]
+ #print "Input Points : ", Points
+ #print "Sorting Criterion : ", Crit
+ Order = SortList (range(NbPts), Crit)
+ #print "Sorted Results : ", Order
+ Output = []
+ Output.append(Points[Order[0]])
+
+ Point0 = Points[Order[0]]
+ #print "Reference point :", Point0
+
+ V = [[Point1[0]-Point0[0],Point1[1]-Point0[1]] for Point1 in Points]
+ Cosines = [-(vec[0]-1E-10)/(math.sqrt(DotProd(vec,vec)+1e-25)) for vec in V]
+ #print "Cosines criterion :", Cosines
+ Order = SortList(range(NbPts),Cosines)
+ #print "Ordered points:", Order
+ for PtIndex in Order[:-1]: Output.append(Points[PtIndex])
+
+ return Output
class MacObject:
- """
- This represents a python class definition which contains
- all necessary information about the macro object being created
- in Salome
- """
+ """
+ This represents a python class definition which contains
+ all necessary information about the macro object being created
+ in Salome
+ """
- def __init__( self, ObjectType, GeoParameters, MeshParameters, **args ):
- """
- Initializes the macro object to be created, saves parameters inside of it, checks for neighboring objects,
- determines meshing parameters if necessary and finally launches the generation process.
- """
- import Config,GenFunctions
- if Config.debug : print "Initializing object No. " + str(len(Config.ListObj)+1)
+ def __init__( self, ObjectType, GeoParameters, MeshParameters, **args ):
+ """
+ Initializes the macro object to be created, saves parameters inside of it, checks for neighboring objects,
+ determines meshing parameters if necessary and finally launches the generation process.
+ """
+ import Config,GenFunctions
+ if Config.debug : print "Initializing object No. " + str(len(Config.ListObj)+1)
- if 'publish' in args :
- if args['publish']==0 : Config.publish = 0
- else : Config.publish = 1
- else : Config.publish = 1
-
- if 'groups' in args :
- self.GroupNames = args['groups']
- for group in args['groups'] :
- if not(group in Config.Groups) and group : Config.Groups.append(group)
- else : self.GroupNames = [None, None, None, None]
-
- if ObjectType == 'NonOrtho':
- if not(len(GeoParameters)==4): print "Error: trying to construct a non-ortho object but the 4 constitutive vertices are not given!"
- else :
- Xmin = min([GeoParameters[i][0] for i in range(4)])
- Xmax = max([GeoParameters[i][0] for i in range(4)])
- Ymin = min([GeoParameters[i][1] for i in range(4)])
- Ymax = max([GeoParameters[i][1] for i in range(4)])
- self.GeoPar = [(0.5*(Xmin+Xmax),0.5*(Ymin+Ymax)),(Xmax-Xmin,Ymax-Ymin)]
- self.PtCoor = GenFunctions.SortPoints(GeoParameters)
- else:
- self.GeoPar = GeoParameters
- [Xmin,Ymin,Xmax,Ymax] = [ self.GeoPar[0][0]-0.5*self.GeoPar[1][0], self.GeoPar[0][1]-0.5*self.GeoPar[1][1] ] + [ self.GeoPar[0][0]+0.5*self.GeoPar[1][0], self.GeoPar[0][1]+0.5*self.GeoPar[1][1] ]
- self.PtCoor = [(Xmin,Ymin),(Xmax,Ymin),(Xmax,Ymax),(Xmin,Ymax)]
-
- self.Type = ObjectType
- self.LowBound = [ self.GeoPar[0][0]-0.5*self.GeoPar[1][0], self.GeoPar[0][1]-0.5*self.GeoPar[1][1] ]
- self.UpperBound = [ self.GeoPar[0][0]+0.5*self.GeoPar[1][0], self.GeoPar[0][1]+0.5*self.GeoPar[1][1] ]
- self.MeshPar = MeshParameters
- self.GeoChildren = []
- self.GeoChildrenNames = []
- self.Mesh = []
- self.MeshGroups = []
- self.CheckInterfaces()
- if 'auto' in MeshParameters : self.AutoParam()
- if not(self.MeshPar[0]<0): self.Generate()
- else :
- Config.ListObj.append(self)
- print("Aborting object creation\n ")
+ if 'publish' in args :
+ if args['publish']==0 : Config.publish = 0
+ else : Config.publish = 1
+ else : Config.publish = 1
- def Generate(self) :
- """
- This method generates the geometrical object with the corresponding mesh once all verifications (CheckInterfaces and AutoParam)
- have been accomplished
- """
- import GenFunctions, Alarms, Config
- self = {'Box11' : lambda : GenFunctions.Box11(self),
- 'Box42' : lambda : GenFunctions.Box42(self),
- 'BoxAng32' : lambda : GenFunctions.BoxAng32(self),
- 'CompBox' : lambda : GenFunctions.CompBox(self),
- 'CompBoxF' : lambda : GenFunctions.CompBoxF(self),
- 'NonOrtho' : lambda : GenFunctions.NonOrtho(self),
- 'QuartCyl' : lambda : GenFunctions.QuartCyl(self) }[self.Type]()
+ if 'groups' in args :
+ self.GroupNames = args['groups']
+ for group in args['groups'] :
+ if not(group in Config.Groups) and group : Config.Groups.append(group)
+ else : self.GroupNames = [None, None, None, None]
- if Config.debug : Alarms.Message(self.status) # notification on the result of the generation algorithm
-
+ if ObjectType == 'NonOrtho':
+ if not(len(GeoParameters)==4): print "Error: trying to construct a non-ortho object but the 4 constitutive vertices are not given!"
+ else :
+ Xmin = min([GeoParameters[i][0] for i in range(4)])
+ Xmax = max([GeoParameters[i][0] for i in range(4)])
+ Ymin = min([GeoParameters[i][1] for i in range(4)])
+ Ymax = max([GeoParameters[i][1] for i in range(4)])
+ self.GeoPar = [(0.5*(Xmin+Xmax),0.5*(Ymin+Ymax)),(Xmax-Xmin,Ymax-Ymin)]
+ self.PtCoor = GenFunctions.SortPoints(GeoParameters)
+ else:
+ self.GeoPar = GeoParameters
+ [Xmin,Ymin,Xmax,Ymax] = [ self.GeoPar[0][0]-0.5*self.GeoPar[1][0], self.GeoPar[0][1]-0.5*self.GeoPar[1][1] ] + [ self.GeoPar[0][0]+0.5*self.GeoPar[1][0], self.GeoPar[0][1]+0.5*self.GeoPar[1][1] ]
+ self.PtCoor = [(Xmin,Ymin),(Xmax,Ymin),(Xmax,Ymax),(Xmin,Ymax)]
- def CheckInterfaces(self):
- """
- This method searches for neighbours for the object being created and saves them inside the Config.Connections
- array. This array contains 4 entries per object corresponding to West, East, South, and North neighbours.
- Note that an object may have more than one neighbour for a given direction.
- """
- import Alarms, Config
- from GenFunctions import AddIfDifferent
- from CompositeBox import FindCommonSide
-
- Config.Connections.append([(-1,),(-1,),(-1,),(-1,)])
- itemID = len(Config.ListObj)
- # In all cases except non ortho, PrincipleBoxes is unitary and contains the box in question
- # In the non-ortho case it contains all possible combinations of boxes with 3 vertices
- PrincipleBoxes = self.PrincipleBoxes()
- for i, TestObj in enumerate(Config.ListObj):
- SecondaryBoxes = TestObj.PrincipleBoxes()
- ConnX = 0
- ConnY = 0
- for Box0 in PrincipleBoxes:
- for Box1 in SecondaryBoxes:
- # Along X
- CenterDis = abs(Box1[0][0]-Box0[0][0])
- Extension = 0.5*(Box1[1][0]+Box0[1][0])
- if CenterDis - Extension < -1e-7 :
- ConnX = -1
- elif CenterDis - Extension < 1e-7 :
- if not(FindCommonSide(self.DirBoundaries(2),TestObj.DirBoundaries(3))==[0,0]) and Box1[0][0] < Box0[0][0] : ConnX = 1
- elif not(FindCommonSide(self.DirBoundaries(3),TestObj.DirBoundaries(2))==[0,0]) and Box1[0][0] >= Box0[0][0]: ConnX = 2
- else : ConnX = 0
-
- # Along Y
- CenterDis = abs(Box1[0][1]-Box0[0][1])
- Extension = 0.5*(Box1[1][1]+Box0[1][1])
- if CenterDis - Extension < -1e-7 :
- ConnY = -1
- elif CenterDis - Extension < 1e-7 :
- if not(FindCommonSide(self.DirBoundaries(0),TestObj.DirBoundaries(1))==[0,0]) and Box1[0][1] < Box0[0][1] : ConnY = 1
- elif not(FindCommonSide(self.DirBoundaries(1),TestObj.DirBoundaries(0))==[0,0]) and Box1[0][1] >= Box0[0][1]: ConnY = 2
- else : ConnY = 0
+ self.Type = ObjectType
+ self.LowBound = [ self.GeoPar[0][0]-0.5*self.GeoPar[1][0], self.GeoPar[0][1]-0.5*self.GeoPar[1][1] ]
+ self.UpperBound = [ self.GeoPar[0][0]+0.5*self.GeoPar[1][0], self.GeoPar[0][1]+0.5*self.GeoPar[1][1] ]
+ self.MeshPar = MeshParameters
+ self.GeoChildren = []
+ self.GeoChildrenNames = []
+ self.Mesh = []
+ self.MeshGroups = []
+ self.CheckInterfaces()
+ if 'auto' in MeshParameters : self.AutoParam()
+ if not(self.MeshPar[0]<0): self.Generate()
+ else :
+ Config.ListObj.append(self)
+ print("Aborting object creation\n ")
- if not (ConnX*ConnY == 0) :
- if max(ConnX,ConnY) == -1 and not('NonOrtho' in [self.Type,TestObj.Type]) : Alarms.Message(3)
- else:
- if ConnX == 1 and ConnY == -1:
- if Config.Connections[i][1] == (-1,) : Config.Connections[i][1] = (itemID,)
- else : Config.Connections[i][1] = AddIfDifferent(Config.Connections[i][1],itemID)
- if Config.Connections[itemID][0] == (-1,) : Config.Connections[itemID][0] = (i,)
- else : Config.Connections[itemID][0] = AddIfDifferent(Config.Connections[itemID][0],i)
- elif ConnX == 2 and ConnY == -1:
- if Config.Connections[i][0] == (-1,) : Config.Connections[i][0] = (itemID,)
- else : Config.Connections[i][0] = AddIfDifferent(Config.Connections[i][0],itemID)
- if Config.Connections[itemID][1] == (-1,) : Config.Connections[itemID][1] = (i,)
- else : Config.Connections[itemID][1] = AddIfDifferent(Config.Connections[itemID][1],i)
- elif ConnY == 1 and ConnX == -1:
- if Config.Connections[i][3] == (-1,) : Config.Connections[i][3] = (itemID,)
- else : Config.Connections[i][3] = AddIfDifferent(Config.Connections[i][3],itemID)
- if Config.Connections[itemID][2] == (-1,) : Config.Connections[itemID][2] = (i,)
- else : Config.Connections[itemID][2] = AddIfDifferent(Config.Connections[itemID][2],i)
- elif ConnY ==2 and ConnX == -1:
- if Config.Connections[i][2] == (-1,) : Config.Connections[i][2] = (itemID,)
- else : Config.Connections[i][2] = AddIfDifferent(Config.Connections[i][2],itemID)
- if Config.Connections[itemID][3] == (-1,) : Config.Connections[itemID][3] = (i,)
- else : Config.Connections[itemID][3] = AddIfDifferent(Config.Connections[itemID][3],i)
+ def Generate(self) :
+ """
+ This method generates the geometrical object with the corresponding mesh once all verifications (CheckInterfaces and AutoParam)
+ have been accomplished
+ """
+ import GenFunctions, Alarms, Config
+ self = {'Box11' : lambda : GenFunctions.Box11(self),
+ 'Box42' : lambda : GenFunctions.Box42(self),
+ 'BoxAng32' : lambda : GenFunctions.BoxAng32(self),
+ 'CompBox' : lambda : GenFunctions.CompBox(self),
+ 'CompBoxF' : lambda : GenFunctions.CompBoxF(self),
+ 'NonOrtho' : lambda : GenFunctions.NonOrtho(self),
+ 'QuartCyl' : lambda : GenFunctions.QuartCyl(self) }[self.Type]()
- def AutoParam (self):
- """
- This method is called only if the 'auto' keyword is used inside the meshing algorithm. It is based on the
- connection results per object and tries to find the correct parameters for obtaining a final compatible mesh
- between the objects already present and the one being created. If this is not possible, the method gives an error
- message.
- """
- import Alarms, Config, GenFunctions, CompositeBox
- MeshPar = [0,0,0,0] # initialize the mesh parameter value to be used to -1
- [(X0,Y0),(DX,DY)] = self.GeoPar
- ObjectsInvolved = []
- for i, Conn in enumerate(Config.Connections[-1]):
- if not ( Conn == (-1,) ): # Meaning that there is one or more neighbors on this direction
- for ObjID in Conn :
- ToLook0 = [2,3,0,1][i]
- ToLook1 = [3,2,1,0][i]
- CommonSide = CompositeBox.FindCommonSide(Config.ListObj[ObjID].DirBoundaries(ToLook1),self.DirBoundaries(ToLook0))
- #print "Common Side is:", CommonSide
- ToLook2 = [1,0,3,2][i]
- #print "Full Side is:", CompositeBox.IntLen(Config.ListObj[ObjID].DirBoundaries(ToLook1))
- #print "Full Segments on this direction are:", Config.ListObj[ObjID].DirectionalMeshParams[ToLook2]
- RealSegments = round(Config.ListObj[ObjID].DirectionalMeshParams[ToLook2]*CompositeBox.IntLen(CommonSide)/CompositeBox.IntLen(Config.ListObj[ObjID].DirBoundaries(ToLook1)))
- #print "RealSegments :", RealSegments
-
- MeshPar[i] = MeshPar[i] + RealSegments
- ObjectsInvolved.append(ObjID+1)
- self.DirectionalMeshParams = MeshPar
- self.MeshPar[0] = GenFunctions.CompatibilityTest(self)
+ if Config.debug : Alarms.Message(self.status) # notification on the result of the generation algorithm
- if self.MeshPar[0] < 0 :
- Alarms.Message(4)
- if self.MeshPar[0] == -1 : print ("Problem encountered with object(s) no. "+str(ObjectsInvolved))
- elif self.MeshPar[0] == -2 : print ("This object has no neighbours !!!")
- def Boundaries (self):
- """
- This method returns the global boundaries of the MacObject. [Xmin,Xmax,Ymin,Ymax]
- """
- Xmin = min([self.DirBoundaries(i)[0] for i in [0,1]])
- Xmax = max([self.DirBoundaries(i)[1] for i in [0,1]])
- Ymin = min([self.DirBoundaries(i)[0] for i in [2,3]])
- Ymax = max([self.DirBoundaries(i)[1] for i in [2,3]])
-
- return [Xmin,Xmax,Ymin,Ymax]
-
- def DirBoundaries (self, Direction):
- """
- This method returns a single interval giving [Xmin,Xmax] or [Ymin,Ymax] according to the required direction.
