-# Copyright (C) 2007-2022 CEA/DEN, EDF R&D, OPEN CASCADE
+# Copyright (C) 2007-2024 CEA, EDF, OPEN CASCADE
#
# This library is free software; you can redistribute it and/or
# modify it under the terms of the GNU Lesser General Public
functor = aFilterMgr.CreateAspectRatio3D()
elif theCriterion == FT_Warping:
functor = aFilterMgr.CreateWarping()
+ elif theCriterion == FT_Warping3D:
+ functor = aFilterMgr.CreateWarping3D()
elif theCriterion == FT_MinimumAngle:
functor = aFilterMgr.CreateMinimumAngle()
elif theCriterion == FT_Taper:
functor = aFilterMgr.CreateNodeConnectivityNumber()
elif theCriterion == FT_BallDiameter:
functor = aFilterMgr.CreateBallDiameter()
+ elif theCriterion == FT_ScaledJacobian:
+ functor = aFilterMgr.CreateScaledJacobian()
else:
print("Error: given parameter is not numerical functor type.")
aFilterMgr.UnRegister()
geo_name = "%s_%s to mesh"%(self.geom.GetShapeType(), id(self.geom)%100)
geompyD.addToStudy( self.geom, geo_name )
if parallel and isinstance(self, ParallelMesh):
- self.SetMesh( self.smeshpyD.CreateParallelMesh(self.geom) )
+ mymesh = self.smeshpyD.CreateParallelMesh(self.geom)
+ mymesh2 = mymesh._narrow(SMESH._objref_SMESH_Mesh)
+ self.SetMesh( mymesh )
else:
self.SetMesh( self.smeshpyD.CreateMesh(self.geom) )
return ok
+ def CheckCompute(self, isDone):
+ """
+ Check if the mesh was properly compute
+ """
+ if not isDone:
+ raise Exception("Could not compute {}".format(self.GetName()))
+
def GetComputeErrors(self, shape=0 ):
"""
Return a list of error messages (:class:`SMESH.ComputeError`) of the last :meth:`Compute`
if mesh: mesh = self.smeshpyD.Mesh(mesh)
return mesh, group
+ def MakeBoundaryOfEachElement(self, groupName="", meshName="", toCopyAll=False, groups=[] ):
+ """
+ Create boundary elements around the whole mesh or groups of elements
+
+ Parameters:
+ groupName: a name of group to store all boundary elements in,
+ "" means not to create the group
+ 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
+ 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
+ groups: list of :class:`sub-meshes, groups or filters <SMESH.SMESH_IDSource>` of elements to make boundary around
+
+ Returns:
+ tuple( long, mesh, group )
+ - long - number of added boundary elements
+ - mesh - the :class:`Mesh` where elements were added to
+ - group - the :class:`group <SMESH.SMESH_Group>` of boundary elements or None
+ """
+ dimension=SMESH.BND_2DFROM3D
+ toCreateAllElements = True # create all boundary elements in the mesh
+ nb, mesh, group = self.editor.MakeBoundaryElements( dimension,groupName,meshName,
+ toCopyAll,toCreateAllElements,groups)
+ if mesh: mesh = self.smeshpyD.Mesh(mesh)
+ return nb, mesh, group
+
def MakeBoundaryElements(self, dimension=SMESH.BND_2DFROM3D, groupName="", meshName="",
toCopyAll=False, groups=[]):
"""
- mesh - the :class:`Mesh` where elements were added to
- group - the :class:`group <SMESH.SMESH_Group>` of boundary elements or None
"""
-
+ toCreateAllElements = False # create only elements in the boundary of the solid
nb, mesh, group = self.editor.MakeBoundaryElements(dimension,groupName,meshName,
- toCopyAll,groups)
+ toCopyAll,toCreateAllElements,groups)
if mesh: mesh = self.smeshpyD.Mesh(mesh)
return nb, mesh, group
return self.FunctorValue(SMESH.FT_Warping, elemId)
+ def GetWarping3D(self, elemId):
+ """
+ Get warping angle of faces element of 3D elements.
