# License along with this library; if not, write to the Free Software
# Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
#
-# See http://www.opencascade.org/SALOME/ or email : webmaster.salome@opencascade.org
+# See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
#
# File : smesh.py
# Author : Francis KLOSS, OCC
import StdMeshers
import SMESH
-# Public variables
-# ----------------
REGULAR = 1
PYTHON = 2
smesh = salome.lcc.FindOrLoadComponent("FactoryServer", "SMESH")
smesh.SetCurrentStudy(salome.myStudy)
-# Private functions
-# -----------------
NO_NAME = "NoName"
def SetName(obj, name):
ior = salome.orb.object_to_string(obj)
sobj = salome.myStudy.FindObjectIOR(ior)
- attr = sobj.FindAttribute("AttributeName")[1]
- attr.SetValue(name)
-
-# Algorithms and hypothesis
-# =========================
-
-# Private class: Mesh_Algorithm
-# -----------------------------
+ if not sobj is None:
+ attr = sobj.FindAttribute("AttributeName")[1]
+ attr.SetValue(name)
+## Mother class to define algorithm, recommended to don't use directly.
+#
+# More details.
class Mesh_Algorithm:
- """
- Mother class to define algorithm, recommended to don't use directly
- """
+ # @class Mesh_Algorithm
+ # @brief Class Mesh_Algorithm
mesh = 0
geom = 0
subm = 0
+ algo = 0
+ ## If the algorithm is global, return 0
+ # \fn else return the submesh associated to this algorithm.
+ #
+ # More details.
def GetSubMesh(self):
- """
- If the algorithm is global, return 0
- else return the submesh associated to this algorithm
- """
return self.subm
+ ## Return the wrapped mesher.
+ def GetAlgorithm(self):
+ return self.algo
+
+ ## Private method. Print error message if a hypothesis was not assigned.
+ def TreatHypoStatus(self, status, hypName, geomName, isAlgo):
+ if isAlgo:
+ hypType = "algorithm"
+ else:
+ hypType = "hypothesis"
+ if status == SMESH.HYP_UNKNOWN_FATAL :
+ reason = "for unknown reason"
+ elif status == SMESH.HYP_INCOMPATIBLE :
+ reason = "this hypothesis mismatches algorithm"
+ elif status == SMESH.HYP_NOTCONFORM :
+ reason = "not conform mesh would be built"
+ elif status == SMESH.HYP_ALREADY_EXIST :
+ reason = hypType + " of the same dimension already assigned to this shape"
+ elif status == SMESH.HYP_BAD_DIM :
+ reason = hypType + " mismatches shape"
+ elif status == SMESH.HYP_CONCURENT :
+ reason = "there are concurrent hypotheses on sub-shapes"
+ elif status == SMESH.HYP_BAD_SUBSHAPE :
+ reason = "shape is neither the main one, nor its subshape, nor a valid group"
+ else:
+ return
+ hypName = '"' + hypName + '"'
+ geomName= '"' + geomName+ '"'
+ if status < SMESH.HYP_UNKNOWN_FATAL:
+ print hypName, "was assigned to", geomName,"but", reason
+ else:
+ print hypName, "was not assigned to",geomName,":", reason
+ pass
+
+ ## Private method.
def Create(self, mesh, geom, hypo, so="libStdMeshersEngine.so"):
- """
- Private method
- """
+ if geom is None:
+ raise RuntimeError, "Attemp to create " + hypo + " algoritm on None shape"
self.mesh = mesh
piece = mesh.geom
if geom==0:
geompy.addToStudyInFather(piece, geom, name)
self.subm = mesh.mesh.GetSubMesh(geom, hypo)
- algo = smesh.CreateHypothesis(hypo, so)
- SetName(algo, name + "/" + hypo)
- mesh.mesh.AddHypothesis(self.geom, algo)
+ self.algo = smesh.CreateHypothesis(hypo, so)
+ SetName(self.algo, name + "/" + hypo)
+ status = mesh.mesh.AddHypothesis(self.geom, self.algo)
+ self.TreatHypoStatus( status, hypo, name, 1 )
+ ## Private method
def Hypothesis(self, hyp, args=[], so="libStdMeshersEngine.so"):
- """
- Private method
- """
hypo = smesh.CreateHypothesis(hyp, so)
a = ""
s = "="
a = a + s + str(args[i])
s = ","
i = i + 1
- SetName(hypo, GetName(self.geom) + "/" + hyp + a)
- self.mesh.mesh.AddHypothesis(self.geom, hypo)
+ name = GetName(self.geom)
+ SetName(hypo, name + "/" + hyp + a)
+ status = self.mesh.mesh.AddHypothesis(self.geom, hypo)
+ self.TreatHypoStatus( status, hyp, name, 0 )
return hypo
# Public class: Mesh_Segment
# --------------------------
+## Class to define a segment 1D algorithm for discretization
+#
+# More details.