- This works particularly well for nonorthogonal objects.
- Direction : [0,1,2,3] <=> [South, North, West, East]
- """
- PtCoor = self.PtCoor
- PtCoor.append(self.PtCoor[0])
- if type(Direction) is str :
- Dir = { 'South' : lambda : 0,
- 'North' : lambda : 1,
- 'West' : lambda : 2,
- 'East' : lambda : 3,}[Direction]()
- else : Dir = int(Direction)
-
- PtIndex = [0,2,3,1][Dir]
- DirIndex = [0,0,1,1][Dir]
-
- return sorted([PtCoor[PtIndex][DirIndex],PtCoor[PtIndex+1][DirIndex]])
- def DirVectors (self, Direction):
- """
- This method returns for a given object, the real vectors which define a given direction
- The interest in using this method is for non-orthogonal objects where the sides can be
- deviated from the orthogonal basis vectors
- """
- if type(Direction) is str :
- Dir = { 'South' : lambda : 0,
- 'North' : lambda : 1,
- 'West' : lambda : 2,
- 'East' : lambda : 3,}[Direction]()
- else : Dir = int(Direction)
- PtCoor = self.PtCoor
- PtCoor.append(self.PtCoor[0])
- PtIndex = [0,2,3,1][Dir]
- return [PtCoor[PtIndex+1][0]-PtCoor[PtIndex][0],PtCoor[PtIndex+1][1]-PtCoor[PtIndex][1],0.]
-
- def GetBorder (self, Criterion):
- import GenFunctions, Config
+ def CheckInterfaces(self):
+ """
+ This method searches for neighbours for the object being created and saves them inside the Config.Connections
+ array. This array contains 4 entries per object corresponding to West, East, South, and North neighbours.
+ Note that an object may have more than one neighbour for a given direction.
+ """
+ import Alarms, Config
+ from GenFunctions import AddIfDifferent
+ from CompositeBox import FindCommonSide
- from salome.geom import geomBuilder
- geompy = geomBuilder.New( Config.theStudy )
-
- if type(Criterion) is str :
- Crit = {'South' : lambda : 0,
- 'North' : lambda : 1,
- 'West' : lambda : 2,
- 'East' : lambda : 3,}[Criterion]()
- else : Crit = int(Criterion)
-
- AcceptedObj = []
- if Crit < 4 :
- Boundaries = self.Boundaries()
- Research = {0 : lambda : [self.DirVectors(0),1,Boundaries[2]],
- 1 : lambda : [self.DirVectors(1),1,Boundaries[3]],
- 2 : lambda : [self.DirVectors(2),0,Boundaries[0]],
- 3 : lambda : [self.DirVectors(3),0,Boundaries[1]], }[Crit]()
-
- for i,ElemObj in enumerate(self.GeoChildren):
- EdgeIDs = geompy.ExtractShapes(ElemObj,6)# List of Edge IDs belonging to ElemObj
- for Edge in EdgeIDs:
- if GenFunctions.IsParallel(Edge,Research[0]):
- if abs( geompy.PointCoordinates(geompy.GetVertexByIndex(Edge,0))[Research[1]] - Research[2] )< 1e-6 or abs( geompy.PointCoordinates(geompy.GetVertexByIndex(Edge,1))[Research[1]] - Research[2] )< 1e-6 :
- AcceptedObj.append(Edge)
- else :
- CenterSrchPar = {'NE' : lambda : [-1., -1.],
- 'NW' : lambda : [ 1., -1.],
- 'SW' : lambda : [ 1., 1.],
- 'SE' : lambda : [-1., 1.], }[self.MeshPar[1]]()
- Radius = self.GeoPar[1][1]*float(self.MeshPar[2])/(self.MeshPar[2]+1)
- Center = (self.GeoPar[0][0]+CenterSrchPar[0]*self.GeoPar[1][0]/2.,self.GeoPar[0][1]+CenterSrchPar[1]*self.GeoPar[1][1]/2.,0.)
- for i,ElemObj in enumerate(self.GeoChildren):
- EdgeIDs = geompy.ExtractShapes(ElemObj,6)# List of Edge IDs belonging to ElemObj
- for Edge in EdgeIDs:
- if GenFunctions.IsOnCircle(Edge,Center,Radius):
- AcceptedObj.append(Edge)
- return AcceptedObj
+ Config.Connections.append([(-1,),(-1,),(-1,),(-1,)])
+ itemID = len(Config.ListObj)
+ # In all cases except non ortho, PrincipleBoxes is unitary and contains the box in question
+ # In the non-ortho case it contains all possible combinations of boxes with 3 vertices
+ PrincipleBoxes = self.PrincipleBoxes()
+ for i, TestObj in enumerate(Config.ListObj):
+ SecondaryBoxes = TestObj.PrincipleBoxes()
+ ConnX = 0
+ ConnY = 0
+ for Box0 in PrincipleBoxes:
+ for Box1 in SecondaryBoxes:
+ # Along X
+ CenterDis = abs(Box1[0][0]-Box0[0][0])
+ Extension = 0.5*(Box1[1][0]+Box0[1][0])
+ if CenterDis - Extension < -1e-7 :
+ ConnX = -1
+ elif CenterDis - Extension < 1e-7 :
+ if not(FindCommonSide(self.DirBoundaries(2),TestObj.DirBoundaries(3))==[0,0]) and Box1[0][0] < Box0[0][0] : ConnX = 1
+ elif not(FindCommonSide(self.DirBoundaries(3),TestObj.DirBoundaries(2))==[0,0]) and Box1[0][0] >= Box0[0][0]: ConnX = 2
+ else : ConnX = 0
- def PrincipleBoxes (self):
- """
- This function returns all possible combination rectangular shape objects that can contain at least 3 of the principle vertices
- constituting the MacObject. This is indispensable for the Non-ortho types and shall return a number of 24 possible combinations
- """
- from itertools import combinations
- Boxes = []
- if self.Type == 'NonOrtho':
- for combi in combinations(range(4),3):
- Xmin = min([self.PtCoor[i][0] for i in combi])
- Xmax = max([self.PtCoor[i][0] for i in combi])
- Ymin = min([self.PtCoor[i][1] for i in combi])
- Ymax = max([self.PtCoor[i][1] for i in combi])
- Boxes.append([(0.5*(Xmin+Xmax),0.5*(Ymin+Ymax)),(Xmax-Xmin,Ymax-Ymin)])
- else :
- Boxes = [self.GeoPar]
-
- return Boxes
-
-
+ # Along Y
+ CenterDis = abs(Box1[0][1]-Box0[0][1])
+ Extension = 0.5*(Box1[1][1]+Box0[1][1])
+ if CenterDis - Extension < -1e-7 :
+ ConnY = -1
+ elif CenterDis - Extension < 1e-7 :
+ if not(FindCommonSide(self.DirBoundaries(0),TestObj.DirBoundaries(1))==[0,0]) and Box1[0][1] < Box0[0][1] : ConnY = 1
+ elif not(FindCommonSide(self.DirBoundaries(1),TestObj.DirBoundaries(0))==[0,0]) and Box1[0][1] >= Box0[0][1]: ConnY = 2
+ else : ConnY = 0
+
+ if not (ConnX*ConnY == 0) :
+ if max(ConnX,ConnY) == -1 and not('NonOrtho' in [self.Type,TestObj.Type]) : Alarms.Message(3)
+ else:
+ if ConnX == 1 and ConnY == -1:
+ if Config.Connections[i][1] == (-1,) : Config.Connections[i][1] = (itemID,)
+ else : Config.Connections[i][1] = AddIfDifferent(Config.Connections[i][1],itemID)
+ if Config.Connections[itemID][0] == (-1,) : Config.Connections[itemID][0] = (i,)
+ else : Config.Connections[itemID][0] = AddIfDifferent(Config.Connections[itemID][0],i)
+ elif ConnX == 2 and ConnY == -1:
+ if Config.Connections[i][0] == (-1,) : Config.Connections[i][0] = (itemID,)
+ else : Config.Connections[i][0] = AddIfDifferent(Config.Connections[i][0],itemID)
+ if Config.Connections[itemID][1] == (-1,) : Config.Connections[itemID][1] = (i,)
+ else : Config.Connections[itemID][1] = AddIfDifferent(Config.Connections[itemID][1],i)
+ elif ConnY == 1 and ConnX == -1:
+ if Config.Connections[i][3] == (-1,) : Config.Connections[i][3] = (itemID,)
+ else : Config.Connections[i][3] = AddIfDifferent(Config.Connections[i][3],itemID)
+ if Config.Connections[itemID][2] == (-1,) : Config.Connections[itemID][2] = (i,)
+ else : Config.Connections[itemID][2] = AddIfDifferent(Config.Connections[itemID][2],i)
+ elif ConnY ==2 and ConnX == -1:
+ if Config.Connections[i][2] == (-1,) : Config.Connections[i][2] = (itemID,)
+ else : Config.Connections[i][2] = AddIfDifferent(Config.Connections[i][2],itemID)
+ if Config.Connections[itemID][3] == (-1,) : Config.Connections[itemID][3] = (i,)
+ else : Config.Connections[itemID][3] = AddIfDifferent(Config.Connections[itemID][3],i)
+
+ def AutoParam (self):
+ """
+ This method is called only if the 'auto' keyword is used inside the meshing algorithm. It is based on the
+ connection results per object and tries to find the correct parameters for obtaining a final compatible mesh
+ between the objects already present and the one being created. If this is not possible, the method gives an error
+ message.
+ """
+ import Alarms, Config, GenFunctions, CompositeBox
+ MeshPar = [0,0,0,0] # initialize the mesh parameter value to be used to -1
+ [(X0,Y0),(DX,DY)] = self.GeoPar
+ ObjectsInvolved = []
+ for i, Conn in enumerate(Config.Connections[-1]):
+ if not ( Conn == (-1,) ): # Meaning that there is one or more neighbors on this direction
+ for ObjID in Conn :
+ ToLook0 = [2,3,0,1][i]
+ ToLook1 = [3,2,1,0][i]
+ CommonSide = CompositeBox.FindCommonSide(Config.ListObj[ObjID].DirBoundaries(ToLook1),self.DirBoundaries(ToLook0))
+ #print "Common Side is:", CommonSide
+ ToLook2 = [1,0,3,2][i]
+ #print "Full Side is:", CompositeBox.IntLen(Config.ListObj[ObjID].DirBoundaries(ToLook1))
+ #print "Full Segments on this direction are:", Config.ListObj[ObjID].DirectionalMeshParams[ToLook2]
+ RealSegments = round(Config.ListObj[ObjID].DirectionalMeshParams[ToLook2]*CompositeBox.IntLen(CommonSide)/CompositeBox.IntLen(Config.ListObj[ObjID].DirBoundaries(ToLook1)))
+ #print "RealSegments :", RealSegments
+
+ MeshPar[i] = MeshPar[i] + RealSegments
+ ObjectsInvolved.append(ObjID+1)
+ self.DirectionalMeshParams = MeshPar
+ self.MeshPar[0] = GenFunctions.CompatibilityTest(self)
+
+ if self.MeshPar[0] < 0 :
+ Alarms.Message(4)
+ if self.MeshPar[0] == -1 : print ("Problem encountered with object(s) no. "+str(ObjectsInvolved))
+ elif self.MeshPar[0] == -2 : print ("This object has no neighbours !!!")
+
+ def Boundaries (self):
+ """
+ This method returns the global boundaries of the MacObject. [Xmin,Xmax,Ymin,Ymax]
+ """
+ Xmin = min([self.DirBoundaries(i)[0] for i in [0,1]])
+ Xmax = max([self.DirBoundaries(i)[1] for i in [0,1]])
+ Ymin = min([self.DirBoundaries(i)[0] for i in [2,3]])
+ Ymax = max([self.DirBoundaries(i)[1] for i in [2,3]])
+
+ return [Xmin,Xmax,Ymin,Ymax]
+
+ def DirBoundaries (self, Direction):
+ """
+ This method returns a single interval giving [Xmin,Xmax] or [Ymin,Ymax] according to the required direction.
+ This works particularly well for nonorthogonal objects.
+ Direction : [0,1,2,3] <=> [South, North, West, East]
+ """
+ PtCoor = self.PtCoor
+ PtCoor.append(self.PtCoor[0])
+ if type(Direction) is str :
+ Dir = { 'South' : lambda : 0,
+ 'North' : lambda : 1,
+ 'West' : lambda : 2,
+ 'East' : lambda : 3,}[Direction]()
+ else : Dir = int(Direction)
+
+ PtIndex = [0,2,3,1][Dir]
+ DirIndex = [0,0,1,1][Dir]
+
+ return sorted([PtCoor[PtIndex][DirIndex],PtCoor[PtIndex+1][DirIndex]])
+ def DirVectors (self, Direction):
+ """
+ This method returns for a given object, the real vectors which define a given direction
+ The interest in using this method is for non-orthogonal objects where the sides can be
+ deviated from the orthogonal basis vectors
+ """
+ if type(Direction) is str :
+ Dir = { 'South' : lambda : 0,
+ 'North' : lambda : 1,
+ 'West' : lambda : 2,
+ 'East' : lambda : 3,}[Direction]()
+ else : Dir = int(Direction)
+ PtCoor = self.PtCoor
+ PtCoor.append(self.PtCoor[0])
+ PtIndex = [0,2,3,1][Dir]
+ return [PtCoor[PtIndex+1][0]-PtCoor[PtIndex][0],PtCoor[PtIndex+1][1]-PtCoor[PtIndex][1],0.]
+
+ def GetBorder (self, Criterion):
+ import GenFunctions, Config
+
+ from salome.geom import geomBuilder
+ geompy = geomBuilder.New( Config.theStudy )
+
+ if type(Criterion) is str :
+ Crit = {'South' : lambda : 0,
+ 'North' : lambda : 1,
+ 'West' : lambda : 2,
+ 'East' : lambda : 3,}[Criterion]()
+ else : Crit = int(Criterion)
+
+ AcceptedObj = []
+ if Crit < 4 :
+ Boundaries = self.Boundaries()
+ Research = {0 : lambda : [self.DirVectors(0),1,Boundaries[2]],
+ 1 : lambda : [self.DirVectors(1),1,Boundaries[3]],
+ 2 : lambda : [self.DirVectors(2),0,Boundaries[0]],
+ 3 : lambda : [self.DirVectors(3),0,Boundaries[1]], }[Crit]()
+
+ for i,ElemObj in enumerate(self.GeoChildren):
+ EdgeIDs = geompy.ExtractShapes(ElemObj,6)# List of Edge IDs belonging to ElemObj
+ for Edge in EdgeIDs:
+ if GenFunctions.IsParallel(Edge,Research[0]):
+ if abs( geompy.PointCoordinates(geompy.GetVertexByIndex(Edge,0))[Research[1]] - Research[2] )< 1e-6 or abs( geompy.PointCoordinates(geompy.GetVertexByIndex(Edge,1))[Research[1]] - Research[2] )< 1e-6 :
+ AcceptedObj.append(Edge)
+ else :
+ CenterSrchPar = {'NE' : lambda : [-1., -1.],
+ 'NW' : lambda : [ 1., -1.],
+ 'SW' : lambda : [ 1., 1.],
+ 'SE' : lambda : [-1., 1.], }[self.MeshPar[1]]()
+ Radius = self.GeoPar[1][1]*float(self.MeshPar[2])/(self.MeshPar[2]+1)
+ Center = (self.GeoPar[0][0]+CenterSrchPar[0]*self.GeoPar[1][0]/2.,self.GeoPar[0][1]+CenterSrchPar[1]*self.GeoPar[1][1]/2.,0.)
