smesh/idl/SMESH_BasicHypothesis.idl
2022-05-05 16:51:14 +03:00

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// Copyright (C) 2007-2022 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
//
// File : SMESH_BasicHypothesis.idl
// Author : Paul RASCLE, EDF
//
#ifndef _SMESH_BASICHYPOTHESIS_IDL_
#define _SMESH_BASICHYPOTHESIS_IDL_
#include "SALOME_Exception.idl"
#include "SMESH_Hypothesis.idl"
#include "SMESH_Mesh.idl"
/*!
* StdMeshers: interfaces to standard hypotheses and algorithms
*/
module StdMeshers
{
/*!
* StdMeshers_LocalLength: interface of "Average length" hypothesis
*/
interface StdMeshers_LocalLength : SMESH::SMESH_Hypothesis
{
/*!
* Sets <length> parameter value
*/
void SetLength(in double length)
raises (SALOME::SALOME_Exception);
/*!
* Sets <precision> parameter value
*
* Precision parameter is used to allow rounding a number of segments,
* calculated from the edge length and average length of segment,
* to the lower integer, if this value outstands from it in bounds of the precision.
* Otherwise, the number of segments is rounded to the higher integer.
* Use value 0.5 to provide rounding to the nearest integer,
* 1.0 for the lower integer, 0.0 for the higher integer.
* Default value is 1e-07. In old studies, restored from file,
* this value will be set to zero, what corresponds to the old behaviour.
*/
void SetPrecision(in double precision)
raises (SALOME::SALOME_Exception);
/*!
* Returns <length> parameter value
*/
double GetLength();
/*!
* Returns <precision> parameter value
*/
double GetPrecision();
};
/*!
* StdMeshers_MaxLength: interface of "Max length" hypothesis
*/
interface StdMeshers_MaxLength : SMESH::SMESH_Hypothesis
{
/*!
* Sets <length> parameter value
*/
void SetLength(in double length)
raises (SALOME::SALOME_Exception);
/*!
* Returns <length> parameter value
*/
double GetLength();
/*!
* Returns true if preestemated length is defined
*/
boolean HavePreestimatedLength();
/*!
* Returns preestemated length
*/
double GetPreestimatedLength();
/*!
* Sets preestemated length
*/
void SetPreestimatedLength(in double length);
/*!
* Sets boolean parameter enabling/desabling usage of length computed
* basing on size of bounding box of shape to mesh
*/
void SetUsePreestimatedLength(in boolean toUse);
/*!
* Returns value of boolean parameter enabling/desabling usage of length computed
* basing on size of bounding box of shape to mesh
*/
boolean GetUsePreestimatedLength();
};
/*!
* StdMeshers_AutomaticLength: interface of "Automatic length" hypothesis
*/
interface StdMeshers_AutomaticLength : SMESH::SMESH_Hypothesis
{
/*!
* Sets Fineness parameter value
*/
void SetFineness(in double theFineness)
raises (SALOME::SALOME_Exception);
/*!
* Returns <Fineness> parameter value
*/
double GetFineness();
};
/*!
* Common interface of 1D hypotheses that can be reversed
*/
interface Reversible1D
{
/*!
* Set list of edges to reverse
*/
void SetReversedEdges( in SMESH::long_array list );
/*!
* Returns list of edges to reverse
*/
SMESH::long_array GetReversedEdges();
/*!
* Set entry of the main object
*/
void SetObjectEntry( in string entry );
/*!
* Get the entry of the main object
*/
string GetObjectEntry();
};
/*!
* StdMeshers_NumberOfSegments: interface of "Nb. Segments" hypothesis
*/
interface StdMeshers_NumberOfSegments : SMESH::SMESH_Hypothesis, Reversible1D
{
/*!
* Builds and returns point distribution according to passed density function
*/
SMESH::double_array BuildDistributionExpr( in string func, in long nbSeg, in long conv )
raises (SALOME::SALOME_Exception);
SMESH::double_array BuildDistributionTab( in SMESH::double_array func, in long nbSeg, in long conv )
raises (SALOME::SALOME_Exception);
/*!
* Sets <number of segments> parameter value
*/
void SetNumberOfSegments(in SMESH::smIdType segmentsNumber)
raises (SALOME::SALOME_Exception);
/*!
* Returns <number of segments> parameter value
*/
long GetNumberOfSegments();
/*!
* Sets <distribution type> parameter value
*/
void SetDistrType(in long typ)
raises (SALOME::SALOME_Exception);
/*!
* Returns <distribution type> parameter value
*/
long GetDistrType();
/*!
