smesh/src/StdMeshers/StdMeshers_CompositeHexa_3D.cxx

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2010-05-14 21:32:37 +06:00
// Copyright (C) 2007-2010 CEA/DEN, EDF R&D, OPEN CASCADE
//
// 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.
//
// 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
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//
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// See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
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//
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// SMESH SMESH : implementaion of SMESH idl descriptions
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// File : StdMeshers_CompositeHexa_3D.cxx
// Module : SMESH
// Created : Tue Nov 25 11:04:59 2008
// Author : Edward AGAPOV (eap)
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//
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#include "StdMeshers_CompositeHexa_3D.hxx"
#include "SMDS_Mesh.hxx"
#include "SMDS_MeshNode.hxx"
#include "SMDS_SetIterator.hxx"
#include "SMESH_Block.hxx"
#include "SMESH_Comment.hxx"
#include "SMESH_ComputeError.hxx"
#include "SMESH_Mesh.hxx"
#include "SMESH_MesherHelper.hxx"
#include "SMESH_subMesh.hxx"
#include <BRepAdaptor_Surface.hxx>
#include <BRep_Tool.hxx>
#include <Standard_ErrorHandler.hxx>
#include <Standard_Failure.hxx>
#include <TopExp_Explorer.hxx>
#include <TopTools_MapIteratorOfMapOfShape.hxx>
#include <TopTools_MapOfShape.hxx>
#include <TopTools_SequenceOfShape.hxx>
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#include <TopoDS.hxx>
#include <TopoDS_Edge.hxx>
#include <TopoDS_Face.hxx>
#include <TopoDS_Vertex.hxx>
#include <gp_Pnt.hxx>
#include <gp_Pnt2d.hxx>
#include <gp_Vec.hxx>
#include <gp_XYZ.hxx>
#include <list>
#include <set>
#include <vector>
#ifdef _DEBUG_
// #define DEB_FACES
// #define DEB_GRID
#define DUMP_VERT(msg,V) \
// { TopoDS_Vertex v = V; gp_Pnt p = BRep_Tool::Pnt(v);\
// cout << msg << "( "<< p.X()<<", "<<p.Y()<<", "<<p.Z()<<" )"<<endl;}
#else
#define DUMP_VERT(msg,v)
#endif
//================================================================================
// text for message about an internal error
#define ERR_LI(txt) SMESH_Comment(txt) << ":" << __LINE__
// order corresponds to right order of edges in CASCADE face
enum EQuadSides{ Q_BOTTOM=0, Q_RIGHT, Q_TOP, Q_LEFT, Q_CHILD, Q_PARENT };
enum EBoxSides{ B_BOTTOM=0, B_RIGHT, B_TOP, B_LEFT, B_FRONT, B_BACK, B_UNDEFINED };
//================================================================================
/*!
* \brief Convertor of a pair of integers to a sole index
*/
struct _Indexer
{
int _xSize, _ySize;
_Indexer( int xSize, int ySize ): _xSize(xSize), _ySize(ySize) {}
int size() const { return _xSize * _ySize; }
int operator()(const int x, const int y) const { return y * _xSize + x; }
};
//================================================================================
/*!
* \brief Wrapper of a composite or an ordinary edge.
*/
class _FaceSide
{
public:
_FaceSide(const _FaceSide& other);
_FaceSide(const TopoDS_Edge& edge=TopoDS_Edge());
_FaceSide(const list<TopoDS_Edge>& edges);
_FaceSide* GetSide(const int i);
const _FaceSide* GetSide(const int i) const;
int size() { return myChildren.size(); }
int NbVertices() const;
TopoDS_Vertex FirstVertex() const;
TopoDS_Vertex LastVertex() const;
TopoDS_Vertex Vertex(int i) const;
bool Contain( const _FaceSide& side, int* which=0 ) const;
bool Contain( const TopoDS_Vertex& vertex ) const;
void AppendSide( const _FaceSide& side );
void SetBottomSide( int i );
int GetNbSegments(SMESH_Mesh& mesh) const;
bool StoreNodes(SMESH_Mesh& mesh, vector<const SMDS_MeshNode*>& myGrid, bool reverse );
void SetID(EQuadSides id) { myID = id; }
static inline const TopoDS_TShape* ptr(const TopoDS_Shape& theShape)
{ return theShape.TShape().operator->(); }
void Dump() const;
private:
TopoDS_Edge myEdge;
list< _FaceSide > myChildren;
int myNbChildren;
//set<const TopoDS_TShape*> myVertices;
TopTools_MapOfShape myVertices;
EQuadSides myID; // debug
};
//================================================================================
/*!