+ for i,ElemObj in enumerate(self.GeoChildren):
+ EdgeIDs = geompy.ExtractShapes(ElemObj,6)# List of Edge IDs belonging to ElemObj
+ for Edge in EdgeIDs:
+ if GenFunctions.IsOnCircle(Edge,Center,Radius):
+ AcceptedObj.append(Edge)
+ return AcceptedObj
+
+ def PrincipleBoxes (self):
+ """
+ This function returns all possible combination rectangular shape objects that can contain at least 3 of the principle vertices
+ constituting the MacObject. This is indispensable for the Non-ortho types and shall return a number of 24 possible combinations
+ """
+ from itertools import combinations
+ Boxes = []
+ if self.Type == 'NonOrtho':
+ for combi in combinations(range(4),3):
+ Xmin = min([self.PtCoor[i][0] for i in combi])
+ Xmax = max([self.PtCoor[i][0] for i in combi])
+ Ymin = min([self.PtCoor[i][1] for i in combi])
+ Ymax = max([self.PtCoor[i][1] for i in combi])
+ Boxes.append([(0.5*(Xmin+Xmax),0.5*(Ymin+Ymax)),(Xmax-Xmin,Ymax-Ymin)])
+ else :
+ Boxes = [self.GeoPar]
+
+ return Boxes
# See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
#
-#
+#
import SMESH
import math
import Config
##########################################################################################################
def PublishGroups ():
- aFilterManager = smesh.CreateFilterManager()
+ aFilterManager = smesh.CreateFilterManager()
+
+ # Building geometric and mesh compounds and groups ##############################################
+ if Config.debug : print "Searching for geometric groups and publishing final compound"
+
+ TempGEOList = []
+ TempMESHList = []
+
+ for MacroObj in Config.ListObj :
+ TempGEOList += MacroObj.GeoChildren
+ TempMESHList += MacroObj.Mesh
- # Building geometric and mesh compounds and groups ##############################################
- if Config.debug : print "Searching for geometric groups and publishing final compound"
-
+ FinalCompound = geompy.MakeCompound(TempGEOList)
+ geompy.addToStudy (FinalCompound,Config.StudyName)
+ MeshCompound = smesh.Concatenate(TempMESHList, 1, 1, 1e-5)
+ MeshCompound.SetName(Config.StudyName)
+
+ GroupGEO = []
+ for group in Config.Groups :
+
+ # Geometric groups definition
TempGEOList = []
- TempMESHList = []
-
- for MacroObj in Config.ListObj :
- TempGEOList += MacroObj.GeoChildren
- TempMESHList += MacroObj.Mesh
-
- FinalCompound = geompy.MakeCompound(TempGEOList)
- geompy.addToStudy (FinalCompound,Config.StudyName)
- MeshCompound = smesh.Concatenate(TempMESHList, 1, 1, 1e-5)
- MeshCompound.SetName(Config.StudyName)
-
- GroupGEO = []
- for group in Config.Groups :
-
- # Geometric groups definition
- TempGEOList = []
- TempNames = []
- for MacroObj in Config.ListObj :
- if group in MacroObj.GroupNames :
- Occurences = IndexMultiOcc(MacroObj.GroupNames, group)
- for Occ in Occurences :
- TempGEOList += MacroObj.GetBorder(Occ)
- GroupGEO.append(geompy.MakeCompound(TempGEOList))
- geompy.addToStudyInFather(FinalCompound,GroupGEO[-1],'GR_'+group)
-
- # Mesh groups definition
- Criterion = smesh.GetCriterion(SMESH.EDGE, SMESH.FT_BelongToGeom,'=',GroupGEO[-1],Tolerance=1e-06)
- #Criterion = smesh.Filter.Criterion(18,39,0,'GR_'+group,'GR_'+group,39,39,1e-06,smesh.EDGE,7)
- MeshCompound.MakeGroupByCriterion(group,Criterion)
-
- StudyBuilder = Config.theStudy.NewBuilder()
- for MeshObj in TempMESHList:
- SO = Config.theStudy.FindObjectIOR(Config.theStudy.ConvertObjectToIOR(MeshObj))
- if SO is not None: StudyBuilder.RemoveObjectWithChildren(SO)
-
- return MeshCompound
-
+ TempNames = []
+ for MacroObj in Config.ListObj :
+ if group in MacroObj.GroupNames :
+ Occurences = IndexMultiOcc(MacroObj.GroupNames, group)
+ for Occ in Occurences :
+ TempGEOList += MacroObj.GetBorder(Occ)
+ GroupGEO.append(geompy.MakeCompound(TempGEOList))
+ geompy.addToStudyInFather(FinalCompound,GroupGEO[-1],'GR_'+group)
+
+ # Mesh groups definition
+ Criterion = smesh.GetCriterion(SMESH.EDGE, SMESH.FT_BelongToGeom,'=',GroupGEO[-1],Tolerance=1e-06)
+ #Criterion = smesh.Filter.Criterion(18,39,0,'GR_'+group,'GR_'+group,39,39,1e-06,smesh.EDGE,7)
+ MeshCompound.MakeGroupByCriterion(group,Criterion)
+
+ StudyBuilder = Config.theStudy.NewBuilder()
+ for MeshObj in TempMESHList:
+ SO = Config.theStudy.FindObjectIOR(Config.theStudy.ConvertObjectToIOR(MeshObj))
+ if SO is not None: StudyBuilder.RemoveObjectWithChildren(SO)
+
+ return MeshCompound
+
def IndexMultiOcc (Array,Element) :
- """
- This function returns the occurrences indices of Element in Array.
- As opposed to Array.index(Element) method, this allows determining
- multiple entries rather than just the first one!
- """
- Output = []
- try : Array.index(Element)
- except ValueError : print "No more occurrences"
- else : Output.append(Array.index(Element))
-
- if not(Output == [-1]) and len(Array) > 1 :
- for index, ArrElem in enumerate(Array[Output[0]+1:]) :
- if ArrElem is Element : Output.append(index+Output[0]+1)
-
- return Output
-
+ """
+ This function returns the occurrences indices of Element in Array.
+ As opposed to Array.index(Element) method, this allows determining
+ multiple entries rather than just the first one!
+ """
+ Output = []
+ try : Array.index(Element)
+ except ValueError : print "No more occurrences"
+ else : Output.append(Array.index(Element))
+
+ if not(Output == [-1]) and len(Array) > 1 :
+ for index, ArrElem in enumerate(Array[Output[0]+1:]) :
+ if ArrElem is Element : Output.append(index+Output[0]+1)
+
+ return Output
+
def Publish (ObjToPublish):
- for i,GeoObj in enumerate(ObjToPublish) : geompy.addToStudy(GeoObj,"Sub_"+str(i))
-
+ for i,GeoObj in enumerate(ObjToPublish) : geompy.addToStudy(GeoObj,"Sub_"+str(i))
+
def RevolveMesh(MainMesh,**args):
- """
- This function premits to revolute and scale a 2D mesh while transforming the edge
- groups into face groups. Moreover, the function automatically creates the face groups
- corresponding to the symmetry lower and upper faces
- Facultatif arguments are :
- - Center [X,Y,Z], origin being the default
- - Direction [VX,VY,VZ], x-axis being the default
- - AngleDeg or AngleRad : ALPHA, 10 degrees being the default
- - Scale : BETA, no scaling being default
- """
- ################################################################################
- # Reading input arguments and proceeding to defaults if necessary
- ################################################################################
- if 'Center' in args : CenterCoor = [float(Coor) for Coor in args['Center']]
- else :
- print "\nThe coordinates of the center of revolution were not given\nThe origin is used by default."
- CenterCoor = [0.,0.,0.]
-
- if 'Direction' in args : Direction = [float(Dir) for Dir in args['Direction']]
- else :
- print "\nThe axis vector of revolution was not given\nThe x-axis is used by default."
- Direction = [1.,0.,0.]
-
- if 'AngleDeg' in args : Angle = float(args['AngleDeg'])*math.pi/180.
- elif 'AngleRad' in args : Angle = float(args['AngleRad'])
- else :
- print "\nThe revolution angle was not given\nAn angle of 10 degrees is used by default."
- Angle = 10.*math.pi/180.
-
- if 'Scale' in args : Scale = float(args['Scale'])
- else : Scale = 1.
-
-
- # Creating the lower face group LOFAC
- LOFAC = MainMesh.CreateEmptyGroup( SMESH.FACE, 'LOFAC' )
- LOFAC.AddFrom(MainMesh.GetMesh())
-
- GR_Names = MainMesh.GetGroupNames()
- GRs = MainMesh.GetGroups()
- Rev3DMeshGroups = MainMesh.RotationSweepObject2D( MainMesh, SMESH.AxisStruct( CenterCoor[0], CenterCoor[1], CenterCoor[2], Direction[0], Direction[1], Direction[2] ), Angle, 1, 1e-05 ,True)
-
- # Adding an EDGE suffix to the edge groups (to be deleted eventually by the user...)
- for GR in GRs:
- CurrentName = GR.GetName()
- if CurrentName in GR_Names and not(CurrentName=='LOFAC'): # Meaning that this is an old edge group
- GR.SetName(CurrentName+'_EDGE')
-
- # Removing the _rotated prefix from the rotated FACE groups
- for GR in Rev3DMeshGroups:
- CurrentName = GR.GetName()
- if CurrentName.endswith( "_rotated"):
- if CurrentName.startswith( 'LOFAC_' ):
- GR.SetName('VOL')
- else:
- GR.SetName(CurrentName[:-8])
- elif CurrentName == 'LOFAC_top':
- GR.SetName('HIFAC')
- #Index = [ GR_Names[i] in CurrentName for i in range(0,len(GR_Names)) ].index(True)
- #GR.SetName(GR_Names[Index])
-
- # Creating the upper face group HIFAC
- ALLFAC = MainMesh.CreateEmptyGroup( SMESH.FACE, 'ALLFAC' )
- ALLFAC.AddFrom(MainMesh.GetMesh())
-
- #HIFAC = MainMesh.GetMesh().CutListOfGroups( [ ALLFAC ], [LOFAC] + [ MeshGroup for MeshGroup in Rev3DMeshGroups if not(MeshGroup.GetName()=='VOL') ], 'HIFAC' )
- #HIFAC = MainMesh.GetMesh().CutListOfGroups( [ ALLFAC ], [LOFAC] + [ MeshGroup for MeshGroup in Rev3DMeshGroups if ( not(MeshGroup.GetName()=='VOL') and MeshGroup.GetType() == SMESH.FACE )], 'HIFAC' )
-
- # Scaling down the mesh to meter units
- if not(Scale==1.):
- MeshEditor = MainMesh.GetMeshEditor()
- MeshEditor.Scale( MainMesh.GetMesh(), SMESH.PointStruct( 0, 0, 0 ) ,[ Scale, Scale, Scale ], 0 )
-
-
+ """
+ This function premits to revolute and scale a 2D mesh while transforming the edge
+ groups into face groups. Moreover, the function automatically creates the face groups
+ corresponding to the symmetry lower and upper faces
+ Facultatif arguments are :
+ - Center [X,Y,Z], origin being the default
+ - Direction [VX,VY,VZ], x-axis being the default
+ - AngleDeg or AngleRad : ALPHA, 10 degrees being the default
+ - Scale : BETA, no scaling being default
+ """
+ ################################################################################
+ # Reading input arguments and proceeding to defaults if necessary
+ ################################################################################
+ if 'Center' in args : CenterCoor = [float(Coor) for Coor in args['Center']]
+ else :
+ print "\nThe coordinates of the center of revolution were not given\nThe origin is used by default."
+ CenterCoor = [0.,0.,0.]
+
+ if 'Direction' in args : Direction = [float(Dir) for Dir in args['Direction']]
+ else :
+ print "\nThe axis vector of revolution was not given\nThe x-axis is used by default."
+ Direction = [1.,0.,0.]
+
+ if 'AngleDeg' in args : Angle = float(args['AngleDeg'])*math.pi/180.
+ elif 'AngleRad' in args : Angle = float(args['AngleRad'])
+ else :
+ print "\nThe revolution angle was not given\nAn angle of 10 degrees is used by default."
+ Angle = 10.*math.pi/180.
+
+ if 'Scale' in args : Scale = float(args['Scale'])
+ else : Scale = 1.
+
+
+ # Creating the lower face group LOFAC
+ LOFAC = MainMesh.CreateEmptyGroup( SMESH.FACE, 'LOFAC' )
+ LOFAC.AddFrom(MainMesh.GetMesh())
+
+ GR_Names = MainMesh.GetGroupNames()
+ GRs = MainMesh.GetGroups()
+ Rev3DMeshGroups = MainMesh.RotationSweepObject2D( MainMesh, SMESH.AxisStruct( CenterCoor[0], CenterCoor[1], CenterCoor[2], Direction[0], Direction[1], Direction[2] ), Angle, 1, 1e-05 ,True)
+
+ # Adding an EDGE suffix to the edge groups (to be deleted eventually by the user...)
+ for GR in GRs:
+ CurrentName = GR.GetName()
+ if CurrentName in GR_Names and not(CurrentName=='LOFAC'): # Meaning that this is an old edge group
+ GR.SetName(CurrentName+'_EDGE')
+
+ # Removing the _rotated prefix from the rotated FACE groups
+ for GR in Rev3DMeshGroups:
+ CurrentName = GR.GetName()
+ if CurrentName.endswith( "_rotated"):
+ if CurrentName.startswith( 'LOFAC_' ):
+ GR.SetName('VOL')
+ else:
+ GR.SetName(CurrentName[:-8])
+ elif CurrentName == 'LOFAC_top':
+ GR.SetName('HIFAC')
+ #Index = [ GR_Names[i] in CurrentName for i in range(0,len(GR_Names)) ].index(True)
+ #GR.SetName(GR_Names[Index])
+
+ # Creating the upper face group HIFAC
+ ALLFAC = MainMesh.CreateEmptyGroup( SMESH.FACE, 'ALLFAC' )
+ ALLFAC.AddFrom(MainMesh.GetMesh())
+
+ #HIFAC = MainMesh.GetMesh().CutListOfGroups( [ ALLFAC ], [LOFAC] + [ MeshGroup for MeshGroup in Rev3DMeshGroups if not(MeshGroup.GetName()=='VOL') ], 'HIFAC' )
+ #HIFAC = MainMesh.GetMesh().CutListOfGroups( [ ALLFAC ], [LOFAC] + [ MeshGroup for MeshGroup in Rev3DMeshGroups if ( not(MeshGroup.GetName()=='VOL') and MeshGroup.GetType() == SMESH.FACE )], 'HIFAC' )
+
+ # Scaling down the mesh to meter units
+ if not(Scale==1.):
+ MeshEditor = MainMesh.GetMeshEditor()
+ MeshEditor.Scale( MainMesh.GetMesh(), SMESH.PointStruct( 0, 0, 0 ) ,[ Scale, Scale, Scale ], 0 )
+
+
def ExtrudeMesh(MainMesh,**args):
- """
- This function premits to extrude and scale a 2D mesh while transforming the edge
- groups into face groups. Moreover, the function automatically creates the face groups
- corresponding to the symmetry lower and upper faces
- Facultatif arguments are :
- - Direction [VX,VY,VZ], z-axis being default
- - Distance : D, default is 1
- - NSteps : the object will be extruded by NSteps*Distance, default is Nsteps = 1
- - Scale : BETA, no scaling being default
- """
- ################################################################################
- # Reading input arguments and proceeding to defaults if necessary
- ################################################################################
- if 'Distance' in args : Distance = float(args['Distance'])
- else :
- print "\nThe extrusion distance was not given\nA default value of 1 is used."