* Sets <scale factor> parameter value
*/
void SetScaleFactor(in double scaleFactor)
raises (SALOME::SALOME_Exception);
/*!
* Returns <scale factor> parameter value
*/
double GetScaleFactor()
raises (SALOME::SALOME_Exception);
/*!
* Sets <table function> parameter value for distribution DT_TabFunc
*/
void SetTableFunction(in SMESH::double_array table)
raises (SALOME::SALOME_Exception);
/*!
* Returns <table function> parameter value for distribution DT_TabFunc
*/
SMESH::double_array GetTableFunction()
raises (SALOME::SALOME_Exception);
/*!
* Sets <expression function> parameter value for distribution DT_ExprFunc
*/
void SetExpressionFunction(in string expr)
raises (SALOME::SALOME_Exception);
/*!
* Returns <expression function> parameter value for distribution DT_ExprFunc
*/
string GetExpressionFunction()
raises (SALOME::SALOME_Exception);
/*!
* Sets <conversion mode> parameter value for functional distributions
*/
void SetConversionMode(in long conv )
raises (SALOME::SALOME_Exception);
/*!
* Returns <conversion mode> parameter value for functional distributions
*/
long ConversionMode()
raises (SALOME::SALOME_Exception);
};
/*!
* StdMeshers_Arithmetic1D: interface of "Arithmetic 1D" hypothesis
*/
interface StdMeshers_Arithmetic1D : SMESH::SMESH_Hypothesis, Reversible1D
{
/*!
* Sets <start segment length> or <end segment length> parameter value
* * OBSOLETE *. Avoid such a way of interface design
* * It is recommended to dedicate a method to each parameter.
*/
void SetLength(in double length, in boolean isStartLength)
raises (SALOME::SALOME_Exception);
/*!
* Sets <start segment length> parameter value
*/
void SetStartLength(in double length)
raises (SALOME::SALOME_Exception);
/*!
* Sets <end segment length> parameter value
*/
void SetEndLength(in double length)
raises (SALOME::SALOME_Exception);
/*!
* Returns <start segment length> or <end segment length> parameter value
*/
double GetLength(in boolean isStartLength);
};
/*!
* StdMeshers_Arithmetic1D: interface of "Geometric 1D" hypothesis
*/
interface StdMeshers_Geometric1D : SMESH::SMESH_Hypothesis, Reversible1D
{
/*!
* Sets length of the first segment
*/
void SetStartLength(in double length)
raises (SALOME::SALOME_Exception);
/*!
* Sets value of Common Ratio
*/
void SetCommonRatio(in double factor)
raises (SALOME::SALOME_Exception);
/*!
* Returns length of the first segment
*/
double GetStartLength();
/*!
* Returns value of Common Ratio
*/
double GetCommonRatio();
};
/*!
* StdMeshers_MaxElementArea: interface of "Max. Triangle Area" hypothesis
*/
interface StdMeshers_MaxElementArea : SMESH::SMESH_Hypothesis
{
/*!
* Sets <maximum element area> parameter value
*/
void SetMaxElementArea(in double area)
raises (SALOME::SALOME_Exception);
/*!
* Returns <maximum element area> parameter value
*/
double GetMaxElementArea();
};
/*!
* StdMeshers_LengthFromEdges: interface of "Length From Edges (2D Hyp. for Triangulator)" hypothesis
*/
interface StdMeshers_LengthFromEdges : SMESH::SMESH_Hypothesis
{
/*!
* Sets <mode> parameter value
*/
void SetMode(in long mode)
raises (SALOME::SALOME_Exception);
/*!
* Returns <mode> parameter value
*/
long GetMode();
};
/*!
* StdMeshers_StartEndLength: interface of "Start and End Length" hypothesis
*/
interface StdMeshers_StartEndLength : SMESH::SMESH_Hypothesis, Reversible1D
{
/*!
* Sets <start segment length> or <end segment length> parameter value
* * OBSOLETE *. Avoid such a way of interface design.
* * It is recommended to dedicate a method to each parameter.
*/
void SetLength(in double length, in boolean isStartLength)
raises (SALOME::SALOME_Exception);
/*!
* Sets <start segment length> parameter value
*/
void SetStartLength(in double length)
raises (SALOME::SALOME_Exception);
/*!
* Sets <end segment length> parameter value
*/
void SetEndLength(in double length)
raises (SALOME::SALOME_Exception);
/*!
* Returns <start segment length> or <end segment length> parameter value
*/
double GetLength(in boolean isStartLength);
};
/*!
