smesh/idl/SMESH_MeshEditor.idl

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// Copyright (C) 2007-2021 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_MeshEditor.idl
#ifndef _SMESH_MESHEDITOR_IDL_
#define _SMESH_MESHEDITOR_IDL_
#include "SMESH_Mesh.idl"
#include "SMESH_Gen.idl"
#include "SMESH_smIdType.idl"
module SMESH
{
interface NumericalFunctor;
enum Bnd_Dimension { BND_2DFROM3D, BND_1DFROM3D, BND_1DFROM2D };
struct FreeBorder
{
SMESH::smIdType_array nodeIDs; // all nodes defining a free border
// 1st and last node is same in a closed border
};
struct FreeBorderPart
{
short border; // border index within a sequence<FreeBorder>
long node1; // node index within the border-th FreeBorder
long node2;
long nodeLast;
};
typedef sequence<FreeBorder> ListOfFreeBorders;
typedef sequence<FreeBorderPart> FreeBordersGroup;
typedef sequence<FreeBordersGroup> ListOfFreeBorderGroups;
struct CoincidentFreeBorders
{
ListOfFreeBorders borders; // nodes of all free borders
ListOfFreeBorderGroups coincidentGroups; // groups of coincident parts of borders
};
// structure used in MakePolyLine() to define a cutting plane
struct PolySegment
{
// a point is defined as follows:
// ( node*ID1 > 0 && node*ID2 > 0 ) ==> point is in the middle of an edge defined by two nodes
// ( node*ID1 > 0 && node*ID2 <=0 ) ==> point is at node*ID1
// else ==> point is at xyz*
// point 1
smIdType node1ID1;
smIdType node1ID2;
PointStruct xyz1;
// point 2
smIdType node2ID1;
smIdType node2ID2;
PointStruct xyz2;
// vector on the plane; to use a default plane set vector = (0,0,0)
DirStruct vector;
};
typedef sequence<PolySegment> ListOfPolySegments;
// face edge defined by two nodes + optional medium node
struct FaceEdge
{
smIdType node1;
smIdType node2;
smIdType medium;
};
typedef sequence<FaceEdge> ListOfEdges;
/*!
* This interface makes modifications on the Mesh - removing elements and nodes etc.
* Also provides some analysis functions.
*/
interface SMESH_MeshEditor
{
/*!
* Returns a mesh subject to edition
*/
SMESH_Mesh GetMesh();
/*!
* Return data of mesh edition preview which is computed provided
* that the editor was obtained through SMESH_Mesh::GetMeshEditPreviewer()
*/
MeshPreviewStruct GetPreviewData() raises (SALOME::SALOME_Exception);
/*!
* If during last operation of MeshEditor some nodes were
* created, this method returns list of their IDs, if new nodes
* not created - returns empty list
*/
smIdType_array GetLastCreatedNodes() raises (SALOME::SALOME_Exception);
/*!
* If during last operation of MeshEditor some elements were
* created, this method returns list of their IDs, if new elements
* not created - returns empty list
*/
smIdType_array GetLastCreatedElems() raises (SALOME::SALOME_Exception);
/*!
* \brief Clears sequences of last created elements and nodes
*/
void ClearLastCreated() raises (SALOME::SALOME_Exception);
/*!
* \brief Returns description of an error/warning occurred during the last operation
*/
ComputeError GetLastError() raises (SALOME::SALOME_Exception);
/*!
* \brief Wrap a sequence of ids in a SMESH_IDSource
* \param IDsOfElements list of mesh elements identifiers
* \return new ID source object
*/
SMESH_IDSource MakeIDSource(in smIdType_array IDsOfElements, in ElementType type);
/*!
* \brief Remove mesh elements specified by their identifiers.
* \param IDsOfElements list of mesh elements identifiers
* \return \c true if elements are correctly removed or \c false otherwise
*/
boolean RemoveElements(in smIdType_array IDsOfElements) raises (SALOME::SALOME_Exception);
/*!
* \brief Remove mesh nodes specified by their identifiers.
* \param IDsOfNodes list of mesh nodes identifiers
* \return \c true if nodes are correctly removed or \c false otherwise
*/
boolean RemoveNodes(in smIdType_array IDsOfNodes) raises (SALOME::SALOME_Exception);
/*!
* \brief Remove all orphan nodes.
* \return number of removed nodes
*/
smIdType RemoveOrphanNodes() raises (SALOME::SALOME_Exception);
/*!
* \brief Remove a mesh node and change surrounding faces to close a hole
* \param nodeID node identifier
* \throw if mesh is not a triangle one
*/
void RemoveNodeWithReconnection(in smIdType nodeID) raises (SALOME::SALOME_Exception);
/*!
* \brief Add a new node.
* \param x X coordinate of new node
* \param y Y coordinate of new node
* \param z Z coordinate of new node
* \return integer identifier of new node
*/
smIdType AddNode(in double x, in double y, in double z) raises (SALOME::SALOME_Exception);
/*!
* Create a 0D element on the given node.
* \param IdOfNode Node IDs for creation of element.
* \param DuplicateElements to add one more 0D element to a node or not
*/
smIdType Add0DElement(in smIdType IDOfNode,
in boolean DuplicateElements) raises (SALOME::SALOME_Exception);
/*!
* Create a ball element on the given node.
* \param IdOfNode Node IDs for creation of element.
*/
smIdType AddBall(in smIdType IDOfNode, in double diameter) raises (SALOME::SALOME_Exception);
/*!
* Create an edge, either linear and quadratic (this is determed
* by number of given nodes, two or three).
* \param IdsOfNodes List of node IDs for creation of element.
* Needed order of nodes in this list corresponds to description
* of MED. This description is located by the following link:
* http://www.salome-platform.org/salome2/web_med_internet/logiciels/medV2.2.2_doc_html/html/modele_de_donnees.html#3.
*/
smIdType AddEdge(in smIdType_array IDsOfNodes) raises (SALOME::SALOME_Exception);
/*!
* Create face, either linear and quadratic (this is determed
* by number of given nodes).
* \param IdsOfNodes List of node IDs for creation of element.
* Needed order of nodes in this list corresponds to description
* of MED. This description is located by the following link:
* http://www.salome-platform.org/salome2/web_med_internet/logiciels/medV2.2.2_doc_html/html/modele_de_donnees.html#3.
*/
smIdType AddFace(in smIdType_array IDsOfNodes) raises (SALOME::SALOME_Exception);
smIdType AddPolygonalFace(in smIdType_array IdsOfNodes) raises (SALOME::SALOME_Exception);
/*!
* Create a quadratic polygonal face
* \param IdsOfNodes - nodes of the polygon; corner nodes follow first
* \return smIdType- ID of a new polygon
*/
smIdType AddQuadPolygonalFace(in smIdType_array IdsOfNodes) raises (SALOME::SALOME_Exception);
/*!
