<?xml version='1.0' encoding='us-ascii'?>
<!DOCTYPE meshers PUBLIC "" "desktop.dtd">
-<!--
- Copyright (C) 2007-2014 CEA/DEN, EDF R&D, OPEN CASCADE
- Copyright (C) 2003-2007 OPEN CASCADE, EADS/CCR, LIP6, CEA/DEN,
- CEDRAT, EDF R&D, LEG, PRINCIPIA R&D, BUREAU VERITAS
-
- This library is free software; you can redistribute it and/or
- modify it under the terms of the GNU Lesser General Public
- License as published by the Free Software Foundation; either
- version 2.1 of the License, or (at your option) any later version.
-
- This library is distributed in the hope that it will be useful,
- but WITHOUT ANY WARRANTY; without even the implied warranty of
- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
- Lesser General Public License for more details.
-
- You should have received a copy of the GNU Lesser General Public
- 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.salome-platform.org/ or email : webmaster.salome@opencascade.com
-
--->
-
-<!-- GUI customization for MESH component -->
+<!-- Attributes of hypotheses/algorithms:
+
+ type - string identifier of a hyp.
+ label-id - hypothesis type name in Create Mesh dialog.
+ icon-id - not used.
+ group-id - (optional) integer ID of a group the hyp belongs to in Create Mesh dialog;
+ by default the hyp is in the last group.
+ priority - (optional) priority within the group; by default the hyp is last in group.
+ dim - dimension; defines a tab page in Create Mesh dialog.
+ context - (optional) allowed context: [LOCAL, GLOBAL, ANY(default)]. LOCAL - the hyp
+ can be only local (on sub-mesh). GLOBAL - the hyp can be only GLOBAL (on mesh).
+ auxiliary - (optional) Boolean. Is additional hyp or not. Default is "false".
+ hypos - list of types of compatible hyps of the algorithm.
+ opt-hypos = (optional) list of types of compatible ADDITIONAL hyps of the algorithm.
+ output - geometry of elements generated by the algo. Used to define compatible algos of
+ different dimensions. Compatible algos have equal geometries in "input" and "output".
+ input - geometry of elements accepted by algorithm input. Used to define compatible algos of
+ different dimensions. Compatible algos have equal geometries in "input" and "output".
+ need-hyp - (optional) Boolean. Does the algo require a hypothesis or not. Default is "false".
+ need-geom - (optional) [true, fasle, never]. Can the algo work w/o geometry or not.
+ Default is "true". "never" means that the algo can't work with geometry.
+ support-submeshes - (optional) Boolean. Does an multi-dimensional algo support sub-meshes.
+ Default is "false".
+
+ -->
<meshers>
-<meshers-group name="Standard Meshers"
- resources="StdMeshers"
+<meshers-group name ="Standard Meshers"
+ resources ="StdMeshers"
idl-module="StdMeshers"
server-lib="StdMeshersEngine"
- gui-lib="StdMeshersGUI">
+ gui-lib ="StdMeshersGUI">
<hypotheses>
<hypothesis type ="SegmentLengthAroundVertex"
<hypothesis type ="LocalLength"
label-id ="Local Length"
icon-id ="mesh_hypo_length.png"
+ group-id ="0"
+ priority ="20"
dim ="1"/>
<hypothesis type ="MaxLength"
label-id ="Max Size"
icon-id ="mesh_hypo_length.png"
+ group-id ="2"
+ priority ="50"
dim ="1"/>
<hypothesis type ="Arithmetic1D"
- label-id ="Arithmetic 1D"
+ label-id ="Arithmetic Progression"
icon-id ="mesh_hypo_length.png"
+ group-id ="1"
+ priority ="10"
dim ="1"/>
<hypothesis type ="GeometricProgression"
label-id ="Geometric Progression"