* StdMeshers_Deflection1D: interface of "Deflection 1D" hypothesis
*/
interface StdMeshers_Deflection1D : SMESH::SMESH_Hypothesis
{
/*!
* Sets <deflection> parameter value
*/
void SetDeflection(in double deflection)
raises (SALOME::SALOME_Exception);
/*!
* Returns <deflection> parameter value
*/
double GetDeflection();
};
/*!
* StdMeshers_FixedPoints1D: interface of "Fixed points 1D" hypothesis
*/
interface StdMeshers_FixedPoints1D : SMESH::SMESH_Hypothesis, Reversible1D
{
/*!
* Sets some points on edge using parameter on curve from 0 to 1
* (additionally it is neecessary to check orientation of edges and
* create list of reversed edges if it is needed) and sets numbers
* of segments between given points (default values are equals 1)
*/
void SetPoints(in SMESH::double_array listParams)
raises (SALOME::SALOME_Exception);
void SetNbSegments(in SMESH::smIdType_array listNbSeg)
raises (SALOME::SALOME_Exception);
/*!
* Returns list of point's parameters
*/
SMESH::double_array GetPoints();
/*!
* Returns list of numbers of segments
*/
SMESH::smIdType_array GetNbSegments();
};
/*!
* StdMeshers_Adaptive1D: interface of "Adaptive" hypothesis
*/
interface StdMeshers_Adaptive1D : SMESH::SMESH_Hypothesis
{
/*!
* Sets minimal allowed segment length
*/
void SetMinSize(in double minSegLen) raises (SALOME::SALOME_Exception);
double GetMinSize();
/*!
* Sets maximal allowed segment length
*/
void SetMaxSize(in double maxSegLen) raises (SALOME::SALOME_Exception);
double GetMaxSize();
/*!
* Sets <deflection> parameter value,
* i.e. a maximal allowed distance between a segment and an edge.
*/
void SetDeflection(in double deflection) raises (SALOME::SALOME_Exception);
double GetDeflection();
};
/*!
* StdMeshers_MaxElementVolume: interface of "Max. Hexahedron or Tetrahedron Volume" hypothesis
*/
interface StdMeshers_MaxElementVolume : SMESH::SMESH_Hypothesis
{
/*!
* Sets <maximum element volume> parameter value
*/
void SetMaxElementVolume(in double volume)
raises (SALOME::SALOME_Exception);
/*!
* Returns <maximum element volume> parameter value
*/
double GetMaxElementVolume();
};
/*!
* StdMeshers_NotConformAllowed: interface of "Not Conform Mesh Allowed" hypothesis.
* Presence of this hypothesis permits to algorithm generation of not conform mesh.
*/
interface StdMeshers_NotConformAllowed : SMESH::SMESH_Hypothesis
{
};
/*!
* StdMeshers_Propagation: interface of "Propagation of 1D Hyp. on
* Opposite Edges" hypothesis.
* Presence of this hypothesis on any edge propagates any other 1D
* hypothesis from this edge on all edges, opposite to it.
* It concerns only edges of quadrangle faces.
*/
interface StdMeshers_Propagation : SMESH::SMESH_Hypothesis
{
};
/*!
* StdMeshers_Propagation: interface of "Propagation of Node
* Distribution on Opposite Edges" hypothesis.
* Presence of this hypothesis on any edge propagates distribution of nodes
* from this edge on all edges, opposite to it.
* It concerns only edges of quadrangle faces.
*/
interface StdMeshers_PropagOfDistribution : SMESH::SMESH_Hypothesis
{
};
/*!
* StdMeshers_QuadranglePreference: interface of "QuadranglePreference" hypothesis.
* This hypothesis is used by StdMeshers_Quadrangle_2D algorithm.
* Presence of this hypothesis forces 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
*/
interface StdMeshers_QuadranglePreference : SMESH::SMESH_Hypothesis
{
};
/*!
* StdMeshers_QuadraticMesh: interface of "QuadraticMesh" hypothesis.
* This is an auxiliary 1D hypothesis whose presence forces 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.
*/
interface StdMeshers_QuadraticMesh : SMESH::SMESH_Hypothesis
{
};
/*!
* StdMeshers_NumberOfLayers: interface of "Nb. Layers" hypothesis.
* This hypothesis is used by "Radial prism" algorithm.
* It specifies number of segments between the internal
* and the external surfaces.
*/
interface StdMeshers_NumberOfLayers : SMESH::SMESH_Hypothesis
{
/*!
* Sets <number of segments> parameter value
*/
void SetNumberOfLayers(in long numberOfLayers)
raises (SALOME::SALOME_Exception);
/*!