* Create volume, either linear and quadratic (this is determed
* by number of given nodes).
* \param IdsOfNodes List of node IDs for creation of element.
* Needed order of nodes in this list corresponds to description
* of MED. This description is located by the following link:
* http://www.salome-platform.org/salome2/web_med_internet/logiciels/medV2.2.2_doc_html/html/modele_de_donnees.html#3.
*/
smIdType AddVolume(in smIdType_array IDsOfNodes) raises (SALOME::SALOME_Exception);
/*!
* Create volume of many faces, giving nodes for each face.
* \param IdsOfNodes List of node IDs for volume creation face by face.
* \param Quantities List of integer values, Quantities[i]
* gives quantity of nodes in face number i.
*/
smIdType AddPolyhedralVolume (in smIdType_array IdsOfNodes,
in long_array Quantities) raises (SALOME::SALOME_Exception);
/*!
* Create volume of many faces, giving IDs of existing faces.
* \param IdsOfFaces List of face IDs for volume creation.
* \note The created volume will refer only to nodes
* of the given faces, not to the faces itself.
*/
smIdType AddPolyhedralVolumeByFaces (in smIdType_array IdsOfFaces) raises (SALOME::SALOME_Exception);
/*!
* Create 0D elements on all nodes of the given object.
* \param theObject object on whose nodes 0D elements will be created.
* \param theGroupName optional name of a group to add 0D elements created
* and/or found on nodes of \a theObject.
* \param theDuplicateElements 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.
*/
SMESH_IDSource Create0DElementsOnAllNodes(in SMESH_IDSource theObject,
in string theGroupName,
in boolean theDuplicateElements)
raises (SALOME::SALOME_Exception);
/*!
* \brief Bind a node to a vertex
* \param NodeID - node ID
* \param VertexID - vertex ID available through GEOM_Object.GetSubShapeIndices()[0]
*/
void SetNodeOnVertex(in smIdType NodeID, in long VertexID)
raises (SALOME::SALOME_Exception);
/*!
* \brief Store node position on an edge
* \param NodeID - node ID
* \param EdgeID - edge ID available through GEOM_Object.GetSubShapeIndices()[0]
* \param paramOnEdge - parameter on edge where the node is located
*/
void SetNodeOnEdge(in smIdType NodeID, in long EdgeID, in double paramOnEdge)
raises (SALOME::SALOME_Exception);
/*!
* \brief Store node position on a face
* \param NodeID - node ID
* \param FaceID - face ID available through GEOM_Object.GetSubShapeIndices()[0]
* \param u - U parameter on face where the node is located
* \param v - V parameter on face where the node is located
*/
void SetNodeOnFace(in smIdType NodeID, in long FaceID, in double u, in double v)
raises (SALOME::SALOME_Exception);
/*!
* \brief Bind a node to a solid
* \param NodeID - node ID
* \param SolidID - vertex ID available through GEOM_Object.GetSubShapeIndices()[0]
*/
void SetNodeInVolume(in smIdType NodeID, in long SolidID)
raises (SALOME::SALOME_Exception);
/*!
* \brief Bind an element to a shape
* \param ElementID - element ID
* \param ShapeID - shape ID available through GEOM_Object.GetSubShapeIndices()[0]
*/
void SetMeshElementOnShape(in smIdType ElementID, in long ShapeID)
raises (SALOME::SALOME_Exception);
/*!
* \brief Change node location
*/
boolean MoveNode(in smIdType NodeID, in double x, in double y, in double z)
raises (SALOME::SALOME_Exception);
/*!
* \brief Swap a diagonal of a quadrangle formed by two adjacent triangles
*/
boolean InverseDiag(in smIdType NodeID1, in smIdType NodeID2)
raises (SALOME::SALOME_Exception);
/*!
* \brief Delete a diagonal of a quadrangle formed by two adjacent triangles
* so that a new quadrangle appears in place of the triangles
*/
boolean DeleteDiag(in smIdType NodeID1, in smIdType NodeID2)
raises (SALOME::SALOME_Exception);
/*!
* \brief Replace each triangle bound by Node1-Node2 segment with
* two triangles by connecting a node made on the segment with a node opposite
* to the segment.
*/
void AddNodeOnSegment(in smIdType Node1, in smIdType Node2, in double position)
raises (SALOME::SALOME_Exception);
/*!
* \brief Split a face into triangles by adding a new node onto the face
* and connecting the new node with face nodes
*/
void AddNodeOnFace(in smIdType triangle, in double x, in double y, in double z);
/*!
* \brief Change orientation of cells
*/
boolean Reorient(in smIdType_array IDsOfElements)
raises (SALOME::SALOME_Exception);
/*!
* \brief Change orientation of cells
*/
boolean ReorientObject(in SMESH_IDSource theObject)
raises (SALOME::SALOME_Exception);
/*!
* \brief Reorient faces contained in \a the2Dgroup.
* \param the2Dgroup - the mesh or its part to reorient
* \param theDirection - desired direction of normal of \a theFace
* \param theFace - ID of face whose orientation is checked.
* It can be < 1 then \a thePoint is used to find a face.
* \param thePoint - is used to find a face if \a theFace < 1.
* \return number of reoriented faces.
*/
long Reorient2D(in SMESH_IDSource the2Dgroup,
in DirStruct theDirection,
in long theFace,
in PointStruct thePoint) raises (SALOME::SALOME_Exception);
/*!
* \brief Reorient faces contained in a list of \a objectFaces
* equally to faces contained in a list of \a referenceFaces.
* \param objectFaces - faces to reorient in a list including either
* the whole mesh or groups and/or sub-meshes.
* \param referenceFaces - correctly oriented faces in a list of groups and/or sub-meshes.
* It can be empty, then the 1st face in \a objectFaces is used as the reference.
* \return number of reoriented faces.
*/
long Reorient2DByNeighbours(in SMESH::ListOfIDSources objectFaces,
in SMESH::ListOfIDSources referenceFaces)
raises (SALOME::SALOME_Exception);
/*!
* \brief Reorient faces basing on orientation of adjacent volumes.
* \param faces - a list of objects containing face to reorient
* \param volumes - an object containing volumes.
* \param outsideNormal - to orient faces to have their normal
* pointing either \a outside or \a inside the adjacent volumes.
* \return number of reoriented faces.
*/
long Reorient2DBy3D(in ListOfIDSources faces,
in SMESH_IDSource volumes,
in boolean outsideNormal) raises (SALOME::SALOME_Exception);
/*!
* \brief Fuse neighbour triangles into quadrangles.
* \param IDsOfElements Ids of triangles to be fused.
* \param theCriterion Is used to choose a neighbour to fuse with.
* \param theMaxAngle Is a max angle between element normals at which fusion
* is still performed; theMaxAngle is measured in radians.