+
+ Parameters:
+ elemId: mesh element ID
+
+ Returns:
+ element's warping angle value
+ """
+
+ return self.FunctorValue(SMESH.FT_Warping3D, elemId)
+
def GetMinimumAngle(self, elemId):
"""
Get minimum angle of 2D element.
return self.FunctorValue(SMESH.FT_Skew, elemId)
+ def GetScaledJacobian(self, elemId):
+ """
+ Get the scaled jacobian of 3D element id
+
+ Parameters:
+ elemId: mesh element ID
+
+ Returns:
+ the scaled jacobian
+ """
+
+ return self.FunctorValue(SMESH.FT_ScaledJacobian, elemId)
+
def GetMinMax(self, funType, meshPart=None):
"""
Return minimal and maximal value of a given functor.
pass # end of Mesh class
+def _copy_gmsh_param(dim, local_param, global_param):
+ if dim==3:
+ local_param.SetMaxSize(global_param.GetMaxSize())
+ local_param.SetMinSize(global_param.GetMinSize())
+ local_param.Set3DAlgo(global_param.Get3DAlgo())
+ local_param.SetRecombineAll(global_param.GetRecombineAll())
+ local_param.SetSubdivAlgo(global_param.GetSubdivAlgo())
+ local_param.SetRemeshAlgo(global_param.GetRemeshAlgo())
+ local_param.SetRemeshPara(global_param.GetRemeshPara())
+ local_param.SetSmouthSteps(global_param.GetSmouthSteps())
+ local_param.SetSizeFactor(global_param.GetSizeFactor())
+ local_param.SetUseIncomplElem(global_param.GetUseIncomplElem())
+ local_param.SetMeshCurvatureSize(global_param.GetMeshCurvatureSize())
+ local_param.SetSecondOrder(global_param.GetSecondOrder())
+ local_param.SetIs2d(global_param.GetIs2d())
+ elif dim==2:
+ local_param.SetMaxSize(global_param.GetMaxSize())
+ local_param.SetMinSize(global_param.GetMinSize())
+ local_param.Set2DAlgo(global_param.Get2DAlgo())
+ local_param.SetRecomb2DAlgo(global_param.GetRecomb2DAlgo())
+ local_param.SetRecombineAll(global_param.GetRecombineAll())
+ local_param.SetSubdivAlgo(global_param.GetSubdivAlgo())
+ local_param.SetRemeshAlgo(global_param.GetRemeshAlgo())
+ local_param.SetRemeshPara(global_param.GetRemeshPara())
+ local_param.SetSmouthSteps(global_param.GetSmouthSteps())
+ local_param.SetSizeFactor(global_param.GetSizeFactor())
+ local_param.SetUseIncomplElem(global_param.GetUseIncomplElem())
+ local_param.SetMeshCurvatureSize(global_param.GetMeshCurvatureSize())
+ local_param.SetSecondOrder(global_param.GetSecondOrder())
+ local_param.SetIs2d(global_param.GetIs2d())
def _copy_netgen_param(dim, local_param, global_param):
"""
Create 1D/2D/3D netgen parameters from a NETGEN 1D2D3D parameter
"""
if dim==1:
- #TODO: Try to identify why we need to substract 1
- local_param.NumberOfSegments(int(global_param.GetNbSegPerEdge())-1)
+ #TODO: More global conversion ? or let user define it
+ local_param.NumberOfSegments(int(global_param.GetMaxSize()))
elif dim==2:
local_param.SetMaxSize(global_param.GetMaxSize())
local_param.SetMinSize(global_param.GetMinSize())
local_param.SetFineness(global_param.GetFineness())
local_param.SetNbSegPerEdge(global_param.GetNbSegPerEdge())
local_param.SetNbSegPerRadius(global_param.GetNbSegPerRadius())
+ #TODO: Why the 0.9 to have same results
local_param.SetGrowthRate(global_param.GetGrowthRate()*0.9)
local_param.SetChordalError(global_param.GetChordalError())
local_param.SetChordalErrorEnabled(global_param.GetChordalErrorEnabled())
local_param.SetGrowthRate(global_param.GetGrowthRate())
local_param.SetNbThreads(global_param.GetNbThreads())
+
+def _shaperstudy2geom(geompyD, shaper_obj):
+ """
+ Convertion of shaper object to geom object
+
+ Parameters:
+ geompyD: geomBuilder instance
+ shaper_obj: Shaper study object
+
+ Returns:
+ geom object
+
+ """
+ import tempfile
+ #Writing shaperstudy object into a brep file