class Mesh_Segment(Mesh_Algorithm):
- """
- Class to define a segment 1D algorithm for discretization
- """
+ ## Private constructor.
def __init__(self, mesh, geom=0):
- """
- Private constructor
- """
self.Create(mesh, geom, "Regular_1D")
+ ## Define "LocalLength" hypothesis to cut an edge in several segments with the same length
+ # @param l for the length of segments that cut an edge
def LocalLength(self, l):
- """
- Define "LocalLength" hypothesis to cut an edge in several segments with the same length
- \param l for the length of segments that cut an edge
- """
hyp = self.Hypothesis("LocalLength", [l])
hyp.SetLength(l)
return hyp
+ ## Define "NumberOfSegments" hypothesis to cut an edge in several fixed number of segments
+ # @param n for the number of segments that cut an edge
+ # @param s for the scale factor (optional)
def NumberOfSegments(self, n, s=[]):
- """
- Define "NumberOfSegments" hypothesis to cut an edge in several fixed number of segments
- \param n for the number of segments that cut an edge
- \param s for the scale factor (optional)
- """
if s == []:
hyp = self.Hypothesis("NumberOfSegments", [n])
else:
hyp = self.Hypothesis("NumberOfSegments", [n,s])
+ hyp.SetDistrType( 1 )
hyp.SetScaleFactor(s)
hyp.SetNumberOfSegments(n)
return hyp
+ ## Define "Arithmetic1D" hypothesis to cut an edge in several segments with arithmetic length increasing
+ # @param start for the length of the first segment
+ # @param end for the length of the last segment
def Arithmetic1D(self, start, end):
- """
- Define "Arithmetic1D" hypothesis to cut an edge in several segments with arithmetic length increasing
- \param start for the length of the first segment
- \param end for the length of the last segment
- """
hyp = self.Hypothesis("Arithmetic1D", [start, end])
hyp.SetLength(start, 1)
hyp.SetLength(end , 0)
return hyp
+ ## Define "StartEndLength" hypothesis to cut an edge in several segments with geometric length increasing
+ # @param start for the length of the first segment
+ # @param end for the length of the last segment
def StartEndLength(self, start, end):
- """
- Define "StartEndLength" hypothesis to cut an edge in several segments with geometric length increasing
- \param start for the length of the first segment
- \param end for the length of the last segment
- """
hyp = self.Hypothesis("StartEndLength", [start, end])
hyp.SetLength(start, 1)
hyp.SetLength(end , 0)
return hyp
+ ## Define "Deflection1D" hypothesis
+ # @param d for the deflection
def Deflection1D(self, d):
- """
- Define "Deflection1D" hypothesis
- \param d for the deflection
- """
hyp = self.Hypothesis("Deflection1D", [d])
hyp.SetDeflection(d)
return hyp
+ ## Define "Propagation" hypothesis that propagate all other hypothesis on all others edges that are in
+ # the opposite side in the case of quadrangular faces
def Propagation(self):
- """
- Define "Propagation" hypothesis that propagate all other hypothesis on all others edges that are in
- the opposite side in the case of quadrangular faces
- """
return self.Hypothesis("Propagation")
+ ## Define "AutomaticLength" hypothesis
+ # @param fineness for the fineness [0-1]
+ def AutomaticLength(self, fineness=0):
+ hyp = self.Hypothesis("AutomaticLength")
+ hyp.SetFineness( fineness )
+ return hyp
+
+ ## Define "QuadraticMesh" hypothesis, forcing construction of quadratic edges.
+ # If the 2D mesher sees that all boundary edges are quadratic ones,
+ # it generates quadratic faces, else it generates linear faces using
+ # medium nodes as if they were vertex ones.
+ # The 3D mesher generates quadratic volumes only if all boundary faces
+ # are quadratic ones, else it fails.