* \return \c true in case of success, FALSE otherwise.
*/
boolean TriToQuad (in smIdType_array IDsOfElements,
in NumericalFunctor Criterion,
in double MaxAngle) raises (SALOME::SALOME_Exception);
/*!
* \brief Fuse neighbour triangles into quadrangles.
*
* Behaves like the above method, taking a list of elements from \a theObject
*/
boolean TriToQuadObject (in SMESH_IDSource theObject,
in NumericalFunctor Criterion,
in double MaxAngle) raises (SALOME::SALOME_Exception);
/*!
* \brief Split quadrangles into triangles.
* \param IDsOfElements Ids of quadrangles to split.
* \param theCriterion Is used to choose a diagonal for splitting.
* \return TRUE in case of success, FALSE otherwise.
*/
boolean QuadToTri (in smIdType_array IDsOfElements,
in NumericalFunctor Criterion) raises (SALOME::SALOME_Exception);
/*!
* \brief Split quadrangles into triangles.
*
* Behaves like the above method, taking a list of elements from \a theObject
*/
boolean QuadToTriObject (in SMESH_IDSource theObject,
in NumericalFunctor Criterion) raises (SALOME::SALOME_Exception);
/*!
* \brief Split each of quadrangles into 4 triangles.
* \param theQuads Container of quadrangles to split.
*/
void QuadTo4Tri (in SMESH_IDSource theQuads) raises (SALOME::SALOME_Exception);
/*!
* \brief Split quadrangles into triangles.
* \param theElems The faces to be split.
* \param the13Diag Is used to choose a diagonal for splitting.
* \return TRUE in case of success, FALSE otherwise.
*/
boolean SplitQuad (in smIdType_array IDsOfElements,
in boolean Diag13) raises (SALOME::SALOME_Exception);
/*!
* \brief Split quadrangles into triangles.
*
* Behaves like the above method, taking list of elements from \a theObject
*/
boolean SplitQuadObject (in SMESH_IDSource theObject,
in boolean Diag13) raises (SALOME::SALOME_Exception);
/*!
* Find better splitting of the given quadrangle.
* \param IDOfQuad ID of the quadrangle to be split.
* \param Criterion A criterion to choose a diagonal for splitting.
* \return 1 if 1-3 diagonal is better, 2 if 2-4
* diagonal is better, 0 if error occurs.
*/
short BestSplit (in smIdType IDOfQuad,
in NumericalFunctor Criterion) raises (SALOME::SALOME_Exception);
/*!
* \brief Split volumic elements into tetrahedrons
* \param elems - elements to split
* \param methodFlags - flags passing splitting method:
* 1 - split the hexahedron into 5 tetrahedrons
* 2 - split the hexahedron into 6 tetrahedrons
* 3 - split the hexahedron into 24 tetrahedrons
*/
void SplitVolumesIntoTetra(in SMESH_IDSource elems, in short methodFlags)
raises (SALOME::SALOME_Exception);
/*!
* \brief Split hexahedra into triangular prisms
* \param elems - elements to split
* \param startHexPoint - a point used to find a hexahedron for which \a facetToSplitNormal
* gives a normal vector defining facets to split into triangles.
* \param facetToSplitNormal - normal used to find a facet of hexahedron
* to split into triangles.
* \param methodFlags - flags passing splitting method:
* 1 - split the hexahedron into 2 prisms
* 2 - split the hexahedron into 4 prisms
* \param allDomains - if \c False, only hexahedra adjacent to one closest
* to \a facetToSplitNormal location are split, else \a facetToSplitNormal
* is used to find the facet to split in all domains present in \a elems.
*/
void SplitHexahedraIntoPrisms(in SMESH_IDSource elems,
in SMESH::PointStruct startHexPoint,
in SMESH::DirStruct facetToSplitNormal,
in short methodFlags,
in boolean allDomains)
raises (SALOME::SALOME_Exception);
/*!
* \brief Split bi-quadratic elements into linear ones without creation of additional nodes.
* - bi-quadratic triangle will be split into 3 linear quadrangles;
* - bi-quadratic quadrangle will be split into 4 linear quadrangles;
* - tri-quadratic hexahedron will be split into 8 linear hexahedra;
* Quadratic elements of lower dimension adjacent to the split bi-quadratic element
* will be split in order to keep the mesh conformal.
* \param elems - elements to split
*/
void SplitBiQuadraticIntoLinear(in ListOfIDSources elems)
raises (SALOME::SALOME_Exception);
enum Smooth_Method { LAPLACIAN_SMOOTH, CENTROIDAL_SMOOTH };
boolean Smooth(in smIdType_array IDsOfElements,
in smIdType_array IDsOfFixedNodes,
in short MaxNbOfIterations,
in double MaxAspectRatio,
in Smooth_Method Method) raises (SALOME::SALOME_Exception);
boolean SmoothObject(in SMESH_IDSource theObject,
in smIdType_array IDsOfFixedNodes,
in short MaxNbOfIterations,
in double MaxAspectRatio,
in Smooth_Method Method) raises (SALOME::SALOME_Exception);
boolean SmoothParametric(in smIdType_array IDsOfElements,
in smIdType_array IDsOfFixedNodes,
in short MaxNbOfIterations,
in double MaxAspectRatio,
in Smooth_Method Method) raises (SALOME::SALOME_Exception);
boolean SmoothParametricObject(in SMESH_IDSource theObject,
in smIdType_array IDsOfFixedNodes,
in short MaxNbOfIterations,
in double MaxAspectRatio,
in Smooth_Method Method) raises (SALOME::SALOME_Exception);
void ConvertToQuadratic(in boolean theForce3d)
raises (SALOME::SALOME_Exception);
void ConvertToQuadraticObject(in boolean theForce3d,
in SMESH_IDSource theObject)
raises (SALOME::SALOME_Exception);
boolean ConvertFromQuadratic()
raises (SALOME::SALOME_Exception);
void ConvertFromQuadraticObject(in SMESH_IDSource theObject)
raises (SALOME::SALOME_Exception);
void ConvertToBiQuadratic(in boolean theForce3d,
in SMESH_IDSource theObject)
raises (SALOME::SALOME_Exception);
void RenumberNodes() raises (SALOME::SALOME_Exception);
void RenumberElements() raises (SALOME::SALOME_Exception);
/*!
* \brief Generate dim+1 elements by rotation of the object around axis
* \param Nodes - nodes to revolve: a list including groups, sub-meshes or a mesh
* \param Edges - edges to revolve: a list including groups, sub-meshes or a mesh
* \param Faces - faces to revolve: a list including groups, sub-meshes or a mesh
* \param Axis - rotation axis
* \param AngleInRadians - rotation angle
* \param NbOfSteps - number of elements to generate from one element
* \param ToMakeGroups - if true, new elements will be included into new groups
* corresponding to groups the input elements included in.