* \brief Class corresponding to a meshed composite face of a box.
* Provides simplified access to it's sub-mesh data.
*/
class _QuadFaceGrid
{
typedef list< _QuadFaceGrid > TChildren;
public:
_QuadFaceGrid();
public: //** Methods to find and orient faces of 6 sides of the box **//
//!< initialization
bool Init(const TopoDS_Face& f);
//!< try to unite self with other face
bool AddContinuousFace( const _QuadFaceGrid& f );
//!< Try to set the side as bottom hirizontal side
bool SetBottomSide(const _FaceSide& side, int* sideIndex=0);
//!< Return face adjacent to i-th side of this face
_QuadFaceGrid* FindAdjacentForSide(int i, vector<_QuadFaceGrid>& faces) const; // (0<i<4)
//!< Reverse edges in order to have the bottom edge going along axes of the unit box
void ReverseEdges(/*int e1, int e2*/);
bool IsComplex() const { return !myChildren.empty(); }
typedef SMDS_SetIterator< const _QuadFaceGrid&, TChildren::const_iterator > TChildIterator;
TChildIterator GetChildren() const
{ return TChildIterator( myChildren.begin(), myChildren.end()); }
public: //** Loading and access to mesh **//
//!< Load nodes of a mesh
bool LoadGrid( SMESH_Mesh& mesh );
//!< Return number of segments on the hirizontal sides
int GetNbHoriSegments(SMESH_Mesh& mesh, bool withBrothers=false) const;
//!< Return number of segments on the vertical sides
int GetNbVertSegments(SMESH_Mesh& mesh, bool withBrothers=false) const;
//!< Return a node by its position
const SMDS_MeshNode* GetNode(int iHori, int iVert) const;
//!< Return node coordinates by its position
gp_XYZ GetXYZ(int iHori, int iVert) const;
public: //** Access to member fields **//
//!< Return i-th face side (0<i<4)
const _FaceSide& GetSide(int i) const;
//!< Return it's face, NULL if it is composite
TopoDS_Face GetFace() const { return myFace; }
//!< Return normal to the face at vertex v
bool GetNormal( const TopoDS_Vertex& v, gp_Vec& n ) const;
SMESH_ComputeErrorPtr GetError() const { return myError; }
void SetID(EBoxSides id) { myID = id; }
void DumpGrid() const;
void DumpVertices() const;
private:
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bool error(const std::string& text, int code = COMPERR_ALGO_FAILED)
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{ myError = SMESH_ComputeError::New( code, text ); return false; }
bool error(const SMESH_ComputeErrorPtr& err)
{ myError = err; return ( !myError || myError->IsOK() ); }
bool loadCompositeGrid(SMESH_Mesh& mesh);
bool fillGrid(SMESH_Mesh& theMesh,
vector<const SMDS_MeshNode*> & theGrid,
const _Indexer& theIndexer,
int theX,
int theY);
bool locateChildren();
void setBrothers( set< _QuadFaceGrid* >& notLocatedBrothers );
TopoDS_Face myFace;
_FaceSide mySides;
bool myReverse;
TChildren myChildren;
_QuadFaceGrid* myLeftBottomChild;
_QuadFaceGrid* myRightBrother;
_QuadFaceGrid* myUpBrother;
_Indexer myIndexer;
vector<const SMDS_MeshNode*> myGrid;
SMESH_ComputeErrorPtr myError;
EBoxSides myID; // debug
};
//================================================================================
/*!
* \brief Constructor
*/
//================================================================================
StdMeshers_CompositeHexa_3D::StdMeshers_CompositeHexa_3D(int hypId, int studyId, SMESH_Gen* gen)
:SMESH_3D_Algo(hypId, studyId, gen)
{
_name = "CompositeHexa_3D";
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_shapeType = (1 << TopAbs_SHELL) | (1 << TopAbs_SOLID); // 1 bit /shape type
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}
//================================================================================
/*!
* \brief always return true
*/
//================================================================================
bool StdMeshers_CompositeHexa_3D::CheckHypothesis(SMESH_Mesh& aMesh,
const TopoDS_Shape& aShape,
Hypothesis_Status& aStatus)
{
aStatus = HYP_OK;
return true;
}
//================================================================================
/*!