icon-id ="mesh_hypo_length.png"
+ group-id ="1"
+ priority ="20"
dim ="1"/>
<hypothesis type ="FixedPoints1D"
- label-id ="Fixed Points 1D"
+ label-id ="Fixed Points"
icon-id ="mesh_hypo_length.png"
+ group-id ="2"
+ priority ="10"
dim ="1"/>
<hypothesis type ="StartEndLength"
label-id ="Start and End Length"
icon-id ="mesh_hypo_length.png"
+ group-id ="1"
+ priority ="30"
dim ="1"/>
<hypothesis type ="NumberOfSegments"
- label-id ="Nb. Segments"
+ label-id ="Number of Segments"
icon-id ="mesh_hypo_segment.png"
+ group-id ="0"
+ priority ="10"
dim ="1"/>
<hypothesis type ="Deflection1D"
- label-id ="Deflection 1D"
+ label-id ="Deflection"
icon-id ="mesh_hypo_length.png"
+ group-id ="2"
+ priority ="20"
dim ="1"/>
<hypothesis type ="Adaptive1D"
label-id ="Adaptive"
icon-id ="mesh_hypo_length.png"
+ group-id ="2"
+ priority ="30"
dim ="1"/>
<hypothesis type ="Propagation"
<hypothesis type ="AutomaticLength"
label-id ="Automatic Length"
icon-id ="mesh_hypo_length.png"
+ group-id ="2"
+ priority ="40"
dim ="1"/>
<hypothesis type ="LengthFromEdges"
label-id ="Quadratic Mesh"
icon-id ="mesh_algo_quad.png"
dim ="1"
- context ="GLOBAL"
auxiliary="true"/>
<hypothesis type ="MaxElementArea"
<hypothesis type ="CartesianParameters3D"
label-id ="Body Fitting Parameters"
icon-id ="mesh_hypo_length.png"
- context ="GLOBAL"
dim ="3"/>
</hypotheses>
label-id ="Segments around Vertex"
icon-id ="mesh_algo_regular.png"
hypos ="SegmentLengthAroundVertex"
- output ="VERTEX"
+ output ="NODE"
need-hyp ="true"
dim ="0"/>
<algorithm type ="Regular_1D"
label-id ="Wire Discretisation"
icon-id ="mesh_algo_regular.png"
+ group-id ="0"
+ priority ="10"
hypos ="Adaptive1D,LocalLength,MaxLength,Arithmetic1D,GeometricProgression,StartEndLength,NumberOfSegments,Deflection1D,AutomaticLength,FixedPoints1D"
opt-hypos="Propagation,PropagOfDistribution,QuadraticMesh"
- input ="VERTEX"
+ input ="NODE"
output ="EDGE"
need-hyp ="true"
dim ="1">
<algorithm type ="CompositeSegment_1D"
label-id ="Composite Side Discretisation"
icon-id ="mesh_algo_regular.png"
+ group-id ="0"
+ priority ="20"
hypos ="Adaptive1D,LocalLength,MaxLength,Arithmetic1D,GeometricProgression,StartEndLength,NumberOfSegments,Deflection1D,AutomaticLength,FixedPoints1D"
opt-hypos="Propagation,PropagOfDistribution,QuadraticMesh"
- input ="VERTEX"
+ input ="NODE"
output ="EDGE"
need-hyp ="true"
dim ="1">
</algorithm>
<algorithm type ="@MEFISTO2D_NAME@"
- label-id ="Triangle (Mefisto)"
+ label-id ="Triangle: Mefisto"
icon-id ="mesh_algo_mefisto.png"
+ group-id ="1"
+ priority ="40"
hypos ="LengthFromEdges,MaxElementArea"
opt-hypos ="ViscousLayers2D"
input ="EDGE"
<algo>MEFISTO_2D=Triangle(algo=smeshBuilder.MEFISTO)</algo>
<hypo>LengthFromEdges=LengthFromEdges()</hypo>
<hypo>MaxElementArea=MaxElementArea(SetMaxElementArea())</hypo>
- <hypo>ViscousLayers2D=ViscousLayers2D(SetTotalThickness(),SetNumberLayers(),SetStretchFactor(),SetEdges(1),SetEdges(2))</hypo>
+ <hypo>ViscousLayers2D=ViscousLayers2D(SetTotalThickness(),SetNumberLayers(),SetStretchFactor(),SetEdges(1),SetEdges(2),SetGroupName())</hypo>
</python-wrap>
</algorithm>
<algorithm type ="Quadrangle_2D"
- label-id ="Quadrangle (Mapping)"
+ label-id ="Quadrangle: Mapping"
icon-id ="mesh_algo_quad.png"
+ group-id ="0"
+ priority ="10"
hypos ="QuadrangleParams"
opt-hypos="ViscousLayers2D"
input ="EDGE"
dim ="2">
<python-wrap>
<algo>Quadrangle_2D=Quadrangle(algo=smeshBuilder.QUADRANGLE)</algo>