* \return ListOfGroups - new groups created if \a ToMakeGroups is true
*/
ListOfGroups RotationSweepObjects(in ListOfIDSources Nodes,
in ListOfIDSources Edges,
in ListOfIDSources Faces,
in AxisStruct Axis,
in double AngleInRadians,
in long NbOfSteps,
in double Tolerance,
in boolean ToMakeGroups)
raises (SALOME::SALOME_Exception);
/*!
* \brief Generate dim+1 elements by extrusion of elements along vector
* \param nodes - nodes to extrude: a list including groups, sub-meshes or a mesh.
* \param edges - edges to extrude: a list including groups, sub-meshes or a mesh.
* \param faces - faces to extrude: a list including groups, sub-meshes or a mesh.
* \param stepVector - vector giving direction and distance of an extrusion step.
* \param nbOfSteps - number of elements to generate from one element.
* \param toMakeGroups - if true, new elements will be included into new groups
* corresponding to groups the input elements included in.
* \param scaleFactors - optional scale factors to apply during extrusion; it's
* usage depends on \a scalesVariation parameter.
* \param scalesVariation - if \c True, \a scaleFactors are spread over all \a NbOfSteps,
otherwise \a scaleFactors[i] is applied to nodes at the i-th extrusion step.
* \param angles - optional rotation angles to apply during extrusion; it's
* usage depends on \a anglesVariation parameter.
* \param anglesVariation - if \c True, \a angles are spread over all \a NbOfSteps,
otherwise \a angle[i] is applied to nodes at the i-th extrusion step.
* \return ListOfGroups - new groups created if \a toMakeGroups is true
*/
ListOfGroups ExtrusionSweepObjects(in ListOfIDSources nodes,
in ListOfIDSources edges,
in ListOfIDSources faces,
in DirStruct stepVector,
in long nbOfSteps,
in boolean toMakeGroups,
in double_array scaleFactors,
in boolean scaleVariation,
in double_array basePoint,
in double_array angles,
in boolean angleVariation)
raises (SALOME::SALOME_Exception);
/*! Generates new elements by extrusion along the normal to a discretized surface or wire
*/
ListOfGroups ExtrusionByNormal(in ListOfIDSources theObjects,
in double stepSize,
in long nbOfSteps,
in boolean byAverageNormal,
in boolean useInputElemsOnly,
in boolean makeGroups,
in short dim)
raises (SALOME::SALOME_Exception);
/*!
* Generate new elements by extrusion of theElements
* by StepVector by NbOfSteps
* \param ExtrFlags set flags for performing extrusion
* \param SewTolerance - uses for comparing locations of nodes if flag
* EXTRUSION_FLAG_SEW is set
* \param ToMakeGroups - if true, new elements will be included into new groups
* corresponding to groups the input elements included in.
* \return ListOfGroups - new groups created if \a ToMakeGroups is true
*/
ListOfGroups AdvancedExtrusion(in smIdType_array IDsOfElements,
in DirStruct StepVector,
in long NbOfSteps,
in long ExtrFlags,
in double SewTolerance,
in boolean ToMakeGroups)
raises (SALOME::SALOME_Exception);
enum Extrusion_Error {
EXTR_OK,
EXTR_NO_ELEMENTS,
EXTR_PATH_NOT_EDGE,
EXTR_BAD_PATH_SHAPE,
EXTR_BAD_STARTING_NODE,
EXTR_BAD_ANGLES_NUMBER,
EXTR_CANT_GET_TANGENT
};
ListOfGroups ExtrusionAlongPathObjects(in ListOfIDSources Nodes,
in ListOfIDSources Edges,
in ListOfIDSources Faces,
in SMESH_IDSource Path,
in GEOM::GEOM_Object PathShape,
in smIdType NodeStart,
in boolean HasAngles,
in double_array Angles,
in boolean AnglesVariation,
in boolean HasRefPoint,
in PointStruct RefPoint,
in boolean MakeGroups,
in double_array ScaleFactors,
in boolean ScaleVariation,
out Extrusion_Error Error)
raises (SALOME::SALOME_Exception);
/*!
* Compute rotation angles for ExtrusionAlongPath as linear variation
* of given angles along path steps
* param PathMesh mesh containing a 1D sub-mesh on the edge, along
* which proceeds the extrusion
* param PathShape is shape(edge); as the mesh can be complex, the edge
* is used to define the sub-mesh for the path
*/
double_array LinearAnglesVariation(in SMESH_Mesh PathMesh,
in GEOM::GEOM_Object PathShape,
in double_array Angles);
enum MirrorType { POINT, AXIS, PLANE };
void Mirror (in smIdType_array IDsOfElements,
in AxisStruct Mirror,
in MirrorType Type,
in boolean Copy)
raises (SALOME::SALOME_Exception);
ListOfGroups MirrorMakeGroups (in smIdType_array IDsOfElements,
in AxisStruct Mirror,
in MirrorType Type)
raises (SALOME::SALOME_Exception);
SMESH_Mesh MirrorMakeMesh (in smIdType_array IDsOfElements,
in AxisStruct Mirror,
in MirrorType Type,
in boolean CopyGroups,
in string MeshName)
raises (SALOME::SALOME_Exception);
void MirrorObject (in SMESH_IDSource theObject,
in AxisStruct Mirror,
in MirrorType Type,
in boolean Copy)
raises (SALOME::SALOME_Exception);
ListOfGroups MirrorObjectMakeGroups (in SMESH_IDSource theObject,
in AxisStruct Mirror,
in MirrorType Type)
raises (SALOME::SALOME_Exception);
SMESH_Mesh MirrorObjectMakeMesh (in SMESH_IDSource theObject,
in AxisStruct Mirror,
in MirrorType Type,
in boolean CopyGroups,
in string MeshName)
raises (SALOME::SALOME_Exception);
void Translate (in smIdType_array IDsOfElements,
in DirStruct Vector,
in boolean Copy)
raises (SALOME::SALOME_Exception);
ListOfGroups TranslateMakeGroups (in smIdType_array IDsOfElements,
in DirStruct Vector)
raises (SALOME::SALOME_Exception);
SMESH_Mesh TranslateMakeMesh (in smIdType_array IDsOfElements,
in DirStruct Vector,
in boolean CopyGroups,
in string MeshName)
raises (SALOME::SALOME_Exception);
void TranslateObject (in SMESH_IDSource theObject,
in DirStruct Vector,
in boolean Copy)
raises (SALOME::SALOME_Exception);
ListOfGroups TranslateObjectMakeGroups (in SMESH_IDSource theObject,
in DirStruct Vector)
raises (SALOME::SALOME_Exception);
SMESH_Mesh TranslateObjectMakeMesh (in SMESH_IDSource theObject,
in DirStruct Vector,
in boolean CopyGroups,
in string MeshName)
raises (SALOME::SALOME_Exception);
void Scale (in SMESH_IDSource theObject,
in PointStruct thePoint,