* \brief Computes hexahedral mesh on a box with composite sides
* \param aMesh - mesh to compute
* \param aShape - shape to mesh
* \retval bool - succes sign
*/
//================================================================================
bool StdMeshers_CompositeHexa_3D::Compute(SMESH_Mesh& theMesh,
const TopoDS_Shape& theShape)
{
SMESH_MesherHelper helper( theMesh );
_quadraticMesh = helper.IsQuadraticSubMesh( theShape );
helper.SetElementsOnShape( true );
// -------------------------
// Try to find 6 side faces
// -------------------------
vector< _QuadFaceGrid > boxFaces; boxFaces.reserve( 6 );
TopExp_Explorer exp;
int iFace, nbFaces = 0;
for ( exp.Init(theShape, TopAbs_FACE); exp.More(); exp.Next(), ++nbFaces )
{
_QuadFaceGrid f;
if ( !f.Init( TopoDS::Face( exp.Current() )))
return error (COMPERR_BAD_SHAPE);
bool isContinuous = false;
for ( int i=0; i < boxFaces.size() && !isContinuous; ++i )
isContinuous = boxFaces[ i ].AddContinuousFace( f );
if ( !isContinuous )
boxFaces.push_back( f );
}
// Check what we have
if ( boxFaces.size() != 6 && nbFaces != 6)
return error
(COMPERR_BAD_SHAPE,
SMESH_Comment("Can't find 6 sides of a box. Number of found sides - ")<<boxFaces.size());
if ( boxFaces.size() != 6 && nbFaces == 6 ) { // strange ordinary box with continuous faces
boxFaces.resize( 6 );
iFace = 0;
for ( exp.Init(theShape, TopAbs_FACE); exp.More(); exp.Next(), ++iFace )
boxFaces[ iFace ].Init( TopoDS::Face( exp.Current() ) );
}
// ----------------------------------------
// Find out position of faces within a box
// ----------------------------------------
_QuadFaceGrid *fBottom, *fTop, *fFront, *fBack, *fLeft, *fRight;
// start from a bottom face
fBottom = &boxFaces[0];
// find vertical faces
fFront = fBottom->FindAdjacentForSide( Q_BOTTOM, boxFaces );
fLeft = fBottom->FindAdjacentForSide( Q_RIGHT, boxFaces );
fBack = fBottom->FindAdjacentForSide( Q_TOP, boxFaces );
fRight = fBottom->FindAdjacentForSide( Q_LEFT, boxFaces );
// check the found
if ( !fFront || !fBack || !fLeft || !fRight )
return error(COMPERR_BAD_SHAPE);
// top face
fTop = 0;
for ( int i=1; i < boxFaces.size() && !fTop; ++i ) {
fTop = & boxFaces[ i ];
if ( fTop==fFront || fTop==fLeft || fTop==fBack || fTop==fRight )
fTop = 0;
}
// set bottom of the top side
if ( !fTop->SetBottomSide( fFront->GetSide( Q_TOP ) )) {
if ( !fFront->IsComplex() )
return error( ERR_LI("Error in StdMeshers_CompositeHexa_3D::Compute()"));
else {
_QuadFaceGrid::TChildIterator chIt = fFront->GetChildren();
while ( chIt.more() ) {
const _QuadFaceGrid& frontChild = chIt.next();
if ( fTop->SetBottomSide( frontChild.GetSide( Q_TOP )))
break;
}
}
}
if ( !fTop )
return error(COMPERR_BAD_SHAPE);
fBottom->SetID( B_BOTTOM );
fBack ->SetID( B_BACK );
fLeft ->SetID( B_LEFT );
fFront ->SetID( B_FRONT );
fRight ->SetID( B_RIGHT );
fTop ->SetID( B_TOP );
// orient bottom egde of faces along axes of the unit box
fBottom->ReverseEdges();
fBack ->ReverseEdges();
fLeft ->ReverseEdges();
// ------------------------------------------
// Fill columns of nodes with existing nodes
// ------------------------------------------
// let faces load their grids
if ( !fBottom->LoadGrid( theMesh )) return error( fBottom->GetError() );
if ( !fBack ->LoadGrid( theMesh )) return error( fBack ->GetError() );
if ( !fLeft ->LoadGrid( theMesh )) return error( fLeft ->GetError() );
if ( !fFront ->LoadGrid( theMesh )) return error( fFront ->GetError() );