+ def QuadraticMesh(self):
+ hyp = self.Hypothesis("QuadraticMesh")
+ return hyp
+
# Public class: Mesh_Segment_Python
# ---------------------------------
+## Class to define a segment 1D algorithm for discretization with python function
+#
+# More details.
class Mesh_Segment_Python(Mesh_Segment):
- """
- Class to define a segment 1D algorithm for discretization with python function
- """
+ ## Private constructor.
def __init__(self, mesh, geom=0):
- """
- Private constructor
- """
import Python1dPlugin
self.Create(mesh, geom, "Python_1D", "libPython1dEngine.so")
+ ## Define "PythonSplit1D" hypothesis based on the Erwan Adam patch, awaiting equivalent SALOME functionality
+ # @param n for the number of segments that cut an edge
+ # @param func for the python function that calculate the length of all segments
def PythonSplit1D(self, n, func):
- """
- Define "PythonSplit1D" hypothesis based on the Erwan Adam patch, awaiting equivalent SALOME functionality
- \param n for the number of segments that cut an edge
- \param func for the python function that calculate the length of all segments
- """
hyp = self.Hypothesis("PythonSplit1D", [n], "libPython1dEngine.so")
hyp.SetNumberOfSegments(n)
hyp.SetPythonLog10RatioFunction(func)
# Public class: Mesh_Triangle
# ---------------------------
+## Class to define a triangle 2D algorithm
+#
+# More details.
class Mesh_Triangle(Mesh_Algorithm):
- """
- Class to define a triangle 2D algorithm
- """
+ ## Private constructor.
def __init__(self, mesh, geom=0):
- """
- Private constructor
- """
self.Create(mesh, geom, "MEFISTO_2D")
+ ## Define "MaxElementArea" hypothesis to give the maximun area of each triangles
+ # @param area for the maximum area of each triangles
def MaxElementArea(self, area):
- """
- Define "MaxElementArea" hypothesis to give the maximun area of each triangles
- \param area for the maximum area of each triangles
- """
hyp = self.Hypothesis("MaxElementArea", [area])
hyp.SetMaxElementArea(area)
return hyp
+ ## Define "LengthFromEdges" hypothesis to build triangles based on the length of the edges taken from the wire
def LengthFromEdges(self):
- """
- Define "LengthFromEdges" hypothesis to build triangles based on the length of the edges taken from the wire
- """
return self.Hypothesis("LengthFromEdges")
# Public class: Mesh_Quadrangle
# -----------------------------
+## Class to define a quadrangle 2D algorithm
+#
+# More details.
class Mesh_Quadrangle(Mesh_Algorithm):
- """
- Class to define a quadrangle 2D algorithm
- """
+ ## Private constructor.
def __init__(self, mesh, geom=0):
- """
- Private constructor
- """
self.Create(mesh, geom, "Quadrangle_2D")
+ ## Define "QuadranglePreference" hypothesis, forcing construction
+ # of quadrangles if the number of nodes on opposite edges is not the same
+ # in the case where the global number of nodes on edges is even
+ def QuadranglePreference(self):
+ hyp = self.Hypothesis("QuadranglePreference")
+ return hyp
+
# Public class: Mesh_Tetrahedron
# ------------------------------
+## Class to define a tetrahedron 3D algorithm
+#
+# More details.
class Mesh_Tetrahedron(Mesh_Algorithm):
- """
- Class to define a tetrahedron 3D algorithm
- """
+ ## Private constructor.
def __init__(self, mesh, algo, geom=0):
- """
- Private constructor
- """
if algo == NETGEN:
self.Create(mesh, geom, "NETGEN_3D", "libNETGENEngine.so")
elif algo == GHS3D:
import GHS3DPlugin
self.Create(mesh, geom, "GHS3D_3D" , "libGHS3DEngine.so")
+ ## Define "MaxElementVolume" hypothesis to give the maximun volume of each tetrahedral
+ # @param vol for the maximum volume of each tetrahedral
def MaxElementVolume(self, vol):
- """
- Define "MaxElementVolume" hypothesis to give the maximun volume of each tetrahedral
- \param vol for the maximum volume of each tetrahedral
- """
hyp = self.Hypothesis("MaxElementVolume", [vol])
hyp.SetMaxElementVolume(vol)
return hyp
# Public class: Mesh_Hexahedron
# ------------------------------
+## Class to define a hexahedron 3D algorithm
+#
+# More details.
class Mesh_Hexahedron(Mesh_Algorithm):
- """
- Class to define a hexahedron 3D algorithm
- """
+ ## Private constructor.
def __init__(self, mesh, geom=0):
- """
- Private constructor
- """
self.Create(mesh, geom, "Hexa_3D")
+# Public class: Mesh_Netgen
+# ------------------------------
+
+## Class to define a NETGEN-based 2D or 3D algorithm
+# that need no discrete boundary (i.e. independent)
+#
+# More details.