* Returns <number of layers> parameter value
*/
long GetNumberOfLayers();
};
/*!
* StdMeshers_LayerDistribution: interface of "Distribution of Layers" hypothesis.
* This hypothesis is used by "Radial prism" algorithm.
* It specifies 1D hypothesis defining distribution of segments between the internal
* and the external surfaces.
*/
interface StdMeshers_LayerDistribution : SMESH::SMESH_Hypothesis
{
/*!
* Sets 1D hypothesis specifying distribution of layers
*/
void SetLayerDistribution(in SMESH::SMESH_Hypothesis distributionHyp)
raises (SALOME::SALOME_Exception);
/*!
* Returns 1D hypothesis specifying distribution of layers
*/
SMESH::SMESH_Hypothesis GetLayerDistribution();
};
/*!
* StdMeshers_NumberOfLayers2D: interface of "Nb. Layers" hypothesis.
* This hypothesis is used by "Radial quadrangle" algorithm.
* It specifies number of segments between the internal
* and the external surfaces.
*/
interface StdMeshers_NumberOfLayers2D : StdMeshers_NumberOfLayers
{
};
/*!
* StdMeshers_LayerDistribution2D: interface of "Distribution of Layers" hypothesis.
* This hypothesis is used by "Radial quadrangle" algorithm.
* It specifies 1D hypothesis defining distribution of segments between the internal
* and the external surfaces.
*/
interface StdMeshers_LayerDistribution2D : StdMeshers_LayerDistribution
{
};
/*!
* interface of "ProjectionSource1D" hypothesis.
* This hypothesis specifies a meshed edge to take a mesh pattern from
* and optionally association of vertices between the source edge and a
* target one (where a hipothesis is assigned to)
*/
interface StdMeshers_ProjectionSource1D : SMESH::SMESH_Hypothesis
{
/*!
* Sets source <edge> to take a mesh pattern from
*/
void SetSourceEdge(in GEOM::GEOM_Object edge)
raises (SALOME::SALOME_Exception);
/*!
* Returns the source edge
*/
GEOM::GEOM_Object GetSourceEdge();
/*!
* Sets source <mesh> to take a mesh pattern from
*/
void SetSourceMesh(in SMESH::SMESH_Mesh mesh);
/*!
* Return source mesh
*/
SMESH::SMESH_Mesh GetSourceMesh();
/*!
* Sets vertex association between the source edge and the target one.
* This parameter is optional
*/
void SetVertexAssociation(in GEOM::GEOM_Object sourceVertex,
in GEOM::GEOM_Object targetVertex)
raises (SALOME::SALOME_Exception);
/*!
* Returns the vertex associated with the target vertex.
* Result may be nil if association not set
*/
GEOM::GEOM_Object GetSourceVertex();
/*!
* Returns the vertex associated with the source vertex.
* Result may be nil if association not set
*/
GEOM::GEOM_Object GetTargetVertex();
};
/*!
* interface of "ProjectionSource2D" hypothesis.
* This hypothesis specifies a meshed face to take a mesh pattern from
* and optionally association of vertices between the source face and a
* target one (where a hipothesis is assigned to)
*/
interface StdMeshers_ProjectionSource2D : SMESH::SMESH_Hypothesis
{
/*!
* Sets a source <face> to take a mesh pattern from
*/
void SetSourceFace(in GEOM::GEOM_Object face)
raises (SALOME::SALOME_Exception);
/*!
* Returns the source face
*/
GEOM::GEOM_Object GetSourceFace();
/*!
* Sets source <mesh> to take a mesh pattern from
*/
void SetSourceMesh(in SMESH::SMESH_Mesh mesh);
/*!
* Return source mesh
*/
SMESH::SMESH_Mesh GetSourceMesh();
/*!
* Sets vertex association between the source face and the target one.
* This parameter is optional.
* Two vertices must belong to one edge of a face
*/
void SetVertexAssociation(in GEOM::GEOM_Object sourceVertex1,
in GEOM::GEOM_Object sourceVertex2,
in GEOM::GEOM_Object targetVertex1,
in GEOM::GEOM_Object targetVertex2)
raises (SALOME::SALOME_Exception);
/*!
* Returns the <i>-th source vertex associated with the <i>-th target vertex.
* Result may be nil if association not set.
* Valid indices are 1 and 2
*/
GEOM::GEOM_Object GetSourceVertex(in long i)
raises (SALOME::SALOME_Exception);
/*!
* Returns the <i>-th target vertex associated with the <i>-th source vertex.
* Result may be nil if association not set.