- Distance = 1.
-
- if 'Direction' in args : Direction = NormalizeVector([float(Dir) for Dir in args['Direction']],Distance)
- else :
- print "\nThe extrusion vector of revolution was not given\nThe z-axis is used by default."
- Direction = NormalizeVector([0.,0.,1.],Distance)
-
- if 'Scale' in args : Scale = float(args['Scale'])
- else : Scale = 1.
-
- if 'NSteps' in args : NSteps = int(args['NSteps'])
- else : NSteps = 1
-
- # Creating the lower face group LOFAC
- LOFAC = MainMesh.CreateEmptyGroup( SMESH.FACE, 'LOFAC' )
- LOFAC.AddFrom(MainMesh.GetMesh())
-
- GR_Names = MainMesh.GetGroupNames()
- GRs = MainMesh.GetGroups()
- Ext3DMeshGroups = MainMesh.ExtrusionSweepObject2D(MainMesh,SMESH.DirStruct(SMESH.PointStruct(Direction[0],Direction[1],Direction[2])), NSteps, True)
-
- # Adding an EDGE suffix to the edge groups (to be deleted eventually by the user...)
- for GR in GRs:
- CurrentName = GR.GetName()
- if CurrentName in GR_Names and not(CurrentName=='LOFAC'): # Meaning that this is an old edge group
- GR.SetName(CurrentName+'_EDGE')
-
- # Removing the _extruded suffix from the extruded FACE groups
- for GR in Ext3DMeshGroups:
- CurrentName = GR.GetName()
- if CurrentName.endswith( "_extruded"):
- if CurrentName.startswith( 'LOFAC_' ):
- GR.SetName('VOL')
- else:
- GR.SetName(CurrentName[:-9])
- elif CurrentName == 'LOFAC_top':
- GR.SetName('HIFAC')
-
- # Creating the upper face group HIFAC
- ALLFAC = MainMesh.CreateEmptyGroup( SMESH.FACE, 'ALLFAC' )
- ALLFAC.AddFrom(MainMesh.GetMesh())
-
- #HIFAC = MainMesh.GetMesh().CutListOfGroups( [ ALLFAC ], [LOFAC] + [ MeshGroup for MeshGroup in Ext3DMeshGroups if not(MeshGroup.GetName()=='VOL') ], 'HIFAC' )
-
- # Scaling down the mesh to meter units
- if not(Scale==1.):
- MeshEditor = MainMesh.GetMeshEditor()
- MeshEditor.Scale( MainMesh.GetMesh(), SMESH.PointStruct( 0, 0, 0 ) ,[ Scale, Scale, Scale ], 0 )
-
-
+ """
+ This function premits to extrude and scale a 2D mesh while transforming the edge
+ groups into face groups. Moreover, the function automatically creates the face groups
+ corresponding to the symmetry lower and upper faces
+ Facultatif arguments are :
+ - Direction [VX,VY,VZ], z-axis being default
+ - Distance : D, default is 1
+ - NSteps : the object will be extruded by NSteps*Distance, default is Nsteps = 1
+ - Scale : BETA, no scaling being default
+ """
+ ################################################################################
+ # Reading input arguments and proceeding to defaults if necessary
+ ################################################################################
+ if 'Distance' in args : Distance = float(args['Distance'])
+ else :
+ print "\nThe extrusion distance was not given\nA default value of 1 is used."
+ Distance = 1.
+
+ if 'Direction' in args : Direction = NormalizeVector([float(Dir) for Dir in args['Direction']],Distance)
+ else :
+ print "\nThe extrusion vector of revolution was not given\nThe z-axis is used by default."
+ Direction = NormalizeVector([0.,0.,1.],Distance)
+
+ if 'Scale' in args : Scale = float(args['Scale'])
+ else : Scale = 1.
+
+ if 'NSteps' in args : NSteps = int(args['NSteps'])
+ else : NSteps = 1
+
+ # Creating the lower face group LOFAC
+ LOFAC = MainMesh.CreateEmptyGroup( SMESH.FACE, 'LOFAC' )
+ LOFAC.AddFrom(MainMesh.GetMesh())
+
+ GR_Names = MainMesh.GetGroupNames()
+ GRs = MainMesh.GetGroups()
+ Ext3DMeshGroups = MainMesh.ExtrusionSweepObject2D(MainMesh,SMESH.DirStruct(SMESH.PointStruct(Direction[0],Direction[1],Direction[2])), NSteps, True)
+
+ # Adding an EDGE suffix to the edge groups (to be deleted eventually by the user...)
+ for GR in GRs:
+ CurrentName = GR.GetName()
+ if CurrentName in GR_Names and not(CurrentName=='LOFAC'): # Meaning that this is an old edge group
+ GR.SetName(CurrentName+'_EDGE')
+
+ # Removing the _extruded suffix from the extruded FACE groups
+ for GR in Ext3DMeshGroups:
+ CurrentName = GR.GetName()
+ if CurrentName.endswith( "_extruded"):
+ if CurrentName.startswith( 'LOFAC_' ):
+ GR.SetName('VOL')
+ else:
+ GR.SetName(CurrentName[:-9])
+ elif CurrentName == 'LOFAC_top':
+ GR.SetName('HIFAC')
+
+ # Creating the upper face group HIFAC
+ ALLFAC = MainMesh.CreateEmptyGroup( SMESH.FACE, 'ALLFAC' )
+ ALLFAC.AddFrom(MainMesh.GetMesh())
+
+ #HIFAC = MainMesh.GetMesh().CutListOfGroups( [ ALLFAC ], [LOFAC] + [ MeshGroup for MeshGroup in Ext3DMeshGroups if not(MeshGroup.GetName()=='VOL') ], 'HIFAC' )
+
+ # Scaling down the mesh to meter units
+ if not(Scale==1.):
+ MeshEditor = MainMesh.GetMeshEditor()
+ MeshEditor.Scale( MainMesh.GetMesh(), SMESH.PointStruct( 0, 0, 0 ) ,[ Scale, Scale, Scale ], 0 )
+
+
def NormalizeVector (V,Norm):
- """
- This function returns a normalized vector (magnitude = Norm), parallel to the entered one
- """
- V = [float(Coor) for Coor in V]
- Norm = float(Norm)
- MagV = math.sqrt(V[0]*V[0]+V[1]*V[1]+V[2]*V[2])
- return [Coor*Norm/MagV for Coor in V]
-
+ """
+ This function returns a normalized vector (magnitude = Norm), parallel to the entered one
+ """
+ V = [float(Coor) for Coor in V]
+ Norm = float(Norm)
+ MagV = math.sqrt(V[0]*V[0]+V[1]*V[1]+V[2]*V[2])
+ return [Coor*Norm/MagV for Coor in V]
# This is an automation of the sharp angle object, with a corner at (X0,Y0), side length : Extension and a fine local meshing : LocalMeshing
# The corner orientation is defined as NE (North-East) , NW (North-West), SE, or SW. The object's "arm" is 8/14 of Extension
-# | | 8 6
-# ------- ---------
-# ----> | | <----
-# | NW NE | oo
-# _____| |_____
+# | | 8 6
+# ------- ---------
+# ----> | | <----
+# | NW NE | oo
+# _____| |_____
import sys, math, commands
CWD = commands.getoutput('pwd')
from CompositeBox import *
import Config, GenFunctions
-def SharpAngleOut (X0 , Y0 , DX , DY , DLocal, LocalMeshing , CornerOrientation , NLevels, **args) :
- if DLocal == 'auto' : DLocal = float(min(DX,DY))
-
- BoxSide = DLocal/(2.**(NLevels+1))
- InternalMeshing = int(math.ceil(BoxSide/(3*LocalMeshing)))
- InternalMeshing = InternalMeshing+InternalMeshing%2 # An even number is needed, otherwise the objects would not be compatible once created
- if InternalMeshing == 0 : InternalMeshing = 2 # This sets a minimum meshing condition in order to avoid an error. The user is notified of the value considered for the local meshing
- print "Possible Local meshing is :", BoxSide/(3*InternalMeshing), "\nThis value is returned by this function for your convenience"
-
- DirPar = {'NE' : lambda : ['NE', 'NW', 'SE', 'EW', 'NW', 'SN', 'SN', 'NE', 'WE', 'WE', 'SE', 'NS'],
- 'NW' : lambda : ['NW', 'NE', 'SW', 'WE', 'NE', 'SN', 'SN', 'NW', 'EW', 'EW', 'SW', 'NS'],
- 'SE' : lambda : ['SE', 'SW', 'NE', 'EW', 'SW', 'NS', 'NS', 'SE', 'WE', 'WE', 'NE', 'SN'],
- 'SW' : lambda : ['SW', 'SE', 'NW', 'WE', 'SE', 'NS', 'NS', 'SW', 'EW', 'EW', 'NW', 'SN'], }[CornerOrientation]()
-
- CoefVer = {'NE' : lambda : 1,
- 'NW' : lambda : 1,
- 'SE' : lambda : -1,
- 'SW' : lambda : -1, }[CornerOrientation]()
-
- CoefHor = {'NE' : lambda : 1,
- 'NW' : lambda : -1,
- 'SE' : lambda : 1,
- 'SW' : lambda : -1, }[CornerOrientation]()
-
- ToLook = {'NE' : lambda : [0,2,1,3],
- 'NW' : lambda : [0,3,1,2],
- 'SE' : lambda : [1,2,0,3],
- 'SW' : lambda : [1,3,0,2], }[CornerOrientation]()
-
- if args.__contains__('groups') :
- GroupNames = args['groups']
- else : GroupNames = [None, None, None, None, None, None]
-
- GN00 = GroupArray(ToLook[0],GroupNames[0])
- GN01 = GroupArray(ToLook[1],GroupNames[1])
-
- GN1 = GroupArray([ToLook[0],ToLook[1]],[GroupNames[0],GroupNames[5]])
- GN7 = GroupArray([ToLook[0],ToLook[1]],[GroupNames[4],GroupNames[1]])
-
- if DY == DLocal :
- GN2 = GroupArray([ToLook[1],ToLook[2]],[GroupNames[5],GroupNames[2]])
- GN3 = GroupArray(ToLook[2],GroupNames[2])
- if DX == DLocal:
- GN4 = GroupArray([ToLook[2],ToLook[3]],[GroupNames[2],GroupNames[3]])
- GN5 = GroupArray(ToLook[3],GroupNames[3])
- GN6 = GroupArray([ToLook[3],ToLook[0]],[GroupNames[3],GroupNames[4]])
- else :
- GN4 = GroupArray(ToLook[2],GroupNames[2])
- GN5 = [None,None,None,None]
- GN6 = GroupArray(ToLook[0],GroupNames[4])
- GN21 = GroupArray([ToLook[3],ToLook[0],ToLook[2]],[GroupNames[3],GroupNames[4],GroupNames[2]])
+def SharpAngleOut (X0 , Y0 , DX , DY , DLocal, LocalMeshing , CornerOrientation , NLevels, **args) :
+ if DLocal == 'auto' : DLocal = float(min(DX,DY))
+
+ BoxSide = DLocal/(2.**(NLevels+1))
+ InternalMeshing = int(math.ceil(BoxSide/(3*LocalMeshing)))
+ InternalMeshing = InternalMeshing+InternalMeshing%2 # An even number is needed, otherwise the objects would not be compatible once created
+ if InternalMeshing == 0 : InternalMeshing = 2 # This sets a minimum meshing condition in order to avoid an error. The user is notified of the value considered for the local meshing
+ print "Possible Local meshing is :", BoxSide/(3*InternalMeshing), "\nThis value is returned by this function for your convenience"
+
+ DirPar = {'NE' : lambda : ['NE', 'NW', 'SE', 'EW', 'NW', 'SN', 'SN', 'NE', 'WE', 'WE', 'SE', 'NS'],
+ 'NW' : lambda : ['NW', 'NE', 'SW', 'WE', 'NE', 'SN', 'SN', 'NW', 'EW', 'EW', 'SW', 'NS'],
+ 'SE' : lambda : ['SE', 'SW', 'NE', 'EW', 'SW', 'NS', 'NS', 'SE', 'WE', 'WE', 'NE', 'SN'],
+ 'SW' : lambda : ['SW', 'SE', 'NW', 'WE', 'SE', 'NS', 'NS', 'SW', 'EW', 'EW', 'NW', 'SN'], }[CornerOrientation]()
+
+ CoefVer = {'NE' : lambda : 1,
+ 'NW' : lambda : 1,
+ 'SE' : lambda : -1,
+ 'SW' : lambda : -1, }[CornerOrientation]()
+
+ CoefHor = {'NE' : lambda : 1,
+ 'NW' : lambda : -1,
+ 'SE' : lambda : 1,
+ 'SW' : lambda : -1, }[CornerOrientation]()
+
+ ToLook = {'NE' : lambda : [0,2,1,3],
+ 'NW' : lambda : [0,3,1,2],
+ 'SE' : lambda : [1,2,0,3],
+ 'SW' : lambda : [1,3,0,2], }[CornerOrientation]()
+
+ if args.__contains__('groups') :
+ GroupNames = args['groups']
+ else : GroupNames = [None, None, None, None, None, None]
+
+ GN00 = GroupArray(ToLook[0],GroupNames[0])
+ GN01 = GroupArray(ToLook[1],GroupNames[1])
+
+ GN1 = GroupArray([ToLook[0],ToLook[1]],[GroupNames[0],GroupNames[5]])
+ GN7 = GroupArray([ToLook[0],ToLook[1]],[GroupNames[4],GroupNames[1]])
+
+ if DY == DLocal :
+ GN2 = GroupArray([ToLook[1],ToLook[2]],[GroupNames[5],GroupNames[2]])
+ GN3 = GroupArray(ToLook[2],GroupNames[2])
+ if DX == DLocal:
+ GN4 = GroupArray([ToLook[2],ToLook[3]],[GroupNames[2],GroupNames[3]])
+ GN5 = GroupArray(ToLook[3],GroupNames[3])
+ GN6 = GroupArray([ToLook[3],ToLook[0]],[GroupNames[3],GroupNames[4]])
else :
- GN2 = GroupArray(ToLook[1],GroupNames[5])
- GN3 = [None,None,None,None]
- if DX == DLocal:
- GN4 = GroupArray(ToLook[3],GroupNames[3])
- GN5 = GroupArray(ToLook[3],GroupNames[3])
- GN6 = GroupArray([ToLook[3],ToLook[0]],[GroupNames[3],GroupNames[4]])
- GN22 = GroupArray([ToLook[1],ToLook[2],ToLook[3]],[GroupNames[5],GroupNames[2],GroupNames[3]])
- else :
- GN4 = [None,None,None,None]
- GN5 = [None,None,None,None]
- GN6 = GroupArray(ToLook[0],GroupNames[4])
- GN21 = GroupArray([ToLook[3],ToLook[0]],[GroupNames[3],GroupNames[4]])
- GN22 = GroupArray([ToLook[1],ToLook[2]],[GroupNames[5],GroupNames[2]])
- GN23 = GroupArray([ToLook[2],ToLook[3]],[GroupNames[2],GroupNames[3]])
-
- Obj = []
-
- Obj.append(MacObject('BoxAng32',[(X0+CoefHor*BoxSide/2,Y0+CoefVer*BoxSide/2),(BoxSide,BoxSide)],[InternalMeshing,DirPar[0]]))
- Obj.append(MacObject('BoxAng32',[(X0-CoefHor*BoxSide/2,Y0+CoefVer*BoxSide/2),(BoxSide,BoxSide)],['auto',DirPar[1]], groups = GroupArray(ToLook[0],GroupNames[0])))
- Obj.append(MacObject('BoxAng32',[(X0+CoefHor*BoxSide/2,Y0-CoefVer*BoxSide/2),(BoxSide,BoxSide)],['auto',DirPar[2]], groups = GroupArray(ToLook[1],GroupNames[1])))
-
- for N in range (1,NLevels+1):
- n = N-1
- if N < NLevels :