- <hypo>QuadrangleParams=QuadrangleParameters(SetQuadType(),SetTriaVertex(),SetEnforcedNodes(1),SetEnforcedNodes(2))</hypo>
- <hypo>ViscousLayers2D=ViscousLayers2D(SetTotalThickness(),SetNumberLayers(),SetStretchFactor(),SetIgnoreEdges())</hypo>
+ <hypo>QuadrangleParams=QuadrangleParameters(SetQuadType(),SetTriaVertex(),SetEnforcedNodes(1),SetEnforcedNodes(2),SetCorners())</hypo>
+ <hypo>ViscousLayers2D=ViscousLayers2D(SetTotalThickness(),SetNumberLayers(),SetStretchFactor(),SetEdges(1),SetEdges(2),SetGroupName())</hypo>
+ </python-wrap>
+ </algorithm>
+
+ <algorithm type ="QuadFromMedialAxis_1D2D"
+ label-id ="Quadrangle: Medial Axis Projection"
+ icon-id ="mesh_algo_quad.png"
+ group-id ="0"
+ priority ="20"
+ hypos ="NumberOfLayers2D, LayerDistribution2D"
+ opt-hypos="ViscousLayers2D"
+ input ="EDGE"
+ output ="QUAD"
+ dim ="2">
+ <python-wrap>
+ <algo>QuadFromMedialAxis_1D2D=Quadrangle(algo=smeshBuilder.QUAD_MA_PROJ)</algo>
+ <hypo>ViscousLayers2D=ViscousLayers2D(SetTotalThickness(),SetNumberLayers(),SetStretchFactor(),SetEdges(1),SetEdges(2),SetGroupName())</hypo>
+ <hypo>NumberOfLayers2D=NumberOfLayers(SetNumberOfLayers())</hypo>
+ </python-wrap>
+ </algorithm>
+
+ <algorithm type ="PolygonPerFace_2D"
+ label-id ="Polygon per Face"
+ icon-id ="mesh_algo_polygon.png"
+ group-id ="2"
+ priority ="40"
+ opt-hypos="ViscousLayers2D"
+ input ="EDGE"
+ output ="POLYGON,QUAD,TRIA"
+ dim ="2">
+ <python-wrap>
+ <algo>PolygonPerFace_2D=Polygon()</algo>
+ <hypo>ViscousLayers2D=ViscousLayers2D(SetTotalThickness(),SetNumberLayers(),SetStretchFactor(),SetEdges(1),SetEdges(2),SetGroupName())</hypo>
+ </python-wrap>
+ </algorithm>
+
+ <algorithm type ="PolyhedronPerSolid_3D"
+ label-id ="Polyhedron per Solid"
+ icon-id ="mesh_algo_polygon.png"
+ opt-hypos="ViscousLayers"
+ input ="POLYGON,QUAD,TRIA,EDGE"
+ dim ="3">
+ <python-wrap>
+ <algo>PolyhedronPerSolid_3D=Polyhedron()</algo>
+ <hypo>ViscousLayers=ViscousLayers(SetTotalThickness(),SetNumberLayers(),SetStretchFactor(),SetIgnoreEdges())</hypo>
</python-wrap>
</algorithm>
<algorithm type ="Hexa_3D"
label-id ="Hexahedron (i,j,k)"
icon-id ="mesh_algo_hexa.png"
+ group-id ="0"
+ priority ="10"
input ="QUAD"
output ="HEXA,PENTA"
need-geom="false"
dim ="3">
<python-wrap>
<algo>Hexa_3D=Hexahedron(algo=smeshBuilder.Hexa)</algo>
- <hypo>ViscousLayers=ViscousLayers(SetTotalThickness(),SetNumberLayers(),SetStretchFactor(),SetIgnoreFaces())</hypo>
+ <hypo>ViscousLayers=ViscousLayers(SetTotalThickness(),SetNumberLayers(),SetStretchFactor(),SetFaces(1),SetFaces(2),SetMethod(),SetGroupName())</hypo>
</python-wrap>
</algorithm>
<algorithm type ="Projection_1D"
label-id="Projection 1D"
icon-id ="mesh_algo_regular.png"
+ group-id="1"
+ priority="10"
hypos ="ProjectionSource1D"
output ="EDGE"
need-hyp="true"
<algorithm type ="Projection_2D"
label-id="Projection 2D"
icon-id ="mesh_algo_quad.png"
+ group-id="2"
+ priority="30"
input ="EDGE"
hypos ="ProjectionSource2D"
output ="QUAD,TRIA"
<algorithm type ="Projection_1D2D"
label-id="Projection 1D-2D"
icon-id ="mesh_algo_quad.png"
+ group-id="2"
+ priority="20"
hypos ="ProjectionSource2D"
output ="QUAD,TRIA"
need-hyp="true"
<algorithm type ="Projection_3D"
label-id="Projection 3D"
icon-id ="mesh_algo_hexa.png"
+ group-id="2"
+ priority="20"
hypos ="ProjectionSource3D"
input ="QUAD,TRIA"
need-hyp="true"
<algorithm type ="Import_1D"
label-id="Import 1D Elements from Another Mesh"