* Valid indices are 1 and 2
*/
GEOM::GEOM_Object GetTargetVertex(in long i)
raises (SALOME::SALOME_Exception);
};
/*!
* interface of "ProjectionSource3D" hypothesis.
* This hypothesis specifies a meshed shell or solid to take a mesh pattern from
* and optionally association of vertices between the source shape and a
* target one (where a hipothesis is assigned to)
*/
interface StdMeshers_ProjectionSource3D : SMESH::SMESH_Hypothesis
{
/*!
* Sets a source <shape> to take a mesh pattern from
*/
void SetSource3DShape(in GEOM::GEOM_Object shape)
raises (SALOME::SALOME_Exception);
/*!
* Returns the source shape
*/
GEOM::GEOM_Object GetSource3DShape();
/*!
* Sets source <mesh> to take a mesh pattern from
*/
void SetSourceMesh(in SMESH::SMESH_Mesh mesh);
/*!
* Return source mesh
*/
SMESH::SMESH_Mesh GetSourceMesh();
/*!
* Sets vertex association between the source shape and the target one.
* This parameter is optional.
* Two vertices must belong to one edge of a shape
*/
void SetVertexAssociation(in GEOM::GEOM_Object sourceVertex1,
in GEOM::GEOM_Object sourceVertex2,
in GEOM::GEOM_Object targetVertex1,
in GEOM::GEOM_Object targetVertex2)
raises (SALOME::SALOME_Exception);
/*!
* Returns the <i>-th source vertex associated with the <i>-th target vertex.
* Result may be nil if association not set.
* Valid indices are 1 and 2
*/
GEOM::GEOM_Object GetSourceVertex(in long i)
raises (SALOME::SALOME_Exception);
/*!
* Returns the <i>-th target vertex associated with the <i>-th source vertex.
* Result may be nil if association not set.
* Valid indices are 1 and 2
*/
GEOM::GEOM_Object GetTargetVertex(in long i)
raises (SALOME::SALOME_Exception);
};
/*!
* interface of "SegmentLengthAroundVertex" hypothesis.
* This hypothesis specifies length of segments adjacent to the vertex the
* hypothesis is assigned to
*/
interface StdMeshers_SegmentLengthAroundVertex : SMESH::SMESH_Hypothesis
{
/*!
* Sets <length> parameter value
*/
void SetLength(in double length)
raises (SALOME::SALOME_Exception);
/*!
* Returns <length> parameter value
*/
double GetLength();
};
/*!
* StdMeshers_QuadrangleParams: interface of "Quadrangle Params" hypothesis
*/
enum QuadType
{
QUAD_STANDARD,
QUAD_TRIANGLE_PREF,
QUAD_QUADRANGLE_PREF,
QUAD_QUADRANGLE_PREF_REVERSED,
QUAD_REDUCED,
QUAD_NB_TYPES /* this is not a type of quadrangulation */
};
interface StdMeshers_QuadrangleParams : SMESH::SMESH_Hypothesis
{
/*!
* Set base vertex for triangles
*/
void SetTriaVertex( in long vertID );
/*!
* Returns base vertex for triangles
*/
long GetTriaVertex();
/*!
* Set entry of the main object
*/
void SetObjectEntry( in string entry );
/*!
* Get the entry of the main object
*/
string GetObjectEntry();
/*!
* Set the type of quadrangulation
*/
void SetQuadType( in QuadType type );
/*!
* Get the type of quadrangulation
*/
QuadType GetQuadType();
/*!
* Set positions of enforced nodes
*/
void SetEnforcedNodes(in GEOM::ListOfGO vertices, in SMESH::nodes_array points)
raises (SALOME::SALOME_Exception);
/*!
* Returns positions of enforced nodes
*/
void GetEnforcedNodes(out GEOM::ListOfGO vertices, out SMESH::nodes_array points);
/*!
* Returns entries of shapes defining enforced nodes
*/
SMESH::string_array GetEnfVertices();
/*!
* Set corner vertices
*/
void SetCorners( in SMESH::long_array vertexIDs );
/*!
* Return IDs of corner vertices
*/
SMESH::long_array GetCorners();
};
/*!
* interface of "Source edges" hypothesis.
* This hypothesis specifies groups of edges of other mesh to be imported
* in this mesh
*/
interface StdMeshers_ImportSource1D : SMESH::SMESH_Hypothesis
{
/*!
* Set edges to import from other mesh
*/
void SetSourceEdges(in SMESH::ListOfGroups groups);
SMESH::string_array GetSourceEdges();
/*!
* Set to import the whole other mesh or not, and if yes, to
* copy groups of not. By default the mesh is not copied.