+class Mesh_Netgen(Mesh_Algorithm):
+
+ is3D = 0
+
+ ## Private constructor.
+ def __init__(self, mesh, is3D, geom=0):
+ self.is3D = is3D
+ if is3D:
+ self.Create(mesh, geom, "NETGEN_2D3D", "libNETGENEngine.so")
+ else:
+ self.Create(mesh, geom, "NETGEN_2D", "libNETGENEngine.so")
+
+ ## Define hypothesis containing parameters of the algorithm
+ def Parameters(self):
+ if self.is3D:
+ hyp = self.Hypothesis("NETGEN_Parameters", [], "libNETGENEngine.so")
+ else:
+ hyp = self.Hypothesis("NETGEN_Parameters_2D", [], "libNETGENEngine.so")
+ return hyp
+
# Public class: Mesh
# ==================
+## Class to define a mesh
+#
+# More details.
class Mesh:
- """
- Class to define a mesh
- """
geom = 0
mesh = 0
+ ## Constructor
+ #
+ # Creates mesh on the shape \a geom,
+ # sets GUI name of this mesh to \a name.
+ # @param geom Shape to be meshed
+ # @param name Study name of the mesh
def __init__(self, geom, name=0):
- """
- Constructor
-
- Creates mesh on the shape \a geom,
- sets GUI name of this mesh to \a name.
- \param geom Shape to be meshed
- \param name Study name of the mesh
- """
self.geom = geom
self.mesh = smesh.CreateMesh(geom)
if name == 0:
else:
SetName(self.mesh, name)
+ ## Method that returns the mesh
def GetMesh(self):
- """
- Method that returns the mesh
- """
return self.mesh
+ ## Method that returns the shape associated to the mesh
def GetShape(self):
- """
- Method that returns the shape associated to the mesh
- """
return self.geom
+ ## Returns mesh dimension depending on shape one
+ def MeshDimension(self):
+ shells = geompy.SubShapeAllIDs( self.geom, geompy.ShapeType["SHELL"] )
+ if len( shells ) > 0 :
+ return 3
+ elif geompy.NumberOfFaces( self.geom ) > 0 :
+ return 2
+ elif geompy.NumberOfEdges( self.geom ) > 0 :
+ return 1
+ else:
+ return 0;
+ pass
+
+ ## Creates a segment discretization 1D algorithm.
+ # If the optional \a algo parameter is not sets, this algorithm is REGULAR.
+ # If the optional \a geom parameter is not sets, this algorithm is global.
+ # Otherwise, this algorithm define a submesh based on \a geom subshape.
+ # @param algo values are smesh.REGULAR or smesh.PYTHON for discretization via python function
+ # @param geom If defined, subshape to be meshed
def Segment(self, algo=REGULAR, geom=0):
- """
- Creates a segment discretization 1D algorithm.
- If the optional \a algo parameter is not sets, this algorithm is REGULAR.
- If the optional \a geom parameter is not sets, this algorithm is global.
- Otherwise, this algorithm define a submesh based on \a geom subshape.
- \param algo values are smesh.REGULAR or smesh.PYTHON for discretization via python function
- \param geom If defined, subshape to be meshed
- """
+ ## if Segment(geom) is called by mistake
+ if ( isinstance( algo, geompy.GEOM._objref_GEOM_Object)):
+ algo, geom = geom, algo
+ pass
if algo == REGULAR:
return Mesh_Segment(self, geom)
elif algo == PYTHON:
return Mesh_Segment_Python(self, geom)
else:
- return Mesh_Segment(self, algo)
+ return Mesh_Segment(self, geom)
+ ## Creates a triangle 2D algorithm for faces.
+ # If the optional \a geom parameter is not sets, this algorithm is global.
+ # Otherwise, this algorithm define a submesh based on \a geom subshape.
+ # @param geom If defined, subshape to be meshed
def Triangle(self, geom=0):
- """
- Creates a triangle 2D algorithm for faces.