in double_array theScaleFact,
in boolean Copy)
raises (SALOME::SALOME_Exception);
ListOfGroups ScaleMakeGroups (in SMESH_IDSource theObject,
in PointStruct thePoint,
in double_array theScaleFact)
raises (SALOME::SALOME_Exception);
SMESH_Mesh ScaleMakeMesh (in SMESH_IDSource theObject,
in PointStruct thePoint,
in double_array theScaleFact,
in boolean CopyGroups,
in string MeshName)
raises (SALOME::SALOME_Exception);
void Rotate (in smIdType_array IDsOfElements,
in AxisStruct Axis,
in double AngleInRadians,
in boolean Copy)
raises (SALOME::SALOME_Exception);
ListOfGroups RotateMakeGroups (in smIdType_array IDsOfElements,
in AxisStruct Axis,
in double AngleInRadians)
raises (SALOME::SALOME_Exception);
SMESH_Mesh RotateMakeMesh (in smIdType_array IDsOfElements,
in AxisStruct Axis,
in double AngleInRadians,
in boolean CopyGroups,
in string MeshName)
raises (SALOME::SALOME_Exception);
void RotateObject (in SMESH_IDSource theObject,
in AxisStruct Axis,
in double AngleInRadians,
in boolean Copy)
raises (SALOME::SALOME_Exception);
ListOfGroups RotateObjectMakeGroups (in SMESH_IDSource theObject,
in AxisStruct Axis,
in double AngleInRadians)
raises (SALOME::SALOME_Exception);
SMESH_Mesh RotateObjectMakeMesh (in SMESH_IDSource theObject,
in AxisStruct Axis,
in double AngleInRadians,
in boolean CopyGroups,
in string MeshName)
raises (SALOME::SALOME_Exception);
SMESH_Mesh Offset(in SMESH_IDSource theObject,
in double Value,
in boolean CopyGroups,
in boolean CopyElements,
in string MeshName,
out ListOfGroups Groups)
raises (SALOME::SALOME_Exception);
void FindCoincidentNodes (in double Tolerance,
out array_of_long_array GroupsOfNodes,
in boolean SeparateCornersAndMedium)
raises (SALOME::SALOME_Exception);
void FindCoincidentNodesOnPart (in SMESH_IDSource SubMeshOrGroup,
in double Tolerance,
out array_of_long_array GroupsOfNodes,
in boolean SeparateCornersAndMedium)
raises (SALOME::SALOME_Exception);
void FindCoincidentNodesOnPartBut (in ListOfIDSources SubMeshOrGroup,
in double Tolerance,
out array_of_long_array GroupsOfNodes,
in ListOfIDSources ExceptSubMeshOrGroups,
in boolean SeparateCornersAndMedium)
raises (SALOME::SALOME_Exception);
void MergeNodes (in array_of_long_array GroupsOfNodes,
in SMESH::ListOfIDSources NodesToKeep,
in boolean AvoidMakingHoles)
raises (SALOME::SALOME_Exception);
/*!
* \brief Find elements built on the same nodes.
* \param MeshOrSubMeshOrGroup Mesh or SubMesh, or Group of elements for searching.
* \return List of groups of equal elements.
*/
void FindEqualElements (in ListOfIDSources MeshOrSubMeshOrGroup,
in ListOfIDSources ExceptSubMeshOrGroups,
out array_of_long_array GroupsOfElementsID)
raises (SALOME::SALOME_Exception);
/*!
* \brief Merge elements in each given group.
* \param GroupsOfElementsID Groups of elements for merging.
*/
void MergeElements(in array_of_long_array GroupsOfElementsID,
in SMESH::ListOfIDSources ElementsToKeep)
raises (SALOME::SALOME_Exception);
/*!
* \brief Merge equal elements in the whole mesh.
*/
void MergeEqualElements()
raises (SALOME::SALOME_Exception);
/*!
* If the given ID is a valid node ID (nodeID > 0), just move this node, else
* move the node closest to the point to point's location and return ID of the node
*/
smIdType MoveClosestNodeToPoint(in double x, in double y, in double z, in smIdType nodeID)
raises (SALOME::SALOME_Exception);
/*!
* Return ID of node closest to a given point
*/
smIdType FindNodeClosestTo(in double x, in double y, in double z)
raises (SALOME::SALOME_Exception);
/*!
* Return elements of given type where the given point is IN or ON.
*
* 'ALL' type means elements of any type excluding nodes and 0D elements
*/
smIdType_array FindElementsByPoint(in double x, in double y, in double z, in ElementType type)
raises (SALOME::SALOME_Exception);
/*!
* Searching among the given elements, return elements of given type
* where the given point is IN or ON.
*
* 'ALL' type means elements of any type excluding nodes and 0D elements
*/
smIdType_array FindAmongElementsByPoint(in SMESH_IDSource elements,
in double x, in double y, in double z,
in ElementType type)
raises (SALOME::SALOME_Exception);
/*!
* Project a point to a mesh object.
* Return ID of an element of given type where the given point is projected
* and coordinates of the projection point.
* In the case if nothing found, return -1 and []
*/
smIdType ProjectPoint(in double x,
in double y,
in double z,
in ElementType type,
in SMESH_IDSource meshObject,
out double_array projecton)
raises (SALOME::SALOME_Exception);
/*!
* Return point state in a closed 2D mesh in terms of TopAbs_State enumeration.
* TopAbs_UNKNOWN state means that either mesh is wrong or the analysis fails.
*/
short GetPointState(in double x, in double y, in double z)
raises (SALOME::SALOME_Exception);
/*!
* Check if a 2D mesh is manifold
*/
boolean IsManifold()
raises (SALOME::SALOME_Exception);
/*!
* Check if orientation of 2D elements is coherent
*/
boolean IsCoherentOrientation2D()
raises (SALOME::SALOME_Exception);
/*!
* Partition given 1D elements into groups of contiguous edges.
* A node where number of meeting edges != 2 is a group end.
* An optional startNode is used to orient groups it belongs to.
* \return a list of edge groups and a list of corresponding node groups.
* If a group is closed, the first and last nodes of the group are same.
*/
array_of_long_array Get1DBranches( in SMESH_IDSource edges,
in smIdType startNode,
out array_of_long_array nodeGroups)
raises (SALOME::SALOME_Exception);
/*!
* Return sharp edges of faces and non-manifold ones.
* Optionally add existing edges. Angle is in degrees.
*/
ListOfEdges FindSharpEdges(in double angle, in boolean addExistingEdges)
raises (SALOME::SALOME_Exception);
/*!
* Returns all or only closed FreeBorder's.
*/
ListOfFreeBorders FindFreeBorders(in boolean closedOnly)
raises (SALOME::SALOME_Exception);
/*!