*/
void SetCopySourceMesh(in boolean toCopyMesh, in boolean toCopyGroups);
void GetCopySourceMesh(out boolean toCopyMesh,out boolean toCopyGroups);
};
/*!
* interface of "Source faces" hypothesis.
* This hypothesis specifies groups of faces of other mesh to be imported
* in this mesh
*/
interface StdMeshers_ImportSource2D : SMESH::SMESH_Hypothesis
{
/*!
* Set faces to import from other mesh
*/
void SetSourceFaces(in SMESH::ListOfGroups groups);
SMESH::string_array GetSourceFaces();
/*!
* Set to import the whole other mesh or not, and if yes, to
* copy groups of not. By default the mesh is not copied.
*/
void SetCopySourceMesh(in boolean toCopyMesh,in boolean toCopyGroups);
void GetCopySourceMesh(out boolean toCopyMesh,out boolean toCopyGroups);
};
/*!
* Method of computing translation of a node at Viscous Layers construction
*/
enum VLExtrusionMethod {
// node is translated along normal to a surface with possible further smoothing
SURF_OFFSET_SMOOTH,
// node is translated along the average normal of surrounding faces till
// intersection with a neighbor face translated along its own normal
// by the layers thickness
FACE_OFFSET,
// node is translated along the average normal of surrounding faces
// by the layers thickness
NODE_OFFSET
};
/*!
* interface of "Viscous Layers" hypothesis.
* This hypothesis specifies parameters of layers of prisms to build
* near mesh boundary. This hypothesis can be used by several 3D algorithms:
* NETGEN 3D, Hexahedron(i,j,k), MG_Tetra
*/
interface StdMeshers_ViscousLayers : SMESH::SMESH_Hypothesis
{
/*!
* Set faces to exclude from treatment
*/
void SetIgnoreFaces(in SMESH::long_array faceIDs) raises (SALOME::SALOME_Exception);
SMESH::long_array GetIgnoreFaces();
/*!
* Set faces either to exclude from treatment or to make the Viscous Layers on.
*/
void SetFaces(in SMESH::long_array faceIDs,
in boolean toIgnore) raises (SALOME::SALOME_Exception);
SMESH::long_array GetFaces();
boolean GetIsToIgnoreFaces();
/*!
* Set total thickness of layers of prisms
*/
void SetTotalThickness(in double thickness) raises (SALOME::SALOME_Exception);
double GetTotalThickness();
/*!
* Set number of layers of prisms
*/
void SetNumberLayers(in short nb) raises (SALOME::SALOME_Exception);
short GetNumberLayers();
/*!
* Set factor (>=1.0) of growth of layer thickness towards inside of mesh
*/
void SetStretchFactor(in double factor) raises (SALOME::SALOME_Exception);
double GetStretchFactor();
void SetMethod( in VLExtrusionMethod how );
VLExtrusionMethod GetMethod();
void SetGroupName(in string name);
string GetGroupName();
};
/*!
* interface of "Viscous Layers 2D" hypothesis.
* This hypothesis specifies parameters of layers of quadrilaterals to build
* near mesh boundary. This hypothesis can be used by several 2D algorithms:
* Mefisto, Quadrangle (mapping), NETGEN, BLSURF
*/
interface StdMeshers_ViscousLayers2D : SMESH::SMESH_Hypothesis
{
/*!
* Set edges to exclude from treatment
*/
void SetIgnoreEdges(in SMESH::long_array edgeIDs) raises (SALOME::SALOME_Exception);
SMESH::long_array GetIgnoreEdges();
/*!
* Set edges either to exclude from treatment or to make the Viscous Layers on.
*/
void SetEdges(in SMESH::long_array edgeIDs,
in boolean toIgnore) raises (SALOME::SALOME_Exception);
SMESH::long_array GetEdges();
boolean GetIsToIgnoreEdges();
/*!
* Set total thickness of layers of prisms
*/
void SetTotalThickness(in double thickness) raises (SALOME::SALOME_Exception);
double GetTotalThickness();
/*!
* Set number of layers of prisms
*/
void SetNumberLayers(in short nb) raises (SALOME::SALOME_Exception);
short GetNumberLayers();
/*!
* Set factor (>=1.0) of growth of layer thickness towards inside of mesh
*/
void SetStretchFactor(in double factor) raises (SALOME::SALOME_Exception);
double GetStretchFactor();
void SetGroupName(in string name);
string GetGroupName();
};
/*!
* interface of "Body fitting Parameters" hypothesis.