- If the optional \a geom parameter is not sets, this algorithm is global.
- Otherwise, this algorithm define a submesh based on \a geom subshape.
- \param geom If defined, subshape to be meshed
- """
return Mesh_Triangle(self, geom)
+ ## Creates a quadrangle 2D algorithm for faces.
+ # If the optional \a geom parameter is not sets, this algorithm is global.
+ # Otherwise, this algorithm define a submesh based on \a geom subshape.
+ # @param geom If defined, subshape to be meshed
def Quadrangle(self, geom=0):
- """
- Creates a quadrangle 2D algorithm for faces.
- If the optional \a geom parameter is not sets, this algorithm is global.
- Otherwise, this algorithm define a submesh based on \a geom subshape.
- \param geom If defined, subshape to be meshed
- """
return Mesh_Quadrangle(self, geom)
+ ## Creates a tetrahedron 3D algorithm for solids.
+ # The parameter \a algo permits to choice the algorithm: NETGEN or GHS3D
+ # If the optional \a geom parameter is not sets, this algorithm is global.
+ # Otherwise, this algorithm define a submesh based on \a geom subshape.
+ # @param algo values are: smesh.NETGEN, smesh.GHS3D
+ # @param geom If defined, subshape to be meshed
def Tetrahedron(self, algo, geom=0):
- """
- Creates a tetrahedron 3D algorithm for solids.
- The parameter \a algo permits to choice the algorithm: NETGEN or GHS3D
- If the optional \a geom parameter is not sets, this algorithm is global.
- Otherwise, this algorithm define a submesh based on \a geom subshape.
- \param algo values are: smesh.NETGEN, smesh.GHS3D
- \param geom If defined, subshape to be meshed
- """
+ ## if Tetrahedron(geom) is called by mistake
+ if ( isinstance( algo, geompy.GEOM._objref_GEOM_Object)):
+ algo, geom = geom, algo
+ pass
return Mesh_Tetrahedron(self, algo, geom)
+ ## Creates a hexahedron 3D algorithm for solids.
+ # If the optional \a geom parameter is not sets, this algorithm is global.
+ # Otherwise, this algorithm define a submesh based on \a geom subshape.
+ # @param geom If defined, subshape to be meshed
def Hexahedron(self, geom=0):
- """
- Creates a hexahedron 3D algorithm for solids.
- If the optional \a geom parameter is not sets, this algorithm is global.
- Otherwise, this algorithm define a submesh based on \a geom subshape.
- \param geom If defined, subshape to be meshed
- """
return Mesh_Hexahedron(self, geom)
+ ## Creates a NETGEN-based 2D or 3D independent algorithm (i.e. needs no
+ # discrete boundary).
+ # If the optional \a geom parameter is not sets, this algorithm is global.
+ # Otherwise, this algorithm defines a submesh based on \a geom subshape.
+ # @param is3D If 0 then algorithm is 2D, otherwise 3D
+ # @param geom If defined, subshape to be meshed
+ def Netgen(self, is3D, geom=0):
+ return Mesh_Netgen(self, is3D, geom)
+
+ ## Compute the mesh and return the status of the computation
def Compute(self):
- """
- Compute the mesh and return the status of the computation
- """
- b = smesh.Compute(self.mesh, self.geom)
+ ok = smesh.Compute(self.mesh, self.geom)
+ if not ok:
+ errors = smesh.GetAlgoState( self.mesh, self.geom )
+ allReasons = ""
+ for err in errors:
+ if err.isGlobalAlgo:
+ glob = " global "
+ else:
+ glob = " local "
+ pass
+ dim = str(err.algoDim)
+ if err.name == SMESH.MISSING_ALGO:
+ reason = glob + dim + "D algorithm is missing"
+ elif err.name == SMESH.MISSING_HYPO:
+ name = '"' + err.algoName + '"'
+ reason = glob + dim + "D algorithm " + name + " misses " + dim + "D hypothesis"
+ else:
+ reason = "Global \"Not Conform mesh allowed\" hypothesis is missing"
+ pass
+ if allReasons != "":
+ allReasons += "\n"
+ pass
+ allReasons += reason
+ pass
+ if allReasons != "":
+ print '"' + GetName(self.mesh) + '"',"not computed:"
+ print allReasons
+ pass
+ pass
if salome.sg.hasDesktop():