+ fid, tmp_file = tempfile.mkstemp(suffix='.brep')
+ with open(fid, 'wb') as f:
+ f.write(shaper_obj.GetShapeStream())
+ # Reimporting brep file into geom
+ real_geom = geompyD.ImportBREP(tmp_file)
+ os.remove(tmp_file)
+
+ return real_geom
+
+
def _split_geom(geompyD, geom):
"""
Splitting geometry into n solids and a 2D/1D compound
geompyD: geomBuilder instance
geom: geometrical object for meshing
+ Returns:
+ compound containing all the 1D,2D elements
+ list of solids
"""
+
# Splitting geometry into 3D elements and all the 2D/1D into one compound
object_solids = geompyD.ExtractShapes(geom, geompyD.ShapeType["SOLID"],
True)
faces = []
iface = 0
- for isolid, solid in enumerate(solids):
- solid_faces = geompyD.ExtractShapes(solid, geompyD.ShapeType["FACE"],
- True)
- for face in solid_faces:
- faces.append(face)
- iface += 1
- geompyD.addToStudyInFather(solid, face,
- 'Face_{}'.format(iface))
-
- # Creating submesh for edges 1D/2D part
+ solid_faces = geompyD.ExtractShapes(geom, geompyD.ShapeType["FACE"],
+ True)
+ for face in solid_faces:
+ faces.append(face)
+ iface += 1
+ geompyD.addToStudyInFather(geom, face,
+ 'Face_{}'.format(iface))
- all_faces = geompyD.MakeCompound(faces)
- geompyD.addToStudy(all_faces, 'Compound_1')
- all_faces = geompyD.MakeGlueEdges(all_faces, 1e-07)
- all_faces = geompyD.MakeGlueFaces(all_faces, 1e-07)
- geompyD.addToStudy(all_faces, 'global2D')
+ return faces, solids
- return all_faces, solids
+MULTITHREAD, MULTINODE = range(2)
class ParallelismSettings:
"""
Defines the parameters for the parallelism of ParallelMesh
self._mesh = mesh
+
+class MTParallelismSettings(ParallelismSettings):
+ """
+ Defines the parameters for the parallelism of ParallelMesh using MultiThreading
+ """
+ def __init__(self, mesh):
+ ParallelismSettings.__init__(self, mesh)
+
+ # Multithreading methods
def SetNbThreads(self, nbThreads):
- """
- Set the number of threads for multithreading
- """
+ """ Set the number of threads for multithread """
if nbThreads < 1:
raise ValueError("Number of threads must be stricly greater than 1")
self._mesh.mesh.SetNbThreads(nbThreads)
def GetNbThreads(self):
- """
- Get Number of threads
- """
+ """ Get Number of threads """
return self._mesh.mesh.GetNbThreads()
+ def __str__(self):
+ """ str conversion """
+ string = "\nParameter for MultiThreading parallelism:\n"
+ string += "NbThreads: {}\n".format(self.GetNbThreads())
+
+ return string
+
+
+class MNParallelismSettings(ParallelismSettings):
+ """
+ Defines the parameters for the parallelism of ParallelMesh using MultiNodal
+ """
+ def __init__(self, mesh):
+ ParallelismSettings.__init__(self, mesh)
+
+ def GetResource(self):
+ """ Get the resource on which to run """
+ return self._mesh.mesh.GetResource()
+
+ def SetResource(self, resource):
+ """ Set the resource on which to run """
+ self._mesh.mesh.SetResource(resource)
+
+ def SetNbProc(self, nbProc):
+ """ Set the number of Processor for multinode """
+ if nbProc < 1:
+ raise ValueError("Number of Proc must be stricly greater than 1")
+ self._mesh.mesh.SetNbProc(nbProc)
+
+ def GetNbProc(self):
+ """ Get Number of Processor """
+ return self._mesh.mesh.GetNbProc()
+
+ def SetNbProcPerNode(self, nbProcPerNode):
+ """ Set the number of Processor Per Node for multinode """
+ if nbProcPerNode < 1:
+ raise ValueError("Number of Processor Per Node must be stricly greater than 1")
+
+ self._mesh.mesh.SetNbProcPerNode(nbProcPerNode)
+
+ def GetNbProcPerNode(self):
+ """ Get Number of Processor Per Node """
+ return self._mesh.mesh.GetNbProcPerNode()