* This hypothesis specifies
* - Size threshold
* - Definition of the Cartesian grid
* - Direction of grid axes
*/
interface StdMeshers_CartesianParameters3D : SMESH::SMESH_Hypothesis
{
/*!
* Set size threshold. A polyhedral cell got by cutting an initial
* hexahedron by geometry boundary is considered small and is removed if
* it's size is \a threshold times less than the size of the initial hexahedron.
* threshold must be > 1.0
*/
void SetSizeThreshold(in double threshold) raises (SALOME::SALOME_Exception);
double GetSizeThreshold();
/*!
* \brief Return true if the grid is defined by spacing functions and
* not by node coordinates in given direction (X==0,...)
*/
boolean IsGridBySpacing(in short axis);
/*!
* Set coordinates of nodes along an axis (countered from zero)
*/
void SetGrid(in SMESH::double_array coords,
in short axis) raises (SALOME::SALOME_Exception);
SMESH::double_array GetGrid(in short axis) raises (SALOME::SALOME_Exception);
/*!
* \brief Set grid spacing along an axis
* \param spaceFunctions - functions defining spacing values at given point on axis
* \param internalPoints - points dividing a grid into parts along an axis
* \param axis - index of an axis counterd from zero, i.e. 0==X, 1==Y, 2==Z
*
* Parameter t of spaceFunction f(t) is a position [0,1] within bounding box of
* the shape to mesh or within an interval defined by internal points
*/
void SetGridSpacing(in SMESH::string_array spaceFunctions,
in SMESH::double_array internalPoints,
in short axis) raises (SALOME::SALOME_Exception);
void GetGridSpacing(out SMESH::string_array spaceFunctions,
out SMESH::double_array internalPoints,
in short axis) raises (SALOME::SALOME_Exception);
/*!
* Set custom direction of axes
*/
void SetAxesDirs(in SMESH::DirStruct x,
in SMESH::DirStruct y,
in SMESH::DirStruct z ) raises (SALOME::SALOME_Exception);
void GetAxesDirs(out SMESH::DirStruct x,
out SMESH::DirStruct y,
out SMESH::DirStruct z );
/*!
* Set/unset a fixed point, at which a node will be created provided that grid
* is defined by spacing in all directions
*/
void SetFixedPoint(in SMESH::PointStruct p, in boolean toUnset);
boolean GetFixedPoint(out SMESH::PointStruct p);
/*!
* Enable implementation of geometrical edges into the mesh. If this feature
* is disabled, sharp edges of the shape are lost ("smoothed") in the mesh if
* they don't coincide with the grid lines
*/
void SetToAddEdges(in boolean toAdd);
boolean GetToAddEdges();
/*!
* Enable treatment of geom faces, either shared by solids or internal.
*/
void SetToConsiderInternalFaces(in boolean toTreat);
boolean GetToConsiderInternalFaces();
/*!
* Enable applying size threshold to grid cells cut by internal geom faces.
*/
void SetToUseThresholdForInternalFaces(in boolean toUse);
boolean GetToUseThresholdForInternalFaces();
/*!
* Enable creation of mesh faces.
*/
void SetToCreateFaces(in boolean toCreate);
boolean GetToCreateFaces();
/*!
* Return axes at which a number of generated hexahedra is maximal
*/
void ComputeOptimalAxesDirs(in GEOM::GEOM_Object shape,
in boolean isOrthogonal,
out SMESH::DirStruct x,
out SMESH::DirStruct y,
out SMESH::DirStruct z )
raises (SALOME::SALOME_Exception);
/*!
* \brief Compute node coordinates by spacing functions
* \param x0 - lower coordinate
* \param x1 - upper coordinate
* \param spaceFuns - space functions
* \param points - internal points
* \param axisName - e.g. "X"
* \return the computed coordinates
*/
SMESH::double_array ComputeCoordinates(in double x0,
in double x1,
in SMESH::string_array spaceFuns,
in SMESH::double_array points,
in string axisName )
raises (SALOME::SALOME_Exception);
};
/*!
* interface of "Renumber" hypothesis used by Hexahedron(ijk) algorithm
* to renumber mesh of a block to be structured-like
*/
struct BlockCS // Local coordinate system of a block
{
GEOM::GEOM_Object solid;
GEOM::GEOM_Object vertex000;
GEOM::GEOM_Object vertex001;
};
typedef sequence<BlockCS> blockcs_array;
interface StdMeshers_BlockRenumber : SMESH::SMESH_Hypothesis
{
void SetBlocksOrientation( in blockcs_array blockCS );
blockcs_array GetBlocksOrientation();
};
/*!