- Obj.append(MacObject('Box42',[(X0-CoefHor*BoxSide*(2**n)*3/2,Y0+CoefVer*(2**n)*BoxSide/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[3]] , groups = GN00))
- Obj.append(MacObject('BoxAng32',[(X0-CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[4]] ))
- Obj.append(MacObject('Box42',[(X0-CoefHor*(2**n)*BoxSide/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[5]] ))
- Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[6]] ))
- Obj.append(MacObject('BoxAng32',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[7]] ))
- Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[8]] ))
- Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0-CoefVer*(2**n)*BoxSide/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[9]] ))
- Obj.append(MacObject('BoxAng32',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0-CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[10]] ))
- Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide/2,Y0-CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[11]] , groups = GN01))
- else :
- Obj.append(MacObject('Box42',[(X0-CoefHor*BoxSide*(2**n)*3/2,Y0+CoefVer*(2**n)*BoxSide/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[3]] , groups = GN1))
- Obj.append(MacObject('BoxAng32',[(X0-CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[4]] , groups = GN2))
- Obj.append(MacObject('Box42',[(X0-CoefHor*(2**n)*BoxSide/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[5]] , groups = GN3))
- Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[6]] , groups = GN3))
- Obj.append(MacObject('BoxAng32',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[7]] , groups = GN4))
- Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[8]] , groups = GN5))
- Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0-CoefVer*(2**n)*BoxSide/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[9]] , groups = GN5))
- Obj.append(MacObject('BoxAng32',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0-CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[10]], groups = GN6))
- Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide/2,Y0-CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[11]] , groups = GN7))
-
- OuterMeshing = (3/2)*InternalMeshing*2**(NLevels-1)
- OuterSegLength = (DLocal/OuterMeshing)
-
- if DX > DLocal :
- dX = DX - DLocal
- Obj.append(MacObject('CompBoxF',[(X0+CoefHor*(DX)/2.,Y0),(dX,DLocal)],['auto'], groups = GN21))
- if DY > DLocal :
- dY = DY - DLocal
- if DX > DLocal :
- Obj.append(MacObject('CompBoxF',[(X0+CoefHor*DX/2.,Y0+CoefVer*(DY)/2.),(DX-DLocal,dY)],['auto'], groups = GN23))
-
- Obj.append(MacObject('CompBoxF',[(X0,Y0+CoefVer*(DY)/2.),(DLocal,dY)],['auto'], groups = GN22))
-
- return Obj
-
-def SharpAngleIn (X0 , Y0 , DX , DY , DLocal, LocalMeshing , CornerOrientation , NLevels, **args) :
- if DLocal == 'auto' : DLocal = float(min(DX,DY))
-
- BoxSide = DLocal/(2.**(NLevels))
- InternalMeshing = int(math.ceil(BoxSide/(3*LocalMeshing)))
- InternalMeshing = InternalMeshing+InternalMeshing%2 # An even number is needed, otherwise the objects would not be compatible once created
- if InternalMeshing == 0 : InternalMeshing = 2 # This sets a minimum meshing condition in order to avoid an error. The user is notified of the value considered for the local meshing
- print "Possible Local meshing is :", BoxSide/(3*InternalMeshing), "\nThis value is returned by this function for your convenience..."
-
- DirPar = {'NE' : lambda : ['NE', 'SN', 'NE', 'WE'],
- 'NW' : lambda : ['NW', 'SN', 'NW', 'EW'],
- 'SE' : lambda : ['SE', 'NS', 'SE', 'WE'],
- 'SW' : lambda : ['SW', 'NS', 'SW', 'EW'], }[CornerOrientation]()
-
- CoefVer = {'NE' : lambda : 1,
- 'NW' : lambda : 1,
- 'SE' : lambda : -1,
- 'SW' : lambda : -1, }[CornerOrientation]()
-
- CoefHor = {'NE' : lambda : 1,
- 'NW' : lambda : -1,
- 'SE' : lambda : 1,
- 'SW' : lambda : -1, }[CornerOrientation]()
-
- ToLook = {'NE' : lambda : [0,2,1,3],
- 'NW' : lambda : [0,3,1,2],
- 'SE' : lambda : [1,2,0,3],
- 'SW' : lambda : [1,3,0,2], }[CornerOrientation]()
-
- if args.__contains__('groups') :
- GroupNames = args['groups']
- else : GroupNames = [None, None, None, None]
-
- GN01 = GroupArray([ToLook[0],ToLook[1]],[GroupNames[ToLook[0]],GroupNames[ToLook[1]]])
- GN02 = GroupArray(ToLook[1],GroupNames[ToLook[1]])
- GN03 = [None, None, None, None]
- GN04 = GroupArray(ToLook[0],GroupNames[ToLook[0]])
-
- if DY == DLocal :
- GN05 = GroupArray([ToLook[1],ToLook[2]],[GroupNames[ToLook[1]],GroupNames[ToLook[2]]])
- GN08 = GroupArray([ToLook[0],ToLook[2],ToLook[3]],[GroupNames[ToLook[0]],GroupNames[ToLook[2]],GroupNames[ToLook[3]]])
- if DX == DLocal:
- GN06 = GroupArray([ToLook[2],ToLook[3]],[GroupNames[ToLook[2]],GroupNames[ToLook[3]]])
- GN07 = GroupArray([ToLook[0],ToLook[3]],[GroupNames[ToLook[0]],GroupNames[ToLook[3]]])
- else :
- GN06 = GroupArray(ToLook[2],GroupNames[ToLook[2]])
- GN07 = GroupArray(ToLook[0],GroupNames[ToLook[0]])
+ GN4 = GroupArray(ToLook[2],GroupNames[2])
+ GN5 = [None,None,None,None]
+ GN6 = GroupArray(ToLook[0],GroupNames[4])
+ GN21 = GroupArray([ToLook[3],ToLook[0],ToLook[2]],[GroupNames[3],GroupNames[4],GroupNames[2]])
+ else :
+ GN2 = GroupArray(ToLook[1],GroupNames[5])
+ GN3 = [None,None,None,None]
+ if DX == DLocal:
+ GN4 = GroupArray(ToLook[3],GroupNames[3])
+ GN5 = GroupArray(ToLook[3],GroupNames[3])
+ GN6 = GroupArray([ToLook[3],ToLook[0]],[GroupNames[3],GroupNames[4]])
+ GN22 = GroupArray([ToLook[1],ToLook[2],ToLook[3]],[GroupNames[5],GroupNames[2],GroupNames[3]])
else :
- GN05 = GroupArray(ToLook[1],GroupNames[ToLook[1]])
- if DX == DLocal :
- GN06 = GroupArray(ToLook[3],GroupNames[ToLook[3]])
- GN07 = GroupArray([ToLook[0],ToLook[3]],[GroupNames[ToLook[0]],GroupNames[ToLook[3]]])
- GN10 = GroupArray([ToLook[1],ToLook[2],ToLook[3]],[GroupNames[ToLook[1]],GroupNames[ToLook[2]],GroupNames[ToLook[3]]])
- else :
- GN06 = [None, None, None, None]
- GN07 = GroupArray(ToLook[0],GroupNames[ToLook[0]])
- GN08 = GroupArray([ToLook[0],ToLook[3]],[GroupNames[ToLook[0]],GroupNames[ToLook[3]]])
- GN09 = GroupArray([ToLook[2],ToLook[3]],[GroupNames[ToLook[2]],GroupNames[ToLook[3]]])
- GN10 = GroupArray([ToLook[1],ToLook[2]],[GroupNames[ToLook[1]],GroupNames[ToLook[2]]])
-
- Obj = []
-
- Obj.append(MacObject('BoxAng32',[(X0+CoefHor*BoxSide/2,Y0+CoefVer*BoxSide/2),(BoxSide,BoxSide)],[InternalMeshing,DirPar[0]],groups = GN01))
-
- for N in range (1,NLevels+1):
- n = N-1
- if N < NLevels :
- Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[1]],groups = GN02))
- Obj.append(MacObject('BoxAng32',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[2]],groups = GN03))
- Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[3]],groups = GN04))
- else :
- Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[1]],groups = GN05))
- Obj.append(MacObject('BoxAng32',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[2]],groups = GN06))
- Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[3]],groups = GN07))
-
- OuterMeshing = (3/2)*InternalMeshing*2**(NLevels-1)
- OuterSegLength = (DLocal/OuterMeshing)
-
- if DX > DLocal :
- dX = DX - DLocal
- Obj = Obj + CompositeBox(X0+CoefHor*(DLocal+dX/2.),Y0+CoefVer*(DLocal)/2.,dX,DLocal, groups = GN08)
- if DY > DLocal :
- dY = DY - DLocal
-
- if DX > DLocal :
- Obj = Obj + CompositeBox(X0+CoefHor*(DLocal+(DX-DLocal)/2.),Y0+CoefVer*(DLocal+dY/2.),DX-DLocal,dY, groups = GN09)
-
- Obj = Obj + CompositeBox(X0+CoefHor*DLocal/2,Y0+CoefVer*(DLocal+dY/2.),DLocal,dY,groups = GN10)
-
- return Obj
+ GN4 = [None,None,None,None]
+ GN5 = [None,None,None,None]
+ GN6 = GroupArray(ToLook[0],GroupNames[4])
+ GN21 = GroupArray([ToLook[3],ToLook[0]],[GroupNames[3],GroupNames[4]])
+ GN22 = GroupArray([ToLook[1],ToLook[2]],[GroupNames[5],GroupNames[2]])
+ GN23 = GroupArray([ToLook[2],ToLook[3]],[GroupNames[2],GroupNames[3]])
+
+ Obj = []
+
+ Obj.append(MacObject('BoxAng32',[(X0+CoefHor*BoxSide/2,Y0+CoefVer*BoxSide/2),(BoxSide,BoxSide)],[InternalMeshing,DirPar[0]]))
+ Obj.append(MacObject('BoxAng32',[(X0-CoefHor*BoxSide/2,Y0+CoefVer*BoxSide/2),(BoxSide,BoxSide)],['auto',DirPar[1]], groups = GroupArray(ToLook[0],GroupNames[0])))
+ Obj.append(MacObject('BoxAng32',[(X0+CoefHor*BoxSide/2,Y0-CoefVer*BoxSide/2),(BoxSide,BoxSide)],['auto',DirPar[2]], groups = GroupArray(ToLook[1],GroupNames[1])))
+
+ for N in range (1,NLevels+1):
+ n = N-1
+ if N < NLevels :
+ Obj.append(MacObject('Box42',[(X0-CoefHor*BoxSide*(2**n)*3/2,Y0+CoefVer*(2**n)*BoxSide/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[3]] , groups = GN00))
+ Obj.append(MacObject('BoxAng32',[(X0-CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[4]] ))
+ Obj.append(MacObject('Box42',[(X0-CoefHor*(2**n)*BoxSide/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[5]] ))
+ Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[6]] ))
+ Obj.append(MacObject('BoxAng32',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[7]] ))
+ Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[8]] ))
+ Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0-CoefVer*(2**n)*BoxSide/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[9]] ))
+ Obj.append(MacObject('BoxAng32',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0-CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[10]] ))
+ Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide/2,Y0-CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[11]] , groups = GN01))
+ else :
+ Obj.append(MacObject('Box42',[(X0-CoefHor*BoxSide*(2**n)*3/2,Y0+CoefVer*(2**n)*BoxSide/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[3]] , groups = GN1))
+ Obj.append(MacObject('BoxAng32',[(X0-CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[4]] , groups = GN2))
+ Obj.append(MacObject('Box42',[(X0-CoefHor*(2**n)*BoxSide/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[5]] , groups = GN3))
+ Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[6]] , groups = GN3))
+ Obj.append(MacObject('BoxAng32',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[7]] , groups = GN4))
+ Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[8]] , groups = GN5))
+ Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0-CoefVer*(2**n)*BoxSide/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[9]] , groups = GN5))
+ Obj.append(MacObject('BoxAng32',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0-CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[10]], groups = GN6))
+ Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide/2,Y0-CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[11]] , groups = GN7))
+
+ OuterMeshing = (3/2)*InternalMeshing*2**(NLevels-1)
+ OuterSegLength = (DLocal/OuterMeshing)
+
+ if DX > DLocal :
+ dX = DX - DLocal
+ Obj.append(MacObject('CompBoxF',[(X0+CoefHor*(DX)/2.,Y0),(dX,DLocal)],['auto'], groups = GN21))
+ if DY > DLocal :
+ dY = DY - DLocal
+ if DX > DLocal :
+ Obj.append(MacObject('CompBoxF',[(X0+CoefHor*DX/2.,Y0+CoefVer*(DY)/2.),(DX-DLocal,dY)],['auto'], groups = GN23))
+
+ Obj.append(MacObject('CompBoxF',[(X0,Y0+CoefVer*(DY)/2.),(DLocal,dY)],['auto'], groups = GN22))
+
+ return Obj
+
+def SharpAngleIn (X0 , Y0 , DX , DY , DLocal, LocalMeshing , CornerOrientation , NLevels, **args) :
+ if DLocal == 'auto' : DLocal = float(min(DX,DY))
+
+ BoxSide = DLocal/(2.**(NLevels))
+ InternalMeshing = int(math.ceil(BoxSide/(3*LocalMeshing)))
+ InternalMeshing = InternalMeshing+InternalMeshing%2 # An even number is needed, otherwise the objects would not be compatible once created
+ if InternalMeshing == 0 : InternalMeshing = 2 # This sets a minimum meshing condition in order to avoid an error. The user is notified of the value considered for the local meshing
+ print "Possible Local meshing is :", BoxSide/(3*InternalMeshing), "\nThis value is returned by this function for your convenience..."