smeshgui = salome.ImportComponentGUI("SMESH")
smeshgui.Init(salome.myStudyId)
- smeshgui.SetMeshIcon( salome.ObjectToID( self.mesh ), b )
+ smeshgui.SetMeshIcon( salome.ObjectToID( self.mesh ), ok )
salome.sg.updateObjBrowser(1)
- return b
-
+ pass
+ return ok
+
+ ## Compute tetrahedral mesh using AutomaticLength + MEFISTO + NETGEN
+ # The parameter \a fineness [0.-1.] defines mesh fineness
+ def AutomaticTetrahedralization(self, fineness=0):
+ dim = self.MeshDimension()
+ # assign hypotheses
+ self.RemoveGlobalHypotheses()
+ self.Segment().AutomaticLength(fineness)
+ if dim > 1 :
+ self.Triangle().LengthFromEdges()
+ pass
+ if dim > 2 :
+ self.Tetrahedron(NETGEN)
+ pass
+ return self.Compute()
+
+ ## Compute hexahedral mesh using AutomaticLength + Quadrangle + Hexahedron
+ # The parameter \a fineness [0.-1.] defines mesh fineness
+ def AutomaticHexahedralization(self, fineness=0):
+ dim = self.MeshDimension()
+ # assign hypotheses
+ self.RemoveGlobalHypotheses()
+ self.Segment().AutomaticLength(fineness)
+ if dim > 1 :
+ self.Quadrangle()
+ pass
+ if dim > 2 :
+ self.Hexahedron()
+ pass
+ return self.Compute()
+
+ ## Removes all global hypotheses
+ def RemoveGlobalHypotheses(self):
+ current_hyps = self.mesh.GetHypothesisList( self.geom )
+ for hyp in current_hyps:
+ self.mesh.RemoveHypothesis( self.geom, hyp )
+ pass
+ pass
+
+ ## Create a mesh group based on geometric object \a grp
+ # and give a \a name, if this parameter is not defined
+ # the name is the same as the geometric group name
+ # @param grp is a geometric group, a vertex, an edge, a face or a solid
+ # @param name is the name of the mesh group
def Group(self, grp, name=""):
- """
- Create a mesh group based on geometric object \a grp
- and give a \a name, if this parameter is not defined
- the name is the same as the geometric group name
- \param grp is a geometric group, a vertex, an edge, a face or a solid
- \param name is the name of the mesh group
- """
if name == "":
name = grp.GetName()
elif tgeo == "SHELL":
type = SMESH.VOLUME
elif tgeo == "COMPOUND":
+ if len( geompy.GetObjectIDs( grp )) == 0:
+ print "Mesh.Group: empty geometric group", GetName( grp )
+ return 0
tgeo = geompy.GetType(grp)
if tgeo == geompy.ShapeType["VERTEX"]:
type = SMESH.NODE
else:
return self.mesh.CreateGroupFromGEOM(type, name, grp)
+ ## Export the mesh in a file with the MED format and choice the \a version of MED format
+ # @param f is the file name
+ # @param version values are SMESH.MED_V2_1, SMESH.MED_V2_2
def ExportToMED(self, f, version, opt=0):
- """
- Export the mesh in a file with the MED format and choice the \a version of MED format
- \param f is the file name
- \param version values are smesh.MED_V2_1, smesh.MED_V2_2
- """
self.mesh.ExportToMED(f, opt, version)
+ ## Export the mesh in a file with the MED format
+ # @param f is the file name
def ExportMED(self, f, opt=0):
- """
- Export the mesh in a file with the MED format
- \param f is the file name
- """
self.mesh.ExportMED(f, opt)
+ ## Export the mesh in a file with the DAT format
+ # @param f is the file name
def ExportDAT(self, f):
- """
- Export the mesh in a file with the DAT format
- \param f is the file name
- """
self.mesh.ExportDAT(f)
+ ## Export the mesh in a file with the UNV format
+ # @param f is the file name
def ExportUNV(self, f):
- """
- Export the mesh in a file with the UNV format
- \param f is the file name
- """
self.mesh.ExportUNV(f)
+ ## Export the mesh in a file with the STL format
+ # @param f is the file name
+ # @param ascii defined the kind of file contents
def ExportSTL(self, f, ascii=1):
- """
- Export the mesh in a file with the STL format
- \param f is the file name
- \param ascii defined the kind of file contents
- """
self.mesh.ExportSTL(f, ascii)