* StdMeshers_SegmentAroundVertex_0D: interface of "SegmentAroundVertex" algorithm
*/
interface StdMeshers_SegmentAroundVertex_0D : SMESH::SMESH_0D_Algo
{
};
/*!
* StdMeshers_Regular_1D: interface of "Wire discretisation" algorithm
*/
interface StdMeshers_Regular_1D : SMESH::SMESH_1D_Algo
{
};
/*!
* StdMeshers_CompositeSegment_1D: interface of "Composite side discretisation" algorithm
*/
interface StdMeshers_CompositeSegment_1D : SMESH::SMESH_1D_Algo
{
};
/*!
* StdMeshers_MEFISTO_2D: interface of "Triangle (Mefisto)" algorithm
*/
interface StdMeshers_MEFISTO_2D : SMESH::SMESH_2D_Algo
{
};
/*!
* StdMeshers_Quadrangle_2D: interface of "Quadrangle (Mapping)" algorithm
*/
interface StdMeshers_Quadrangle_2D : SMESH::SMESH_2D_Algo
{
};
/*!
* StdMeshers_QuadFromMedialAxis_1D2D: interface of "Quadrangle (Medial Axis Projection)" algorithm
*/
interface StdMeshers_QuadFromMedialAxis_1D2D : SMESH::SMESH_2D_Algo
{
};
/*!
* StdMeshers_PolygonPerFace_2D: interface of "Polygon Per Face" 2D algorithm
*/
interface StdMeshers_PolygonPerFace_2D : SMESH::SMESH_2D_Algo
{
};
/*!
* StdMeshers_PolyhedronPerSolid_3D: interface of "Polyhedron Per Solid" 3D algorithm
*/
interface StdMeshers_PolyhedronPerSolid_3D : SMESH::SMESH_3D_Algo
{
};
/*!
* StdMeshers_Hexa_3D: interface of "Hexahedron (i,j,k)" algorithm
*/
interface StdMeshers_Hexa_3D : SMESH::SMESH_3D_Algo
{
};
/*!
* StdMeshers_Prism_3D: interface of "3D extrusion" algorithm
*/
interface StdMeshers_Prism_3D : SMESH::SMESH_3D_Algo
{
};
/*!
* StdMeshers_RadialPrism_3D: interface of "Radial Prism" algorithm
*/
interface StdMeshers_RadialPrism_3D : SMESH::SMESH_3D_Algo
{
};
/*!
* StdMeshers_Projection_3D: interface of "Projection 3D" algorithm
*/
interface StdMeshers_Projection_3D : SMESH::SMESH_3D_Algo
{
};
/*!
* StdMeshers_Projection_2D: interface of "Projection 2D" algorithm
*/
interface StdMeshers_Projection_2D : SMESH::SMESH_2D_Algo
{
};
/*!
* StdMeshers_Projection_1D2D: interface of "Projection 1D-2D" algorithm
*/
interface StdMeshers_Projection_1D2D : SMESH::SMESH_2D_Algo
{
};
/*!
* StdMeshers_Projection_1D: interface of "Projection 1D" algorithm
*/
interface StdMeshers_Projection_1D : SMESH::SMESH_1D_Algo
{
};
/*!
* StdMeshers_UseExisting_2D: interface of "UseExisting 2D" algorithm
* doing nothing to allow mesh generation by mesh edition functions in TUI mode
*/
interface StdMeshers_UseExisting_2D : SMESH::SMESH_2D_Algo
{
};
/*!
* StdMeshers_UseExisting_1D: interface of "UseExisting 1D" algorithm
* doing nothing to allow mesh generation by mesh edition functions in TUI mode
*/
interface StdMeshers_UseExisting_1D : SMESH::SMESH_1D_Algo
{
};
/*!
* StdMeshers_RadialQuadrangle_1D2D: interface of "Radial quadrangle" algorithm
*/
interface StdMeshers_RadialQuadrangle_1D2D : SMESH::SMESH_2D_Algo
{
};
/*!
* StdMeshers_Import_1D2D: interface of "Use existing 2D elements" algorithm
*/
interface StdMeshers_Import_1D2D : SMESH::SMESH_2D_Algo
{
};
/*!
* StdMeshers_Import_1D: interface of "Use existing 1D elements" algorithm
*/
interface StdMeshers_Import_1D : SMESH::SMESH_1D_Algo
{
};
/*!
* StdMeshers_Cartesian_3D: interface of "Body fitting" algorithm
*/
interface StdMeshers_Cartesian_3D : SMESH::SMESH_3D_Algo
{
};
};
#endif