+
+ DirPar = {'NE' : lambda : ['NE', 'SN', 'NE', 'WE'],
+ 'NW' : lambda : ['NW', 'SN', 'NW', 'EW'],
+ 'SE' : lambda : ['SE', 'NS', 'SE', 'WE'],
+ 'SW' : lambda : ['SW', 'NS', 'SW', 'EW'], }[CornerOrientation]()
+
+ CoefVer = {'NE' : lambda : 1,
+ 'NW' : lambda : 1,
+ 'SE' : lambda : -1,
+ 'SW' : lambda : -1, }[CornerOrientation]()
+
+ CoefHor = {'NE' : lambda : 1,
+ 'NW' : lambda : -1,
+ 'SE' : lambda : 1,
+ 'SW' : lambda : -1, }[CornerOrientation]()
+
+ ToLook = {'NE' : lambda : [0,2,1,3],
+ 'NW' : lambda : [0,3,1,2],
+ 'SE' : lambda : [1,2,0,3],
+ 'SW' : lambda : [1,3,0,2], }[CornerOrientation]()
+
+ if args.__contains__('groups') :
+ GroupNames = args['groups']
+ else : GroupNames = [None, None, None, None]
+
+ GN01 = GroupArray([ToLook[0],ToLook[1]],[GroupNames[ToLook[0]],GroupNames[ToLook[1]]])
+ GN02 = GroupArray(ToLook[1],GroupNames[ToLook[1]])
+ GN03 = [None, None, None, None]
+ GN04 = GroupArray(ToLook[0],GroupNames[ToLook[0]])
+
+ if DY == DLocal :
+ GN05 = GroupArray([ToLook[1],ToLook[2]],[GroupNames[ToLook[1]],GroupNames[ToLook[2]]])
+ GN08 = GroupArray([ToLook[0],ToLook[2],ToLook[3]],[GroupNames[ToLook[0]],GroupNames[ToLook[2]],GroupNames[ToLook[3]]])
+ if DX == DLocal:
+ GN06 = GroupArray([ToLook[2],ToLook[3]],[GroupNames[ToLook[2]],GroupNames[ToLook[3]]])
+ GN07 = GroupArray([ToLook[0],ToLook[3]],[GroupNames[ToLook[0]],GroupNames[ToLook[3]]])
+ else :
+ GN06 = GroupArray(ToLook[2],GroupNames[ToLook[2]])
+ GN07 = GroupArray(ToLook[0],GroupNames[ToLook[0]])
+ else :
+ GN05 = GroupArray(ToLook[1],GroupNames[ToLook[1]])
+ if DX == DLocal :
+ GN06 = GroupArray(ToLook[3],GroupNames[ToLook[3]])
+ GN07 = GroupArray([ToLook[0],ToLook[3]],[GroupNames[ToLook[0]],GroupNames[ToLook[3]]])
+ GN10 = GroupArray([ToLook[1],ToLook[2],ToLook[3]],[GroupNames[ToLook[1]],GroupNames[ToLook[2]],GroupNames[ToLook[3]]])
+ else :
+ GN06 = [None, None, None, None]
+ GN07 = GroupArray(ToLook[0],GroupNames[ToLook[0]])
+ GN08 = GroupArray([ToLook[0],ToLook[3]],[GroupNames[ToLook[0]],GroupNames[ToLook[3]]])
+ GN09 = GroupArray([ToLook[2],ToLook[3]],[GroupNames[ToLook[2]],GroupNames[ToLook[3]]])
+ GN10 = GroupArray([ToLook[1],ToLook[2]],[GroupNames[ToLook[1]],GroupNames[ToLook[2]]])
+
+ Obj = []
+
+ Obj.append(MacObject('BoxAng32',[(X0+CoefHor*BoxSide/2,Y0+CoefVer*BoxSide/2),(BoxSide,BoxSide)],[InternalMeshing,DirPar[0]],groups = GN01))
+
+ for N in range (1,NLevels+1):
+ n = N-1
+ if N < NLevels :
+ Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[1]],groups = GN02))
+ Obj.append(MacObject('BoxAng32',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[2]],groups = GN03))
+ Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[3]],groups = GN04))
+ else :
+ Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[1]],groups = GN05))
+ Obj.append(MacObject('BoxAng32',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide*3/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[2]],groups = GN06))
+ Obj.append(MacObject('Box42',[(X0+CoefHor*(2**n)*BoxSide*3/2,Y0+CoefVer*(2**n)*BoxSide/2),((2**n)*BoxSide,(2**n)*BoxSide)],['auto',DirPar[3]],groups = GN07))
+
+ OuterMeshing = (3/2)*InternalMeshing*2**(NLevels-1)
+ OuterSegLength = (DLocal/OuterMeshing)
+
+ if DX > DLocal :
+ dX = DX - DLocal
+ Obj = Obj + CompositeBox(X0+CoefHor*(DLocal+dX/2.),Y0+CoefVer*(DLocal)/2.,dX,DLocal, groups = GN08)
+ if DY > DLocal :
+ dY = DY - DLocal
+
+ if DX > DLocal :
+ Obj = Obj + CompositeBox(X0+CoefHor*(DLocal+(DX-DLocal)/2.),Y0+CoefVer*(DLocal+dY/2.),DX-DLocal,dY, groups = GN09)
+
+ Obj = Obj + CompositeBox(X0+CoefHor*DLocal/2,Y0+CoefVer*(DLocal+dY/2.),DLocal,dY,groups = GN10)
+
+ return Obj
def GroupArray(indices, GroupNames) :
- if type(indices) is int :
- indices = [indices]
- GroupNames = [GroupNames]
- Output = [None,None,None,None]
- for i, ind in enumerate(indices) :
- Output[ind] = GroupNames[i]
- return Output
+ if type(indices) is int :
+ indices = [indices]
+ GroupNames = [GroupNames]
+ Output = [None,None,None,None]
+ for i, ind in enumerate(indices) :
+ Output[ind] = GroupNames[i]
+ return Output
if __name__ == "__main__":
- from optparse import OptionParser
- p=OptionParser()
- p.add_option('-p',dest='partiel',action="store_true", default=False,help='import de machine, groupe, ratio Maille et Perf uniquement')
- p.add_option('-f',dest='force',action="store_true", default=False,help='ecrasement des valeurs dans la base par les valeurs dans les fichiers en cas de meme clef primaire')
- p.add_option('-d',dest='database',default="myMesh.db",help='nom de la database')
- options, args = p.parse_args()
- if len(args) != 1 :
- print "entrer SVP le nom de la directory ou sont rangees les fichiers a charger"
- exit()
- folder=args[0]
+ from optparse import OptionParser
+ p=OptionParser()
+ p.add_option('-p',dest='partiel',action="store_true", default=False,help='import de machine, groupe, ratio Maille et Perf uniquement')
+ p.add_option('-f',dest='force',action="store_true", default=False,help='ecrasement des valeurs dans la base par les valeurs dans les fichiers en cas de meme clef primaire')
+ p.add_option('-d',dest='database',default="myMesh.db",help='nom de la database')
+ options, args = p.parse_args()
+ if len(args) != 1 :
+ print "entrer SVP le nom de la directory ou sont rangees les fichiers a charger"
+ exit()
+ folder=args[0]
- if not(os.path.isdir(folder)):
- print folder , " n existe pas"
- exit()
-
- maBase=Base(options.database)
- maBase.create()
- maBase.initialise()
- maBase.importFromCSV(folder,options.partiel,options.force)
- maBase.close()
+ if not(os.path.isdir(folder)):
+ print folder , " n existe pas"
+ exit()
+ maBase=Base(options.database)
+ maBase.create()
+ maBase.initialise()
+ maBase.importFromCSV(folder,options.partiel,options.force)
+ maBase.close()
import datetime
class TableDeBase :
- def __init__(self,nom):
- self.nom=nom
-
- def setField(self,FieldStringList):
- self.FieldStringList=FieldStringList
- self.idName=FieldStringList[0]
-
- def setTypeField(self,FieldTypeListe,clef):
- self.FieldTypeListe = FieldTypeListe
- self.clef=clef
-
- def getFields(self):
- return self.FieldStringList
-
- def insereLigne(self,valeurs,debug=False):
- if self.verifieExitenceId(valeurs[0])!=0 :
- print "impossible d inserer " , valeurs, "dans ", self.nom
- print "l id est deja existant"
- return False
- texteQuery='insert into ' + self.nom + " values "+ str(valeurs)+ ';'
- maQuery=QSqlQuery()
- if debug : print texteQuery, " " , maQuery.exec_(texteQuery)
- else : maQuery.exec_(texteQuery)
-
- def insereLigneAutoId(self,valeurs,debug=False):
- texteQuery='insert into ' + self.nom + self.cols+ " values "+ str(valeurs)+ ';'
- maQuery=QSqlQuery()
- if debug : print texteQuery, " " , maQuery.exec_(texteQuery)
- else : maQuery.exec_(texteQuery)
-
- def insereOuRemplaceLigne(self,valeurs,debug=False):
- texteQuery='insert or replace into ' + self.nom + " values "+ str(valeurs)+ ';'
- maQuery=QSqlQuery()
- if debug : print texteQuery, " " , maQuery.exec_(texteQuery)
- else : maQuery.exec_(texteQuery)
-
-
- def verifieExitenceId(self,valeur):
+ def __init__(self,nom):
+ self.nom=nom
+
+ def setField(self,FieldStringList):
+ self.FieldStringList=FieldStringList
+ self.idName=FieldStringList[0]
+
+ def setTypeField(self,FieldTypeListe,clef):
+ self.FieldTypeListe = FieldTypeListe
+ self.clef=clef
+
+ def getFields(self):
+ return self.FieldStringList
+
+ def insereLigne(self,valeurs,debug=False):
+ if self.verifieExitenceId(valeurs[0])!=0 :
+ print "impossible d inserer " , valeurs, "dans ", self.nom
+ print "l id est deja existant"
+ return False
+ texteQuery='insert into ' + self.nom + " values "+ str(valeurs)+ ';'
+ maQuery=QSqlQuery()
+ if debug : print texteQuery, " " , maQuery.exec_(texteQuery)
+ else : maQuery.exec_(texteQuery)
+
+ def insereLigneAutoId(self,valeurs,debug=False):
+ texteQuery='insert into ' + self.nom + self.cols+ " values "+ str(valeurs)+ ';'
+ maQuery=QSqlQuery()
+ if debug : print texteQuery, " " , maQuery.exec_(texteQuery)
+ else : maQuery.exec_(texteQuery)
+
+ def insereOuRemplaceLigne(self,valeurs,debug=False):
+ texteQuery='insert or replace into ' + self.nom + " values "+ str(valeurs)+ ';'
+ maQuery=QSqlQuery()
+ if debug : print texteQuery, " " , maQuery.exec_(texteQuery)
+ else : maQuery.exec_(texteQuery)
+
+
+ def verifieExitenceId(self,valeur):
# ne fonctionne pas correctement, il faudrait se servir de la clef
- texteQuery= "select * from " + self.nom + " where "+ self.idName+'='+str(valeur) +';'
- maQuery=QSqlQuery()
- maQuery.exec_(texteQuery)
- nb=0
- while(maQuery.next()): nb=nb+1
- return nb
+ texteQuery= "select * from " + self.nom + " where "+ self.idName+'='+str(valeur) +';'
+ maQuery=QSqlQuery()
+ maQuery.exec_(texteQuery)
+ nb=0
+ while(maQuery.next()): nb=nb+1
+ return nb
- def remplit(self):
- print "Pas de remplissage sauf si cette methode est surchargee"
+ def remplit(self):
+ print "Pas de remplissage sauf si cette methode est surchargee"
- def createSqlTable(self):
- print "Pas de creation par defaut : cette methode doit etre surchargee"
+ def createSqlTable(self):
+ print "Pas de creation par defaut : cette methode doit etre surchargee"
# On ne se sert pas du csv python entre autre parcequ'il ne gere pas les entetes
- def exportToCSV(self):
- aujourdhui=datetime.date.today()
- monFolder="ExportDB"+str(aujourdhui)
- monFichier=monFolder+"/Sauve_"+str(self.nom)+'.csv'
- texteQuery= "select * from " + self.nom +';'
- texteSauve=""
- for col in self.FieldStringList:
- texteSauve+=col+";"
- texteSauve=texteSauve[0:-1] # on enleve le dernier ";"
- texteSauve+="\n"
-
- maQuery=QSqlQuery()
- maQuery.exec_(texteQuery)
- asauver=0
- while(maQuery.next()):
- asauver=1
- for i in range(len(self.FieldStringList)):
- texteSauve+=str(maQuery.value(i).toString())+";"
- texteSauve=texteSauve[0:-1] # on enleve le dernier ";"
- texteSauve+="\n"
-
- if asauver == 0 :
- print "pas de sauvegarde de : " , self.nom , " table vide"
- return
-
- from Stats.utiles import writeFile
- Bok=writeFile(monFichier,texteSauve)
- if Bok :
- print "sauvegarde de : " , self.nom , " effectuee "
- else :
- print "pas de sauvegarde de : " , self.nom , " IOerror"
-
- def importFromCSV(self,folder,force):
- monFichier=folder+"/Sauve_"+str(self.nom)+'.csv'
- try :
- f=open(monFichier,'r')
- except:
- print "Pas de chargement de la table ", self.nom
- print "Impossible d'ouvrir le fichier ", monFichier
- return 0
- lignes=f.readlines()
- enTete=tuple(lignes[0][0:-1].split(";"))
- if enTete!=self.FieldStringList:
- print "Pas de chargement de la table ", self.nom
- print "les entetes ne correspondent pas"
- return 0
- for StrVal in lignes[1:]:
- listeVal=tuple(StrVal[0:-1].split(";"))
- listeValTypee=[]
- for i in range(len(listeVal)):
- if self.FieldTypeListe[i]=='int' : listeValTypee.append(int(listeVal[i]))
- if self.FieldTypeListe[i]=='float': listeValTypee.append(float(listeVal[i]))
- if self.FieldTypeListe[i]=='str' : listeValTypee.append(listeVal[i])
- if force==1 : self.insereOuRemplaceLigne(tuple(listeValTypee))
- if force==0 : self.insereLigne(tuple(listeValTypee))
-
-
+ def exportToCSV(self):
+ aujourdhui=datetime.date.today()
+ monFolder="ExportDB"+str(aujourdhui)
+ monFichier=monFolder+"/Sauve_"+str(self.nom)+'.csv'
+ texteQuery= "select * from " + self.nom +';'
+ texteSauve=""
+ for col in self.FieldStringList:
+ texteSauve+=col+";"
+ texteSauve=texteSauve[0:-1] # on enleve le dernier ";"
+ texteSauve+="\n"
+
+ maQuery=QSqlQuery()
+ maQuery.exec_(texteQuery)
+ asauver=0
+ while(maQuery.next()):
+ asauver=1
+ for i in range(len(self.FieldStringList)):
+ texteSauve+=str(maQuery.value(i).toString())+";"
+ texteSauve=texteSauve[0:-1] # on enleve le dernier ";"
+ texteSauve+="\n"
+
+ if asauver == 0 :
+ print "pas de sauvegarde de : " , self.nom , " table vide"
+ return
+
+ from Stats.utiles import writeFile
+ Bok=writeFile(monFichier,texteSauve)
+ if Bok :
+ print "sauvegarde de : " , self.nom , " effectuee "
+ else :
+ print "pas de sauvegarde de : " , self.nom , " IOerror"
+
+ def importFromCSV(self,folder,force):
+ monFichier=folder+"/Sauve_"+str(self.nom)+'.csv'
+ try :
+ f=open(monFichier,'r')
+ except:
+ print "Pas de chargement de la table ", self.nom
+ print "Impossible d'ouvrir le fichier ", monFichier