if ( !fRight ->LoadGrid( theMesh )) return error( fRight ->GetError() );
if ( !fTop ->LoadGrid( theMesh )) return error( fTop ->GetError() );
int x, xSize = fBottom->GetNbHoriSegments(theMesh) + 1, X = xSize - 1;
int y, ySize = fBottom->GetNbVertSegments(theMesh) + 1, Y = ySize - 1;
int z, zSize = fFront ->GetNbVertSegments(theMesh) + 1, Z = zSize - 1;
_Indexer colIndex( xSize, ySize );
vector< vector< const SMDS_MeshNode* > > columns( colIndex.size() );
// fill node columns by front and back box sides
for ( x = 0; x < xSize; ++x ) {
vector< const SMDS_MeshNode* >& column0 = columns[ colIndex( x, 0 )];
vector< const SMDS_MeshNode* >& column1 = columns[ colIndex( x, Y )];
column0.resize( zSize );
column1.resize( zSize );
for ( z = 0; z < zSize; ++z ) {
column0[ z ] = fFront->GetNode( x, z );
column1[ z ] = fBack ->GetNode( x, z );
}
}
// fill node columns by left and right box sides
for ( y = 1; y < ySize-1; ++y ) {
vector< const SMDS_MeshNode* >& column0 = columns[ colIndex( 0, y )];
vector< const SMDS_MeshNode* >& column1 = columns[ colIndex( X, y )];
column0.resize( zSize );
column1.resize( zSize );
for ( z = 0; z < zSize; ++z ) {
column0[ z ] = fLeft ->GetNode( y, z );
column1[ z ] = fRight->GetNode( y, z );
}
}
// get nodes from top and bottom box sides
for ( x = 1; x < xSize-1; ++x ) {
for ( y = 1; y < ySize-1; ++y ) {
vector< const SMDS_MeshNode* >& column = columns[ colIndex( x, y )];
column.resize( zSize );
column.front() = fBottom->GetNode( x, y );
column.back() = fTop ->GetNode( x, y );
}
}
// ----------------------------
// Add internal nodes of a box
// ----------------------------
// projection points of internal nodes on box subshapes by which
// coordinates of internal nodes are computed
vector<gp_XYZ> pointsOnShapes( SMESH_Block::ID_Shell );
// projections on vertices are constant
pointsOnShapes[ SMESH_Block::ID_V000 ] = fBottom->GetXYZ( 0, 0 );
pointsOnShapes[ SMESH_Block::ID_V100 ] = fBottom->GetXYZ( X, 0 );
pointsOnShapes[ SMESH_Block::ID_V010 ] = fBottom->GetXYZ( 0, Y );
pointsOnShapes[ SMESH_Block::ID_V110 ] = fBottom->GetXYZ( X, Y );
pointsOnShapes[ SMESH_Block::ID_V001 ] = fTop->GetXYZ( 0, 0 );
pointsOnShapes[ SMESH_Block::ID_V101 ] = fTop->GetXYZ( X, 0 );
pointsOnShapes[ SMESH_Block::ID_V011 ] = fTop->GetXYZ( 0, Y );
pointsOnShapes[ SMESH_Block::ID_V111 ] = fTop->GetXYZ( X, Y );
for ( x = 1; x < xSize-1; ++x )
{
gp_XYZ params; // normalized parameters of internal node within a unit box
params.SetCoord( 1, x / double(X) );
for ( y = 1; y < ySize-1; ++y )
{
params.SetCoord( 2, y / double(Y) );
// column to fill during z loop
vector< const SMDS_MeshNode* >& column = columns[ colIndex( x, y )];
// points projections on horizontal edges
pointsOnShapes[ SMESH_Block::ID_Ex00 ] = fBottom->GetXYZ( x, 0 );
pointsOnShapes[ SMESH_Block::ID_Ex10 ] = fBottom->GetXYZ( x, Y );
pointsOnShapes[ SMESH_Block::ID_E0y0 ] = fBottom->GetXYZ( 0, y );
pointsOnShapes[ SMESH_Block::ID_E1y0 ] = fBottom->GetXYZ( X, y );
pointsOnShapes[ SMESH_Block::ID_Ex01 ] = fTop->GetXYZ( x, 0 );
pointsOnShapes[ SMESH_Block::ID_Ex11 ] = fTop->GetXYZ( x, Y );
pointsOnShapes[ SMESH_Block::ID_E0y1 ] = fTop->GetXYZ( 0, y );
pointsOnShapes[ SMESH_Block::ID_E1y1 ] = fTop->GetXYZ( X, y );
// points projections on horizontal faces
pointsOnShapes[ SMESH_Block::ID_Fxy0 ] = fBottom->GetXYZ( x, y );
pointsOnShapes[ SMESH_Block::ID_Fxy1 ] = fTop ->GetXYZ( x, y );