* Fill with 2D elements a hole defined by a FreeBorder.
* Optionally add new faces to a given group, which is returned.
*/
SMESH_Group FillHole(in FreeBorder hole, in string groupName)
raises (SALOME::SALOME_Exception);
/*!
* Returns groups of FreeBorder's coincident within the given tolerance.
* If the tolerance <= 0.0 then one tenth of an average size of elements adjacent
* to free borders being compared is used.
*/
CoincidentFreeBorders FindCoincidentFreeBorders(in double tolerance);
/*!
* Sew FreeBorder's of each group
*/
short SewCoincidentFreeBorders (in CoincidentFreeBorders freeBorders,
in boolean createPolygons,
in boolean createPolyedrs)
raises (SALOME::SALOME_Exception);
enum Sew_Error {
SEW_OK,
SEW_BORDER1_NOT_FOUND,
SEW_BORDER2_NOT_FOUND,
SEW_BOTH_BORDERS_NOT_FOUND,
SEW_BAD_SIDE_NODES,
SEW_VOLUMES_TO_SPLIT,
// for SewSideElements() only:
SEW_DIFF_NB_OF_ELEMENTS,
SEW_TOPO_DIFF_SETS_OF_ELEMENTS,
SEW_BAD_SIDE1_NODES,
SEW_BAD_SIDE2_NODES,
SEW_INTERNAL_ERROR
};
Sew_Error SewFreeBorders (in smIdType FirstNodeID1,
in smIdType SecondNodeID1,
in smIdType LastNodeID1,
in smIdType FirstNodeID2,
in smIdType SecondNodeID2,
in smIdType LastNodeID2,
in boolean CreatePolygons,
in boolean CreatePolyedrs)
raises (SALOME::SALOME_Exception);
Sew_Error SewConformFreeBorders (in smIdType FirstNodeID1,
in smIdType SecondNodeID1,
in smIdType LastNodeID1,
in smIdType FirstNodeID2,
in smIdType SecondNodeID2)
raises (SALOME::SALOME_Exception);
Sew_Error SewBorderToSide (in smIdType FirstNodeIDOnFreeBorder,
in smIdType SecondNodeIDOnFreeBorder,
in smIdType LastNodeIDOnFreeBorder,
in smIdType FirstNodeIDOnSide,
in smIdType LastNodeIDOnSide,
in boolean CreatePolygons,
in boolean CreatePolyedrs)
raises (SALOME::SALOME_Exception);
Sew_Error SewSideElements (in smIdType_array IDsOfSide1Elements,
in smIdType_array IDsOfSide2Elements,
in smIdType NodeID1OfSide1ToMerge,
in smIdType NodeID1OfSide2ToMerge,
in smIdType NodeID2OfSide1ToMerge,
in smIdType NodeID2OfSide2ToMerge)
raises (SALOME::SALOME_Exception);
/*!
* Set new nodes for given element.
* If number of nodes is not corresponded to type of
* element - returns false
*/
boolean ChangeElemNodes(in smIdType id, in smIdType_array newIDs)
raises (SALOME::SALOME_Exception);
/*!
* \brief Duplicates given elements, i.e. creates new elements based on the
* same nodes as the given ones.
* \param theElements - container of elements to duplicate.
* \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 existing group, else a new group is created.
* If \a theGroupName is empty, new elements are not added
* in any group.
* \return a group where the new elements are added. NULL if theGroupName == "".
* \sa DoubleNode()
*/
SMESH_Group DoubleElements( in SMESH_IDSource theElements,
in string theGroupName )
raises (SALOME::SALOME_Exception);
/*!
* \brief Creates a hole in a mesh by doubling the nodes of some particular elements
* \param theNodes - identifiers of nodes to be doubled
* \param theModifiedElems - identifiers of elements to be updated by the new (doubled)
* nodes. If list of element identifiers is empty then nodes are doubled but
* they not assigned to elements
* \return TRUE if operation has been completed successfully, FALSE otherwise
* \sa DoubleNode(), DoubleNodeGroup(), DoubleNodeGroups()
*/
boolean DoubleNodes( in smIdType_array theNodes, in smIdType_array theModifiedElems )
raises (SALOME::SALOME_Exception);
/*!
* \brief Creates a hole in a mesh by doubling the nodes of some particular elements
* This method provided for convenience works as DoubleNodes() described above.
* \param theNodeId - identifier of node to be doubled.
* \param theModifiedElems - identifiers of elements to be updated.
* \return TRUE if operation has been completed successfully, FALSE otherwise
* \sa DoubleNodes(), DoubleNodeGroup(), DoubleNodeGroups()
*/
boolean DoubleNode( in smIdType theNodeId, in smIdType_array theModifiedElems )
raises (SALOME::SALOME_Exception);
/*!
* \brief Creates a hole in a mesh by doubling the nodes of some particular elements
* This method provided for convenience works as DoubleNodes() described above.
* \param theNodes - group of nodes to be doubled.
* \param theModifiedElems - group of elements to be updated.
* \return TRUE if operation has been completed successfully, FALSE otherwise
* \sa DoubleNode(), DoubleNodes(), DoubleNodeGroups(), DoubleNodeGroupNew()
*/
boolean DoubleNodeGroup( in SMESH_GroupBase theNodes,
in SMESH_GroupBase theModifiedElems )
raises (SALOME::SALOME_Exception);
/*!
* \brief Creates a hole in a mesh by doubling the nodes of some particular elements.
* Works as DoubleNodeGroup() described above, but returns a new group with
* newly created nodes.
* \param theNodes - group of nodes to be doubled.
* \param theModifiedElems - group of elements to be updated.
* \return a new group with newly created nodes
* \sa DoubleNodeGroup()
*/
SMESH_Group DoubleNodeGroupNew( in SMESH_GroupBase theNodes,
in SMESH_GroupBase theModifiedElems )
raises (SALOME::SALOME_Exception);
/*!
* \brief Creates a hole in a mesh by doubling the nodes of some particular elements
* This method provided for convenience works as DoubleNodes() described above.
* \param theNodes - list of groups of nodes to be doubled
* \param theModifiedElems - list of groups of elements to be updated.
* \return TRUE if operation has been completed successfully, FALSE otherwise
* \sa DoubleNode(), DoubleNodeGroup(), DoubleNodes()
*/
boolean DoubleNodeGroups( in ListOfGroups theNodes,
in ListOfGroups theModifiedElems )
raises (SALOME::SALOME_Exception);
/*!
* \brief Creates a hole in a mesh by doubling the nodes of some particular elements
* Works as DoubleNodeGroups() described above, but returns a new group with
* newly created nodes.
* \param theNodes - list of groups of nodes to be doubled
* \param theModifiedElems - list of groups of elements to be updated.