+
+ def SetNbNode(self, nbNode):
+ """ Set the number of Node for multinode """
+ if nbNode < 1:
+ raise ValueError("Number of Node must be stricly greater than 1")
+ self._mesh.mesh.SetNbNode(nbNode)
+
+ def GetNbNode(self):
+ """ Get Number of Node """
+ return self._mesh.mesh.GetNbNode()
+
+ def SetWcKey(self, wcKey):
+ """ Set the number of Node for multinode """
+ self._mesh.mesh.SetWcKey(wcKey)
+
+ def GetWcKey(self):
+ """ Get Number of Node """
+ return self._mesh.mesh.GetWcKey()
+
+ def SetWalltime(self, walltime):
+ """ Set the number of Node for multinode """
+ self._mesh.mesh.SetWalltime(walltime)
+
+ def GetWalltime(self):
+ """ Get Number of Node """
+ return self._mesh.mesh.GetWalltime()
+
+ def __str__(self):
+ """ str conversion """
+ string = "\nParameter for MultiNode parallelism:\n"
+ string += "Reource: {}\n".format(self.GetResource())
+ string += "NbProc: {}\n".format(self.GetNbProc())
+ string += "NbProcPerNode: {}\n".format(self.GetNbProcPerNode())
+ string += "NbNode: {}\n".format(self.GetNbNode())
+ string += "WcKey: {}\n".format(self.GetWcKey())
+ string += "Walltime: {}\n".format(self.GetWalltime())
+
+ return string
+
+
class ParallelMesh(Mesh):
"""
Surcharge on Mesh for parallel computation of a mesh
if not isinstance(geom, geomBuilder.GEOM._objref_GEOM_Object):
raise ValueError("geom argument must be a geometry")
+ try:
+ import SHAPERSTUDY
+ shaper_object = SHAPERSTUDY.SHAPERSTUDY_ORB._objref_SHAPER_Object
+ has_shaper = True
+ except ImportError:
+ shaper_object = int
+ has_shaper = False
+
+ # If we have a shaper object converting it into geom (temporary solution)
+ if isinstance(geom, shaper_object):
+ self._geom_obj = _shaperstudy2geom(geompyD, geom)
+ elif isinstance(geom, geomBuilder.GEOM._objref_GEOM_Object):
+ self._geom_obj = geom
+ else:
+ msg= ""
+ if not has_shaper:
+ msg = "\nShaper was not compiled"
+ raise Exception("Could not handle geom format {}.{} ".format(type(geom), msg))
+
# Splitting geometry into one geom containing 1D and 2D elements and a
# list of 3D elements
- super(ParallelMesh, self).__init__(smeshpyD, geompyD, geom, name, parallel=True)
+ super(ParallelMesh, self).__init__(smeshpyD, geompyD, self._geom_obj, name, parallel=True)
if split_geom:
- self._all_faces, self._solids = _split_geom(geompyD, geom)
+ self._faces, self._solids = _split_geom(geompyD, self._geom_obj)
- self.UseExistingSegments()
- self.UseExistingFaces()
+ self._param = None
- self._algo2d = self.Triangle(geom=self._all_faces, algo="NETGEN_2D")
- self._algo3d = []
+ def _build_submeshes(self, mesher2D, mesher3D):
+ """
+ Contruct the submeshes for a parallel use of smesh
+
+ Parameters:
+ mesher2D: name of 2D mesher for 2D parallel compute (NETGEN)
+ mesher3D: name of 3D mesher for 3D parallel compute (NETGEN or
+ GMSH)
+ """
+
+ # Building global 2D mesher
+ if mesher3D:
+ if mesher3D == "NETGEN":
+ algo2D = "NETGEN_2D"
+ elif mesher3D == "GMSH":
+ algo2D = "GMSH_2D"
+ else:
+ raise ValueError("mesher3D should be either NETGEN or GMSH")
+
+ self._algo2d = self.Triangle(geom=self._geom_obj, algo=algo2D)
+
+ # Parallel 2D
+ if mesher2D:
+ #Means that we want to mesh face of solids in parallel and not
+ #the volume
+ self._algo2d = []
+ #For the moment use AutomaticLength based on finesse
+ # TODO: replace by input hypothesis
+ self._algo1d = self.Segment(geom=self._geom_obj)
+
+ for face_id, face in enumerate(self._faces):
+ name = "face_{}".format(face_id)
+ algo2d = self.Triangle(geom=face, algo="NETGEN_2D_Remote")
+ self._algo2d.append(algo2d)
+ if mesher3D:
+ self._algo3d = []
for solid_id, solid in enumerate(self._solids):
name = "Solid_{}".format(solid_id)
- self.UseExistingSegments(geom=solid)
- self.UseExistingFaces(geom=solid)
- algo3d = self.Tetrahedron(geom=solid, algo="NETGEN_3D_Remote")
- self._algo3d.append(algo3d)
+ if ( mesher3D == "NETGEN" ):
+ algo3d = self.Tetrahedron(geom=solid, algo="NETGEN_3D_Remote")
+ self._algo3d.append(algo3d)
+ elif ( mesher3D == "GMSH" ):
+ algo3d = self.Tetrahedron(geom=solid, algo="GMSH_3D_Remote")
+ self._algo3d.append(algo3d)
+
+ def GetNbSolids(self):
+ """
+ Return the number of 3D solids
+ """
+ return len(self._solids)
+
+ def GetNbFaces(self):
+ """
+ Return the number of 2D faces
+ """
+ return len(self._faces)
+
+ def GetParallelismMethod(self):
+ """ Get the parallelims method """
+ return self.mesh.GetParallelismMethod()
+
+ def SetParallelismMethod(self, method):
+ """ Set the parallelims method """
+ if method not in [MULTITHREAD , MULTINODE]:
+ raise ValueError("Parallelism method can only be 0:MultiThread or 1:MultiNode")
- self._param = ParallelismSettings(self)
+ self.mesh.SetParallelismMethod(method)
+ if method == MULTITHREAD:
+ self._param = MTParallelismSettings(self)
+ else:
+ self._param = MNParallelismSettings(self)
def GetParallelismSettings(self):
"""
Return class to set parameters for the parallelism
"""
+ if self._param is None:
+ raise Exception("You need to set Parallelism method first (SetParallelismMethod)")
return self._param
def AddGlobalHypothesis(self, hyp):
hyp: a hypothesis to assign
"""
- if not isinstance(hyp, NETGENPlugin._objref_NETGENPlugin_Hypothesis):
- raise ValueError("param must come from NETGENPlugin")
+ if isinstance(hyp, NETGENPlugin._objref_NETGENPlugin_Hypothesis):
+ copy_param = _copy_netgen_param
+ mesher3D = "NETGEN"
+ elif isinstance(hyp, GMSHPlugin._objref_GMSHPlugin_Hypothesis):
+ copy_param = _copy_gmsh_param
+ mesher3D = "GMSH"
+ else:
+ raise ValueError("param must come from NETGENPlugin or GMSHPlugin")
+
+ self.mesh.SetParallelismDimension(3)
+ self._build_submeshes(None, mesher3D)
param2d = self._algo2d.Parameters()
- _copy_netgen_param(2, param2d, hyp)
+ copy_param(2, param2d, hyp)
for algo3d in self._algo3d:
-
param3d = algo3d.Parameters()
- _copy_netgen_param(3, param3d, hyp)
+ copy_param(3, param3d, hyp)
+ def Add2DGlobalHypothesis(self, hyp):
+ """
+ Split hypothesis to apply it to all the submeshes:
+ - the 1D
+ - each of the 2D faces
- pass # End of ParallelMesh
+ Parameters:
+ hyp: a hypothesis to assign
+
+ """
+ if isinstance(hyp, NETGENPlugin._objref_NETGENPlugin_Hypothesis):
+ copy_param = _copy_netgen_param
+ mesher2D = "NETGEN"
+ else:
+ raise ValueError("param must come from NETGENPlugin")
+ self.mesh.SetParallelismDimension(2)
+ self._build_submeshes(mesher2D, None)
+
+ param1d = self._algo1d
+ copy_param(1, param1d, hyp)
+
+ for algo2d in self._algo2d:
+ param2d = algo2d.Parameters()
+ copy_param(2, param2d, hyp)
+
+ pass # End of ParallelMesh
class meshProxy(SMESH._objref_SMESH_Mesh):
"""
if len( args ) == 1:
args += True,
return SMESH._objref_SMESH_Mesh.ExportDAT(self, *args)
- pass
+
omniORB.registerObjref(SMESH._objref_SMESH_Mesh._NP_RepositoryId, meshProxy)
+class parallelMeshProxy(SMESH._objref_SMESH_ParallelMesh):
+ def __init__(self,*args):
+ SMESH._objref_SMESH_ParallelMesh.__init__(self,*args)
+ def __deepcopy__(self, memo=None):
+ new = self.__class__(self)
+ return new
+omniORB.registerObjref(SMESH._objref_SMESH_ParallelMesh._NP_RepositoryId, parallelMeshProxy)
+
+
+
class submeshProxy(SMESH._objref_SMESH_subMesh):
"""