icon-id ="mesh_algo_regular.png"
+ group-id="1"
+ priority="20"
hypos ="ImportSource1D"
output ="EDGE"
need-hyp="true"
</algorithm>
<algorithm type ="Import_1D2D"
- label-id ="Import 2D Elements from Another Mesh"
+ label-id ="Import 1D-2D Elements from Another Mesh"
icon-id ="mesh_algo_quad.png"
+ group-id ="2"
+ priority ="50"
hypos ="ImportSource2D"
output ="QUAD,TRIA"
support-submeshes="false"
</algorithm>
<algorithm type ="Prism_3D"
- label-id="3D Extrusion"
+ label-id="Extrusion 3D"
icon-id ="mesh_algo_hexa.png"
- input ="QUAD,TRIA"
+ group-id="2"
+ priority="10"
+ input ="EDGE"
output ="HEXA,PENTA,OCTA,POLYHEDRON"
dim ="3">
<python-wrap>
</algorithm>
<algorithm type ="RadialPrism_3D"
- label-id="Radial Prism 3D"
+ label-id="Radial Prism"
icon-id ="mesh_algo_hexa.png"
+ group-id="2"
+ priority="30"
hypos ="NumberOfLayers, LayerDistribution"
input ="QUAD,TRIA"
output ="HEXA,PENTA,OCTA,POLYHEDRON"
<algorithm type ="UseExisting_1D"
label-id="Use Edges to be Created Manually"
icon-id ="mesh_algo_regular.png"
- input ="VERTEX"
+ group-id="1"
+ priority="30"
+ input ="NODE"
output ="EDGE"
dim ="1">
<python-wrap>
<algorithm type ="UseExisting_2D"
label-id="Use Faces to be Created Manually"
icon-id ="mesh_algo_quad.png"
+ group-id="2"
+ priority="60"
input ="EDGE"
output ="QUAD,TRIA"
dim ="2">
</algorithm>
<algorithm type ="RadialQuadrangle_1D2D"
- label-id="Radial Quadrangle 1D2D"
+ label-id="Radial Quadrangle 1D-2D"
icon-id ="mesh_algo_quad.png"
+ group-id="2"
+ priority="10"
hypos ="NumberOfLayers2D, LayerDistribution2D"
input ="EDGE"
output ="QUAD"
<algorithm type ="Cartesian_3D"
label-id ="Body Fitting"
icon-id ="mesh_algo_hexa.png"
+ group-id ="0"
+ priority ="20"
hypos ="CartesianParameters3D"
support-submeshes="false"
output ="HEXA"
need-hyp ="true"
- context ="GLOBAL"
dim ="3">
<python-wrap>
<algo>Cartesian_3D=BodyFitted()</algo>
<hypotheses-set-group>
- <hypotheses-set name="Automatic Tetrahedralization"
- hypos="MaxLength"
- algos="Regular_1D, @MEFISTO2D_NAME@, NETGEN_3D"/>
+ <hypotheses-set name="Tetrahedralization"
+ use-common-size="true"
+ hypos="MG-CADSurf Parameters"
+ algos="MG-CADSurf, MG-Tetra"
+ alt-hypos="NETGEN_Parameters"
+ alt-algos="NETGEN_2D3D"
+ intern-edge-hypos="LocalLength"
+ intern-edge-algos="Regular_1D"/>
- <hypotheses-set name="Automatic Hexahedralization"
+ <hypotheses-set name="Mapped Hexahedralization"
hypos="NumberOfSegments"
algos="Regular_1D, Quadrangle_2D, Hexa_3D"/>
- <hypotheses-set name="Automatic Triangulation"
- hypos="MaxLength"
- algos="Regular_1D, @MEFISTO2D_NAME@"/>
-
- <hypotheses-set name="Automatic Quadrangulation"
+ <hypotheses-set name="Free Hexahedralization"
+ use-common-size="true"
+ quad-dominated="true"
+ hypos="MG-CADSurf Parameters"
+ algos="MG-CADSurf, MG-Hexa"
+ alt-hypos="None"
+ alt-algos="None"
+ intern-edge-hypos="LocalLength"
+ intern-edge-algos="Regular_1D"/>
+
+ <hypotheses-set name="Triangulation"
+ use-common-size="true"
+ hypos="MG-CADSurf Parameters"
+ algos="MG-CADSurf"
+ alt-hypos="NETGEN_Parameters_2D"
+ alt-algos="NETGEN_2D"/>
+
+ <hypotheses-set name="Mapped Quadrangulation"
hypos="NumberOfSegments"
algos="Regular_1D, Quadrangle_2D"/>
+ <hypotheses-set name="Free Quadrangulation"
+ use-common-size="true"
+ quad-dominated="true"
+ hypos="MG-CADSurf Parameters"
+ algos="MG-CADSurf"
+ alt-hypos="NETGEN_Parameters_2D"
+ alt-algos="NETGEN_2D"/>
+
</hypotheses-set-group>
</meshers>