+ return 0
+ lignes=f.readlines()
+ enTete=tuple(lignes[0][0:-1].split(";"))
+ if enTete!=self.FieldStringList:
+ print "Pas de chargement de la table ", self.nom
+ print "les entetes ne correspondent pas"
+ return 0
+ for StrVal in lignes[1:]:
+ listeVal=tuple(StrVal[0:-1].split(";"))
+ listeValTypee=[]
+ for i in range(len(listeVal)):
+ if self.FieldTypeListe[i]=='int' : listeValTypee.append(int(listeVal[i]))
+ if self.FieldTypeListe[i]=='float': listeValTypee.append(float(listeVal[i]))
+ if self.FieldTypeListe[i]=='str' : listeValTypee.append(listeVal[i])
+ if force==1 : self.insereOuRemplaceLigne(tuple(listeValTypee))
+ if force==0 : self.insereLigne(tuple(listeValTypee))
from tableDeBase import TableDeBase
class TableGroupesRef (TableDeBase):
- def __init__(self):
- TableDeBase.__init__(self,"GroupesRef")
- self.setField(("nomGroupe","idMaillage"))
- self.setTypeField(('str','int'),('nomGroupe'))
+ def __init__(self):
+ TableDeBase.__init__(self,"GroupesRef")
+ self.setField(("nomGroupe","idMaillage"))
+ self.setTypeField(('str','int'),('nomGroupe'))
- def createSqlTable(self):
- query=QSqlQuery()
- texteQuery ="create table GroupesRef(nomGroupe varchar(40), idMaillage int,"
- texteQuery+="foreign key (idMaillage) references Maillages(idMaillage),"
- texteQuery+="primary key (nomGroupe,idMaillage));"
- print "Creation de TableGroupesRef : " , query.exec_(texteQuery)
+ def createSqlTable(self):
+ query=QSqlQuery()
+ texteQuery ="create table GroupesRef(nomGroupe varchar(40), idMaillage int,"
+ texteQuery+="foreign key (idMaillage) references Maillages(idMaillage),"
+ texteQuery+="primary key (nomGroupe,idMaillage));"
+ print "Creation de TableGroupesRef : " , query.exec_(texteQuery)
- def getVals(self,idMaillage):
- query=QSqlQuery()
- texteQuery ='select NomGroupe from GroupesRef where idMaillage='+str(idMaillage) +";"
- listeGroupes=[]
- query.exec_(texteQuery)
- while (query.next()) :
- listeGroupes.append(str(query.value(0).toString()))
- return listeGroupes
+ def getVals(self,idMaillage):
+ query=QSqlQuery()
+ texteQuery ='select NomGroupe from GroupesRef where idMaillage='+str(idMaillage) +";"
+ listeGroupes=[]
+ query.exec_(texteQuery)
+ while (query.next()) :
+ listeGroupes.append(str(query.value(0).toString()))
+ return listeGroupes
# def remplit(self):
-
+
# Groupe pour le script du tunnel (fiche 7566)
# self.insereLigne(('FRONT_07',1))
# self.insereLigne(('FOND_07',1))
import os
class TableMachines (TableDeBase):
- def __init__(self):
- TableDeBase.__init__(self,"Machines")
- self.setField(("nomMachine","Os"))
- self.setTypeField(('str','str'),('nomMachine'))
+ def __init__(self):
+ TableDeBase.__init__(self,"Machines")
+ self.setField(("nomMachine","Os"))
+ self.setTypeField(('str','str'),('nomMachine'))
- def createSqlTable(self):
- query=QSqlQuery()
- print "creation de TableMachine : ", query.exec_("create table Machines( nomMachine varchar(10) primary key, os varchar(10));")
+ def createSqlTable(self):
+ query=QSqlQuery()
+ print "creation de TableMachine : ", query.exec_("create table Machines( nomMachine varchar(10) primary key, os varchar(10));")
- def creeMachine(self):
- nomMachine=os.uname()[1]
- nomOs=os.uname()[2]
- self.insereLigne((nomMachine,nomOs))
-
- def chercheMachine(self):
- query=QSqlQuery()
- machine=os.uname()[1]
- texteQuery ="select nomMachine from Machines where nomMachine ='" + machine +"' ;"
- query.exec_(texteQuery)
- nb=0
- while(query.next()):
- nb=nb+1
- nom=str(query.value(0).toString())
- if nb != 1 : return 0, ""
- return 1, nom
+ def creeMachine(self):
+ nomMachine=os.uname()[1]
+ nomOs=os.uname()[2]
+ self.insereLigne((nomMachine,nomOs))
+ def chercheMachine(self):
+ query=QSqlQuery()
+ machine=os.uname()[1]
+ texteQuery ="select nomMachine from Machines where nomMachine ='" + machine +"' ;"
+ query.exec_(texteQuery)
+ nb=0
+ while(query.next()):
+ nb=nb+1
+ nom=str(query.value(0).toString())
+ if nb != 1 : return 0, ""
+ return 1, nom
from tableDeBase import TableDeBase
class TableMaillages (TableDeBase):
- def __init__(self):
- TableDeBase.__init__(self,"Maillages")
- self.setField(("id","nomMaillage","Script","fichier","idMailleur","Dimension","Seuil CPU","Seuil Ratio","Seuil Taille","Seuil Nb Maille","Commentaire"))
- self.cols="(nomMaillage,nomScript,medResultat,idMailleur,dimension,seuilCPU,seuilRatio,seuilTaille,seuilNbMaille,commentaire)"
- self.setTypeField(('int','str','str','str','int','int','int','int','int','int','str'),('id'))
+ def __init__(self):
+ TableDeBase.__init__(self,"Maillages")
+ self.setField(("id","nomMaillage","Script","fichier","idMailleur","Dimension","Seuil CPU","Seuil Ratio","Seuil Taille","Seuil Nb Maille","Commentaire"))
+ self.cols="(nomMaillage,nomScript,medResultat,idMailleur,dimension,seuilCPU,seuilRatio,seuilTaille,seuilNbMaille,commentaire)"
+ self.setTypeField(('int','str','str','str','int','int','int','int','int','int','str'),('id'))
- def createSqlTable(self):
- query=QSqlQuery()
- texteQuery ="create table Maillages(id integer primary key autoincrement, nomMaillage varchar(10), "
- texteQuery+="nomScript varchar(40), medResultat varchar(15), idMailleur int, dimension int,"
- texteQuery+="seuilCPU int, seuilRatio int, seuilTaille int, seuilNbMaille int, commentaire varchar(60), "
- texteQuery+="foreign key (idMailleur) references Mailleur(id));"
- print "creation de TableMaillages : " , query.exec_(texteQuery)
+ def createSqlTable(self):
+ query=QSqlQuery()
+ texteQuery ="create table Maillages(id integer primary key autoincrement, nomMaillage varchar(10), "
+ texteQuery+="nomScript varchar(40), medResultat varchar(15), idMailleur int, dimension int,"
+ texteQuery+="seuilCPU int, seuilRatio int, seuilTaille int, seuilNbMaille int, commentaire varchar(60), "
+ texteQuery+="foreign key (idMailleur) references Mailleur(id));"
+ print "creation de TableMaillages : " , query.exec_(texteQuery)
- def getVal(self,idMaillage, nomChamp):
- query=QSqlQuery()
- valeur=None
- texteQuery ='select '+ nomChamp + ' from Maillages where id=' + str(idMaillage) + ";"
- query.exec_(texteQuery)
- while (query.next()) :
- valeur=query.value(0).toInt()[0]
- while (query.next()) :
- print "plusieurs enregistrements dans Maillages pour ",str(idMaillage)
- exit()
- return valeur
+ def getVal(self,idMaillage, nomChamp):
+ query=QSqlQuery()
+ valeur=None
+ texteQuery ='select '+ nomChamp + ' from Maillages where id=' + str(idMaillage) + ";"
+ query.exec_(texteQuery)
+ while (query.next()) :
+ valeur=query.value(0).toInt()[0]
+ while (query.next()) :
+ print "plusieurs enregistrements dans Maillages pour ",str(idMaillage)
+ exit()
+ return valeur
- def dejaRemplie(self):
- texteQuery="select * from Maillages where medResultat='/tmp/tetra.med';"
- maQuery=QSqlQuery()
- maQuery.exec_(texteQuery)
- nb=0
- while(maQuery.next()): nb=nb+1
- return nb
+ def dejaRemplie(self):
+ texteQuery="select * from Maillages where medResultat='/tmp/tetra.med';"
+ maQuery=QSqlQuery()
+ maQuery.exec_(texteQuery)
+ nb=0
+ while(maQuery.next()): nb=nb+1
+ return nb
- def remplit(self):
- if self.dejaRemplie():
- print "table Maillage deja initialisee"
- return
+ def remplit(self):
+ if self.dejaRemplie():
+ print "table Maillage deja initialisee"
+ return
# self.insereLigneAutoId(('Fiche_7566_TUNNEL', '/home/H77945/CAS_TEST/MAILLEUR/FICHE_7566_TUNNEL/Fiche_7566_TUNNEL.py', '/tmp/Fiche_7566_TUNNEL.med', 3,3,10,10,10,10, 'Maillage d un tunnel'))
# self.insereLigneAutoId(('Fiche_7957_AILETTE', '/home/H77945/CAS_TEST/MAILLEUR/FICHE_7957_AILETTE/Fiche_7957_AILETTE.py', '/tmp/Fiche_7957_AILETTE.med', 1,2,10,10,10,10, 'Maillage d une attache d aillette'))
-
- def construitListeMaillages(self):
- maQuery=QSqlQuery()
- texteQuery="select id, nomScript,medResultat from Maillages;"
- maQuery.exec_(texteQuery)
- listeMaillages=[]
- while(maQuery.next()):
- listeMaillages.append((maQuery.value(0).toInt()[0], maQuery.value(1).toString(), maQuery.value(2).toString()))
- return listeMaillages
-
- def verifieListeMaillages(self,listeMaillage):
- newListeMaillages=[]
- maQuery=QSqlQuery()
- for idM in listeMaillage:
- texteQuery="select id, nomScript,medResultat from Maillages where id = " + str(idM) +';'
- maQuery.exec_(texteQuery)
- maSize=0
- while(maQuery.next()):
- maSize+=1
- newListeMaillages.append((maQuery.value(0).toInt()[0], maQuery.value(1).toString(), maQuery.value(2).toString()))
- if maSize != 1 :
- print "impossible de traiter le maillage : ", idM
- return newListeMaillages
- def getSeuilsPourMaillage(self,idMaillage):
- texteQuery="select id,nomMaillage,seuilCPU,seuilRatio,seuilTaille,seuilNbMaille from Maillages where id = "+ str(idMaillage) +" ;"
- maQuery=QSqlQuery()
- maQuery.exec_(texteQuery)
- while(maQuery.next()):
- l1 = maQuery.value(0).toInt()[0]
- l2 = maQuery.value(1).toString()
- l3 = maQuery.value(2).toInt()[0]
- l4 = maQuery.value(3).toInt()[0]
- l5 = maQuery.value(4).toInt()[0]
- l6 = maQuery.value(5).toInt()[0]
- return l1,l2,l3,l4,l5,l6
+ def construitListeMaillages(self):
+ maQuery=QSqlQuery()
+ texteQuery="select id, nomScript,medResultat from Maillages;"
+ maQuery.exec_(texteQuery)
+ listeMaillages=[]
+ while(maQuery.next()):
+ listeMaillages.append((maQuery.value(0).toInt()[0], maQuery.value(1).toString(), maQuery.value(2).toString()))
+ return listeMaillages
- def getTous(self):
- maillagesIdListe=[]; maillagesNomListe=[]
- texteQuery="select id,nomMaillage from Maillages order by id;"
- maQuery=QSqlQuery()
+ def verifieListeMaillages(self,listeMaillage):
+ newListeMaillages=[]
+ maQuery=QSqlQuery()
+ for idM in listeMaillage:
+ texteQuery="select id, nomScript,medResultat from Maillages where id = " + str(idM) +';'
maQuery.exec_(texteQuery)
+ maSize=0
while(maQuery.next()):
- maillagesIdListe.append( maQuery.value(0).toInt()[0])
- maillagesNomListe.append( maQuery.value(1).toString())
- return maillagesIdListe, maillagesNomListe
+ maSize+=1
+ newListeMaillages.append((maQuery.value(0).toInt()[0], maQuery.value(1).toString(), maQuery.value(2).toString()))
+ if maSize != 1 :
+ print "impossible de traiter le maillage : ", idM
+ return newListeMaillages
- def getMailleurId(self,idMaillage):
- texteQuery="select idMailleur from Maillages where id = "+ str(idMaillage) +" ;"
- maQuery=QSqlQuery()
- print texteQuery
- print maQuery.exec_(texteQuery)
- maQuery.exec_(texteQuery)
- while(maQuery.next()):
- idMailleur = maQuery.value(0).toInt()[0]
- return idMailleur
+ def getSeuilsPourMaillage(self,idMaillage):
+ texteQuery="select id,nomMaillage,seuilCPU,seuilRatio,seuilTaille,seuilNbMaille from Maillages where id = "+ str(idMaillage) +" ;"
+ maQuery=QSqlQuery()
+ maQuery.exec_(texteQuery)
+ while(maQuery.next()):
+ l1 = maQuery.value(0).toInt()[0]
+ l2 = maQuery.value(1).toString()
+ l3 = maQuery.value(2).toInt()[0]
+ l4 = maQuery.value(3).toInt()[0]
+ l5 = maQuery.value(4).toInt()[0]
+ l6 = maQuery.value(5).toInt()[0]
+ return l1,l2,l3,l4,l5,l6
+
+ def getTous(self):
+ maillagesIdListe=[]; maillagesNomListe=[]
+ texteQuery="select id,nomMaillage from Maillages order by id;"
+ maQuery=QSqlQuery()
+ maQuery.exec_(texteQuery)
+ while(maQuery.next()):
+ maillagesIdListe.append( maQuery.value(0).toInt()[0])
+ maillagesNomListe.append( maQuery.value(1).toString())
+ return maillagesIdListe, maillagesNomListe
+
+ def getMailleurId(self,idMaillage):
+ texteQuery="select idMailleur from Maillages where id = "+ str(idMaillage) +" ;"
+ maQuery=QSqlQuery()
+ print texteQuery
+ print maQuery.exec_(texteQuery)
+ maQuery.exec_(texteQuery)
+ while(maQuery.next()):
+ idMailleur = maQuery.value(0).toInt()[0]
+ return idMailleur
from tableDeBase import TableDeBase
class TableMailleurs (TableDeBase):
- def __init__(self):
- TableDeBase.__init__(self,"Mailleurs")
- self.cols=" (nomMailleur) "
- self.setField(("id","nomMailleur"))
- self.setTypeField(("int","str"),('id'))
-
- def createSqlTable(self):
- query=QSqlQuery()
- print "Creation de TableMailleurs", query.exec_("create table Mailleurs(id integer primary key autoincrement, nomMailleur varchar(40));")
-
- def dejaRemplie(self):
- texteQuery="select * from Mailleurs where nomMailleur='Blsurf+Ghs3D';"
- maQuery=QSqlQuery()
- maQuery.exec_(texteQuery)
- nb=0
- while(maQuery.next()): nb=nb+1