* \return a new group with newly created nodes
* \sa DoubleNodeGroups()
*/
SMESH_Group DoubleNodeGroupsNew( in ListOfGroups theNodes,
in ListOfGroups theModifiedElems )
raises (SALOME::SALOME_Exception);
/*!
* \brief Creates a hole in a mesh by doubling the nodes of some particular elements
* \param theElems - the list of elements (edges or faces) to be replicated
* The nodes for duplication could be found from these elements
* \param theNodesNot - list of nodes to NOT replicate
* \param theAffectedElems - the list of elements (cells and edges) to which the
* replicated nodes should be associated to.
* \return TRUE if operation has been completed successfully, FALSE otherwise
* \sa DoubleNodeGroup(), DoubleNodeGroups()
*/
boolean DoubleNodeElem( in smIdType_array theElems,
in smIdType_array theNodesNot,
in smIdType_array theAffectedElems )
raises (SALOME::SALOME_Exception);
/*!
* \brief Creates a hole in a mesh by doubling the nodes of some particular elements
* \param theElems - the list of elements (edges or faces) to be replicated
* The nodes for duplication could be found from these elements
* \param theNodesNot - list of nodes to NOT replicate
* \param theShape - shape to detect affected elements (element which geometric center
* located on or inside shape).
* The replicated nodes should be associated to affected elements.
* \return TRUE if operation has been completed successfully, FALSE otherwise
* \sa DoubleNodeGroupInRegion(), DoubleNodeGroupsInRegion()
*/
boolean DoubleNodeElemInRegion( in smIdType_array theElems,
in smIdType_array theNodesNot,
in GEOM::GEOM_Object theShape )
raises (SALOME::SALOME_Exception);
/*!
* \brief Creates a hole in a mesh by doubling the nodes of some particular elements
* This method provided for convenience works as DoubleNodes() described above.
* \param theElems - group of of elements (edges or faces) to be replicated
* \param theNodesNot - group of nodes not to replicated
* \param theAffectedElems - group of elements to which the replicated nodes
* should be associated to.
* \return TRUE if operation has been completed successfully, FALSE otherwise
* \sa DoubleNodes(), DoubleNodeGroups(), DoubleNodeElemGroupNew()
*/
boolean DoubleNodeElemGroup( in SMESH_GroupBase theElems,
in SMESH_GroupBase theNodesNot,
in SMESH_GroupBase theAffectedElems )
raises (SALOME::SALOME_Exception);
/*!
* \brief Creates a hole in a mesh by doubling the nodes of some particular elements.
* Works as DoubleNodeElemGroup() described above, but returns a new group with
* newly created elements.
* \param theElems - group of of elements (edges or faces) to be replicated
* \param theNodesNot - group of nodes not to replicated
* \param theAffectedElems - group of elements to which the replicated nodes
* should be associated to.
* \return a new group with newly created elements
* \sa DoubleNodeElemGroup()
*/
SMESH_Group DoubleNodeElemGroupNew( in SMESH_GroupBase theElems,
in SMESH_GroupBase theNodesNot,
in SMESH_GroupBase theAffectedElems )
raises (SALOME::SALOME_Exception);
/*!
* \brief Creates a hole in a mesh by doubling the nodes of some particular elements.
* Works as DoubleNodeElemGroup() described above, but returns two new groups:
* a group of newly created elements and a group of newly created nodes
* \param theElems - group of of elements (edges or faces) to be replicated
* \param theNodesNot - group of nodes not to replicated
* \param theAffectedElems - group of elements to which the replicated nodes
* should be associated to.
* \param theElemGroupNeeded - to create group of new elements or not
* \param theNodeGroupNeeded - to create group of new nodes or not
* \return two new groups of newly created elements (1st) and nodes (2nd)
* \sa DoubleNodeElemGroup()
*/
ListOfGroups DoubleNodeElemGroup2New( in SMESH_GroupBase theElems,
in SMESH_GroupBase theNodesNot,
in SMESH_GroupBase theAffectedElems,
in boolean theElemGroupNeeded,
in boolean theNodeGroupNeeded)
raises (SALOME::SALOME_Exception);
/*!
* \brief Creates a hole in a mesh by doubling the nodes of some particular elements
* This method provided for convenience works as DoubleNodes() described above.
* \param theElems - group of elements (edges or faces) to be replicated
* \param theNodesNot - group of nodes not to replicated
* \param theShape - shape to detect affected elements (element which geometric center
* located on or inside shape).
* The replicated nodes should be associated to affected elements.
* \return TRUE if operation has been completed successfully, FALSE otherwise
* \sa DoubleNodesInRegion(), DoubleNodeGroupsInRegion()
*/
boolean DoubleNodeElemGroupInRegion( in SMESH_GroupBase theElems,
in SMESH_GroupBase theNodesNot,
in GEOM::GEOM_Object theShape )
raises (SALOME::SALOME_Exception);
/*!
* \brief Creates a hole in a mesh by doubling the nodes of some particular elements
* This method provided for convenience works as DoubleNodes() described above.
* \param theElems - list of groups of elements (edges or faces) to be replicated
* \param theNodesNot - list of groups of nodes not to replicated
* \param theAffectedElems - group of elements to which the replicated nodes
* should be associated to.
* \return TRUE if operation has been completed successfully, FALSE otherwise
* \sa DoubleNodeGroup(), DoubleNodes(), DoubleNodeElemGroupsNew()
*/
boolean DoubleNodeElemGroups( in ListOfGroups theElems,
in ListOfGroups theNodesNot,
in ListOfGroups theAffectedElems )
raises (SALOME::SALOME_Exception);
/*!
* \brief Creates a hole in a mesh by doubling the nodes of some particular elements.
* Works as DoubleNodeElemGroups() described above, but returns a new group with
* newly created elements.
* \param theElems - list of groups of elements (edges or faces) to be replicated
* \param theNodesNot - list of groups of nodes not to replicated
* \param theAffectedElems - group of elements to which the replicated nodes
* should be associated to.
* \return a new group with newly created elements
* \sa DoubleNodeElemGroups()
*/
SMESH_Group DoubleNodeElemGroupsNew( in ListOfGroups theElems,
in ListOfGroups theNodesNot,
in ListOfGroups theAffectedElems )
raises (SALOME::SALOME_Exception);
/*!
* \brief Creates a hole in a mesh by doubling the nodes of some particular elements.
* Works as DoubleNodeElemGroups() described above, but returns two new groups:
* a group of newly created elements and a group of newly created nodes.
* \param theElems - list of groups of elements (edges or faces) to be replicated
* \param theNodesNot - list of groups of nodes not to replicated
* \param theAffectedElems - group of elements to which the replicated nodes
* should be associated to.