- return nb
-
- def remplit(self):
- if self.dejaRemplie() :
- print "Table Mailleurs deja initialisee"
- return
- self.insereLigneAutoId(('BLSURF',))
- self.insereLigneAutoId(('NETGEN1D2D',))
- self.insereLigneAutoId(('GHS3D+BLSURF',))
- self.insereLigneAutoId(('GHS3D+NETGEN1D2D',))
- self.insereLigneAutoId(('NETGEN1D2D3D',))
-
- def insereLigneAutoId(self,valeurs,debug=False):
- # difficulte a construire le texte avec une seule valeur
- texteQuery='insert into Mailleurs (nomMailleur) values ("'+ str(valeurs[0])+ '");'
- maQuery=QSqlQuery()
- if debug : print texteQuery, " " , maQuery.exec_(texteQuery)
- else : maQuery.exec_(texteQuery)
-
- def getTous(self):
- l1=[]
- l2=[]
- texteQuery="select * from Mailleurs;"
- maQuery=QSqlQuery()
- maQuery.exec_(texteQuery)
- while(maQuery.next()):
- l1.append( maQuery.value(0).toInt()[0])
- l2.append( maQuery.value(1).toString())
- return l1,l2
-
- def getName(self,mailleurId):
- texteQuery="select nomMailleur from Mailleurs where id = " + str(mailleurId) + " ;"
- maQuery=QSqlQuery()
- maQuery.exec_(texteQuery)
- while(maQuery.next()):
- mailleurName=maQuery.value(0).toString()
- return mailleurName
-
-
+ def __init__(self):
+ TableDeBase.__init__(self,"Mailleurs")
+ self.cols=" (nomMailleur) "
+ self.setField(("id","nomMailleur"))
+ self.setTypeField(("int","str"),('id'))
+
+ def createSqlTable(self):
+ query=QSqlQuery()
+ print "Creation de TableMailleurs", query.exec_("create table Mailleurs(id integer primary key autoincrement, nomMailleur varchar(40));")
+
+ def dejaRemplie(self):
+ texteQuery="select * from Mailleurs where nomMailleur='Blsurf+Ghs3D';"
+ maQuery=QSqlQuery()
+ maQuery.exec_(texteQuery)
+ nb=0
+ while(maQuery.next()): nb=nb+1
+ return nb
+
+ def remplit(self):
+ if self.dejaRemplie() :
+ print "Table Mailleurs deja initialisee"
+ return
+ self.insereLigneAutoId(('BLSURF',))
+ self.insereLigneAutoId(('NETGEN1D2D',))
+ self.insereLigneAutoId(('GHS3D+BLSURF',))
+ self.insereLigneAutoId(('GHS3D+NETGEN1D2D',))
+ self.insereLigneAutoId(('NETGEN1D2D3D',))
+
+ def insereLigneAutoId(self,valeurs,debug=False):
+ # difficulte a construire le texte avec une seule valeur
+ texteQuery='insert into Mailleurs (nomMailleur) values ("'+ str(valeurs[0])+ '");'
+ maQuery=QSqlQuery()
+ if debug : print texteQuery, " " , maQuery.exec_(texteQuery)
+ else : maQuery.exec_(texteQuery)
+
+ def getTous(self):
+ l1=[]
+ l2=[]
+ texteQuery="select * from Mailleurs;"
+ maQuery=QSqlQuery()
+ maQuery.exec_(texteQuery)
+ while(maQuery.next()):
+ l1.append( maQuery.value(0).toInt()[0])
+ l2.append( maQuery.value(1).toString())
+ return l1,l2
+
+ def getName(self,mailleurId):
+ texteQuery="select nomMailleur from Mailleurs where id = " + str(mailleurId) + " ;"
+ maQuery=QSqlQuery()
+ maQuery.exec_(texteQuery)
+ while(maQuery.next()):
+ mailleurName=maQuery.value(0).toString()
+ return mailleurName
from tableDeBase import TableDeBase
class TableVersions (TableDeBase):
- def __init__(self):
- TableDeBase.__init__(self,"Versions")
- self.setField(("id","nomVersion","commentaire"))
- self.setTypeField(('int','str','str'),('id',))
- self.cols=" (nomVersion, commentaire) "
-
- def createSqlTable(self):
- query=QSqlQuery()
- texteQuery ="create table Versions(id integer primary key autoincrement, nomVersion varchar(10),"
- texteQuery+="commentaire varchar(30));"
- print "Creation de TableVersions : " , query.exec_(texteQuery)
-
-
- def remplit(self):
- self.insereLigneAutoId(('Salome7.2.0',''))
- self.insereLigneAutoId(('Salome7.3.0',''))
- self.insereLigneAutoId(('Salome7.4.0',''))
-
- def creeVersion(self,version,commentaire=""):
- self.insereLigneAutoId((version,commentaire))
-
-
- def chercheVersion(self,version):
- query=QSqlQuery()
- version=str(version)
- if bool(version) == True :
- texteQuery ="select id, nomVersion from Versions where id = " + str(version) +";"
- else:
- texteQuery ="select id, nomVersion from Versions where nomVersion ='" + version +"' ;"
- query.exec_(texteQuery)
- nb=0
- while(query.next()):
- nb=nb+1
- id=query.value(0).toInt()[0]
- nom=query.value(1).toString()
- if nb != 1 : return 0, 0, ""
- return 1, id, nom
-
-
-
+ def __init__(self):
+ TableDeBase.__init__(self,"Versions")
+ self.setField(("id","nomVersion","commentaire"))
+ self.setTypeField(('int','str','str'),('id',))
+ self.cols=" (nomVersion, commentaire) "
+
+ def createSqlTable(self):
+ query=QSqlQuery()
+ texteQuery ="create table Versions(id integer primary key autoincrement, nomVersion varchar(10),"
+ texteQuery+="commentaire varchar(30));"
+ print "Creation de TableVersions : " , query.exec_(texteQuery)
+
+
+ def remplit(self):
+ self.insereLigneAutoId(('Salome7.2.0',''))
+ self.insereLigneAutoId(('Salome7.3.0',''))
+ self.insereLigneAutoId(('Salome7.4.0',''))
+
+ def creeVersion(self,version,commentaire=""):
+ self.insereLigneAutoId((version,commentaire))
+
+
+ def chercheVersion(self,version):
+ query=QSqlQuery()
+ version=str(version)
+ if bool(version) == True :
+ texteQuery ="select id, nomVersion from Versions where id = " + str(version) +";"
+ else:
+ texteQuery ="select id, nomVersion from Versions where nomVersion ='" + version +"' ;"
+ query.exec_(texteQuery)
+ nb=0
+ while(query.next()):
+ nb=nb+1
+ id=query.value(0).toInt()[0]
+ nom=query.value(1).toString()
+ if nb != 1 : return 0, 0, ""
+ return 1, id, nom
if __name__ == "__main__":
- from optparse import OptionParser
- p=OptionParser()
- p.add_option('-a',dest='all',action="store_true", default=False,help='passe l ensemble des Tests')
- p.add_option('-s',dest='salomePath',help='chemin du runAppli',default="Appli")
- p.add_option('-v',dest='version',help='id de la version')
- p.add_option('-d',dest='database',default="myMesh.db",help='nom de la database')
- p.add_option('-f',dest='force',default=True,help='force la passage des jobs meme si l execution a deja eu lieu sur cette machine pour cette version de salome')
- options, args = p.parse_args()
- if len(args) == 0 and options.all== False:
- print "Enter -a ou un numero de job"
- print 2
- exit()
- if options.salomePath==None :
- print "chemin du runAppli obligatoire"
- exit()
- if options.version==None :
- options.version=Chercheversion(options.salomePath)
- maBase=Base(options.database)
- maBase.initialise()
- maBase.passeJobs(options.all,options.salomePath,options.version,options.force,args)
- maBase.close()
-
+ from optparse import OptionParser
+ p=OptionParser()
+ p.add_option('-a',dest='all',action="store_true", default=False,help='passe l ensemble des Tests')
+ p.add_option('-s',dest='salomePath',help='chemin du runAppli',default="Appli")
+ p.add_option('-v',dest='version',help='id de la version')
+ p.add_option('-d',dest='database',default="myMesh.db",help='nom de la database')
+ p.add_option('-f',dest='force',default=True,help='force la passage des jobs meme si l execution a deja eu lieu sur cette machine pour cette version de salome')
+ options, args = p.parse_args()
+ if len(args) == 0 and options.all== False:
+ print "Enter -a ou un numero de job"
+ print 2
+ exit()
+ if options.salomePath==None :
+ print "chemin du runAppli obligatoire"
+ exit()
+ if options.version==None :
+ options.version=Chercheversion(options.salomePath)
+ maBase=Base(options.database)
+ maBase.initialise()
+ maBase.passeJobs(options.all,options.salomePath,options.version,options.force,args)
+ maBase.close()
force = os.getenv("FORCE_DISTENE_LICENSE_FILE")
if force != None:
- os.environ["DISTENE_LICENSE_FILE"] = force
- os.environ["DLIM8VAR"] = "NOTHING"
+ os.environ["DISTENE_LICENSE_FILE"] = force
+ os.environ["DLIM8VAR"] = "NOTHING"
class MonViewText(Ui_ViewExe, QDialog):
"""
self.monExe.readyReadStandardOutput.connect( self.readFromStdOut )
self.monExe.readyReadStandardError.connect( self.readFromStdErr )
self.monExe.finished.connect( self.finished )
-
+
cmds = ''
ext = ''
if sys.platform == "win32":
cmds += 'echo %s\n' % txt #to see what is compute command
cmds += txt+'\n'
cmds += 'echo "END_OF_MGSurfOpt"\n'
-
+
nomFichier = os.path.splitext(self.parent().fichierOut)[0] + ext
with open(nomFichier, 'w') as f:
- f.write(cmds)
+ f.write(cmds)
self.make_executable(nomFichier)
-
+
if verbose: print("INFO: MGSurfOpt launch script file: %s" % nomFichier)
-
+
self.monExe.start(nomFichier)
self.monExe.closeWriteChannel()
self.enregistreResultatsDone=False
if fn.isNull() : return
ulfile = os.path.abspath(unicode(fn))
try:
- f = open(fn, 'wb')
- f.write(str(self.TB_Exe.toPlainText()))
- f.close()
+ f = open(fn, 'wb')
+ f.write(str(self.TB_Exe.toPlainText()))
+ f.close()
except IOError, why:
- QMessageBox.critical(self, 'Save File',
- 'The file <b>%1</b> could not be saved.<br>Reason: %2'%(unicode(fn), str(why)))
+ QMessageBox.critical(self, 'Save File',
+ 'The file <b>%1</b> could not be saved.<br>Reason: %2'%(unicode(fn), str(why)))
def readFromStdErr(self):
a=self.monExe.readAllStandardError()
def readFromStdOut(self) :
a=self.monExe.readAllStandardOutput()
aa=unicode(a.data())
- self.TB_Exe.append(aa)
-
+ self.TB_Exe.append(aa)
+
def finished(self):
self.parent().enregistreResultat()
self.enregistreResultatsDone=True
-
+
def theClose(self):
- if not self.enregistreResultatsDone:
- self.parent().enregistreResultat()
- self.enregistreResultatsDone=True
- self.close()
+ if not self.enregistreResultatsDone:
+ self.parent().enregistreResultat()
+ self.enregistreResultatsDone=True
+ self.close()
self.__ui.btnClear.setIcon(icon)
# Then, we can connect the slot to there associated button event
- self.__ui.btnInput.clicked.connect( self.onInput )
+ self.__ui.btnInput.clicked.connect( self.onInput )
self.__ui.btnCompute.clicked.connect( self.onCompute )
self.__ui.btnRefresh.clicked.connect( self.onRefresh )
self.__ui.btnPublish.clicked.connect( self.onPublish )
self.clear()
self.setupJobManager()
-
+
def setupJobManager(self):
'''
the initialize step, by specifing the name of the resource to
be used.
'''
- # We first
-
+ # We first
+
configReader = ConfigReader()
config = configReader.getLocalConfig()
configId = config.resname
self.__inputDialog.windowFlags() | Qt.WindowStaysOnTopHint)
# The signal inputValidated emitted from inputDialog is
# connected to the slot function onProcessInput:
- self.__inputDialog.inputValidated.connect( self.onProcessInput )
-
+ self.__inputDialog.inputValidated.connect( self.onProcessInput )
+
else:
self.__ui.frameInput.setVisible(True)
self.__ui.btnInput.setVisible(False)
def getInputFrame(self):
return self.__ui.frameInput
-
+
def __setGuiState(self,states=["CAN_SELECT"]):
if "CAN_SELECT" in states:
self.__ui.btnInput.setEnabled(True)
else:
self.__ui.btnInput.setEnabled(False)
-
+
if "CAN_COMPUTE" in states:
self.__ui.btnCompute.setEnabled(True)
else:
def __log(self, message):
"""
This function prints the specified message in the log area
- """
+ """
self.__ui.txtLog.append(message)
def __exportMesh(self, meshName, meshObject):
self.__ui.lblStatusBar.setText("Input data OK")
self.__log("INF: Press \"Compute\" to start the job")
self.__setGuiState(["CAN_SELECT", "CAN_COMPUTE"])
-
+
def onCompute(self):
'''
This function is the slot connected to the Compute button. It
initializes a mesh computation job and start it using the
- SALOME launcher.
+ SALOME launcher.
'''
# We first have to create the list of parameters for the
# initialize function. For that, we have to create the files
self.__log("ERR: %s"%jobManager.getLastErrorMessage())
return
self.__log("INF: the job has been initialized with jobid = "+str(self.__jobid))
-
+
startOk = jobManager.start(self.__jobid)
if not startOk:
self.__log("ERR: the job with jobid = "+str(self.__jobid)+" can't be started")
This function is the slot connected on the Publish button. It
requests the mesh job manager to download the results data
from the computation resource host and load the med file in
- the SALOME study.
+ the SALOME study.
"""
jobManager = self.__getJobManager()
state = jobManager.getState(self.__jobid)
one is running.
"""
self.clear()
-
+
__dialog=None
def getDialog():
"""
- This function returns a singleton instance of the plugin dialog.
+ This function returns a singleton instance of the plugin dialog.
"""
global __dialog
if __dialog is None:
if __name__ == "__main__":
TEST_PluginDialog()
-
-
-