* \param theElemGroupNeeded - to create group of new elements or not
* \param theNodeGroupNeeded - to create group of new nodes or not
* \return two new groups of newly created elements (1st) and nodes (2nd)
* \sa DoubleNodeElemGroups()
*/
ListOfGroups DoubleNodeElemGroups2New( in ListOfGroups theElems,
in ListOfGroups theNodesNot,
in ListOfGroups theAffectedElems,
in boolean theElemGroupNeeded,
in boolean theNodeGroupNeeded )
raises (SALOME::SALOME_Exception);
/*!
* \brief Creates a hole in a mesh by doubling the nodes of some particular elements
* This method provided for convenience works as DoubleNodes() described above.
* \param theElems - list of groups of elements (edges or faces) to be replicated
* \param theNodesNot - list of groups of nodes not to replicated
* \param theShape - shape to detect affected elements (element which geometric center
* located on or inside shape).
* The replicated nodes should be associated to affected elements.
* \return TRUE if operation has been completed successfully, FALSE otherwise
* \sa DoubleNodeGroupInRegion(), DoubleNodesInRegion()
*/
boolean DoubleNodeElemGroupsInRegion( in ListOfGroups theElems,
in ListOfGroups theNodesNot,
in GEOM::GEOM_Object theShape )
raises (SALOME::SALOME_Exception);
/*!
* \brief Identify the elements that will be affected by node duplication (actual duplication is not performed).
* This method is the first step of DoubleNodeElemGroupsInRegion.
* \param theElems - list of groups of elements (edges or faces) to be replicated
* \param theNodesNot - list of groups of nodes not to replicated
* \param theShape - shape to detect affected elements (element which geometric center
* located on or inside shape).
* The replicated nodes should be associated to affected elements.
* \return groups of affected elements
* \sa DoubleNodeElemGroupsInRegion()
*/
ListOfGroups AffectedElemGroupsInRegion( in ListOfGroups theElems,
in ListOfGroups theNodesNot,
in GEOM::GEOM_Object theShape )
raises (SALOME::SALOME_Exception);
/*!
* \brief Generates skin mesh (containing 2D cells) from 3D mesh
* The created 2D mesh elements based on nodes of free faces of boundary volumes
* \return TRUE if operation has been completed successfully, FALSE otherwise
*/
boolean Make2DMeshFrom3D() raises (SALOME::SALOME_Exception);
/*!
* \brief Creates missing boundary elements
* \param elements - elements whose boundary is to be checked
* \param dimension - defines type of boundary elements to create
* BND_1DFROM3D creates mesh edges on all borders of free facets of 3D elements.
* \param groupName - a name of group to store created boundary elements in,
* "" means not to create the group
* \param meshName - a name of new mesh to store created boundary elements in,
* "" means not to create the new mesh
* \param toCopyElements - if true, the checked elements will be copied into the new mesh
* else only boundary elements will be copied into the new mesh
* \param toCopyExistingBondary - if true, not only new but also pre-existing
* boundary elements will be copied into the new mesh
* \param group - returns the create group, if any
* \retval SMESH::SMESH_Mesh - the mesh where elements were added to
*/
SMESH_Mesh MakeBoundaryMesh(in SMESH_IDSource elements,
in Bnd_Dimension dimension,
in string groupName,
in string meshName,
in boolean toCopyElements,
in boolean toCopyExistingBondary,
out SMESH_Group group) raises (SALOME::SALOME_Exception);
/*!
* \brief Creates missing boundary elements around either the whole mesh or
* groups of 2D elements
* \param dimension - defines type of boundary elements to create
* \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
* 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
* \param groups - optional groups of 2D elements to make boundary around
* \param mesh - returns the mesh where elements were added to
* \param group - returns the created group, if any
* \retval long - number of added boundary elements
*/
long MakeBoundaryElements(in Bnd_Dimension dimension,
in string groupName,
in string meshName,
in boolean toCopyAll,
in ListOfIDSources groups,
out SMESH_Mesh mesh,
out SMESH_Group group) raises (SALOME::SALOME_Exception);
/*!
* \brief Double nodes on shared faces between groups of volumes and create flat elements on demand.
* Flat elements are mainly used by some types of mechanic calculations.
*
* The list of groups must describe a partition of the mesh volumes.
* The nodes of the internal faces at the boundaries of the groups are doubled.
* In option, the internal faces are replaced by flat elements.
* Triangles are transformed in prisms, and quadrangles in hexahedrons.
* \param theDomains - list of groups of volumes
* \param createJointElems - if TRUE, create the elements
* \param onAllBoundaries - if TRUE, the nodes and elements are also created on
* the boundary between \a theDomains and the rest mesh
* \return TRUE if operation has been completed successfully, FALSE otherwise
*/
boolean DoubleNodesOnGroupBoundaries( in ListOfGroups theDomains,
in boolean createJointElems,
in boolean onAllBoundaries)
raises (SALOME::SALOME_Exception);
/*!
* \brief 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
* \return TRUE if operation has been completed successfully, FALSE otherwise
*/
boolean CreateFlatElementsOnFacesGroups( in ListOfGroups theGroupsOfFaces )
raises (SALOME::SALOME_Exception);
/*!
* \brief identify all the elements around a geom shape, get the faces delimiting the hole
* Build groups of volume to remove, groups of faces to replace on the skin of the object,
* groups of faces to remove insidethe object, (idem edges).
* Build ordered list of nodes at the border of each group of faces to replace (to be used to build a geom subshape)
*/
void CreateHoleSkin(in double radius,
in GEOM::GEOM_Object theShape,
in string groupName,
in double_array theNodesCoords,
out array_of_long_array GroupsOfNodes)
raises (SALOME::SALOME_Exception);
/*!
* \brief Create a polyline consisting of 1D mesh elements each lying on a 2D element of
* the initial triangle mesh. Positions of new nodes are found by cutting the mesh by
* the plane passing through pairs of points specified by each PolySegment structure.
* If there are several paths connecting a pair of points, the shortest path is
* selected by the module. Position of the cutting plane is defined by the two
* points and an optional vector lying on the plane specified by a PolySegment.
* By default the vector is defined by Mesh module as following. A middle point
* of the two given points is computed. The middle point is projected to the mesh.
* The vector goes from the middle point to the projection point. In case of planar
* mesh, the vector is normal to the mesh.
* \param [inout] segments - PolySegment's defining positions of cutting planes.
* Return the used vector which goes from the middle point to its projection.
* \param [in] groupName - optional name of a group where created mesh segments will
* be added.
*/
void MakePolyLine(inout ListOfPolySegments segments,
in string groupName)
raises (SALOME::SALOME_Exception);
/*!
* \brief Create a slot of given width around given 1D elements lying on a triangle mesh.
* The slot is constructed by cutting faces by cylindrical surfaces made
* around each segment. Segments are expected to be created by MakePolyLine().
* \return Edges located at the slot boundary
*/
ListOfEdges MakeSlot( in SMESH_GroupBase segments,
in double width )
raises (SALOME::SALOME_Exception);
};
};
#endif