for ( z = 1; z < zSize-1; ++z ) // z loop
{
params.SetCoord( 3, z / double(Z) );
// point projections on vertical edges
pointsOnShapes[ SMESH_Block::ID_E00z ] = fFront->GetXYZ( 0, z );
pointsOnShapes[ SMESH_Block::ID_E10z ] = fFront->GetXYZ( X, z );
pointsOnShapes[ SMESH_Block::ID_E01z ] = fBack->GetXYZ( 0, z );
pointsOnShapes[ SMESH_Block::ID_E11z ] = fBack->GetXYZ( X, z );
// point projections on vertical faces
pointsOnShapes[ SMESH_Block::ID_Fx0z ] = fFront->GetXYZ( x, z );
pointsOnShapes[ SMESH_Block::ID_Fx1z ] = fBack ->GetXYZ( x, z );
pointsOnShapes[ SMESH_Block::ID_F0yz ] = fLeft ->GetXYZ( y, z );
pointsOnShapes[ SMESH_Block::ID_F1yz ] = fRight->GetXYZ( y, z );
// compute internal node coordinates
gp_XYZ coords;
SMESH_Block::ShellPoint( params, pointsOnShapes, coords );
column[ z ] = helper.AddNode( coords.X(), coords.Y(), coords.Z() );
#ifdef DEB_GRID
// debug
//cout << "----------------------------------------------------------------------"<<endl;
//for ( int id = SMESH_Block::ID_V000; id < SMESH_Block::ID_Shell; ++id)
//{
// gp_XYZ p = pointsOnShapes[ id ];
// SMESH_Block::DumpShapeID( id,cout)<<" ( "<<p.X()<<", "<<p.Y()<<", "<<p.Z()<<" )"<<endl;
//}
//cout << "Params: ( "<< params.X()<<", "<<params.Y()<<", "<<params.Z()<<" )"<<endl;
//cout << "coords: ( "<< coords.X()<<", "<<coords.Y()<<", "<<coords.Z()<<" )"<<endl;
#endif
}
}
}
// faces no more needed, free memory
boxFaces.clear();
// ----------------
// Add hexahedrons
// ----------------
for ( x = 0; x < xSize-1; ++x ) {
for ( y = 0; y < ySize-1; ++y ) {
vector< const SMDS_MeshNode* >& col00 = columns[ colIndex( x, y )];
vector< const SMDS_MeshNode* >& col10 = columns[ colIndex( x+1, y )];
vector< const SMDS_MeshNode* >& col01 = columns[ colIndex( x, y+1 )];
vector< const SMDS_MeshNode* >& col11 = columns[ colIndex( x+1, y+1 )];
for ( z = 0; z < zSize-1; ++z )
{
// bottom face normal of a hexa mush point outside the volume
helper.AddVolume(col00[z], col01[z], col11[z], col10[z],
col00[z+1], col01[z+1], col11[z+1], col10[z+1]);
}
}
}
return true;
}
//=======================================================================
//function : GetNb2d
//purpose : auxilary for Evaluate
//=======================================================================
int GetNb2d(_QuadFaceGrid* QFG, SMESH_Mesh& theMesh,
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MapShapeNbElems& aResMap)
{
int nb2d = 0;
_QuadFaceGrid::TChildIterator aCI = QFG->GetChildren();
while( aCI.more() ) {
const _QuadFaceGrid& currChild = aCI.next();
SMESH_subMesh *sm = theMesh.GetSubMesh(currChild.GetFace());
if( sm ) {
MapShapeNbElemsItr anIt = aResMap.find(sm);
if( anIt == aResMap.end() ) continue;
std::vector<int> aVec = (*anIt).second;
nb2d += Max(aVec[SMDSEntity_Quadrangle],aVec[SMDSEntity_Quad_Quadrangle]);
}
}
return nb2d;
}
//================================================================================
/*!
* Evaluate
*/
//================================================================================
bool StdMeshers_CompositeHexa_3D::Evaluate(SMESH_Mesh& theMesh,
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const TopoDS_Shape& theShape,
MapShapeNbElems& aResMap)
{
SMESH_MesherHelper aTool(theMesh);
bool _quadraticMesh = aTool.IsQuadraticSubMesh(theShape);
// -------------------------
// Try to find 6 side faces
// -------------------------
vector< _QuadFaceGrid > boxFaces; boxFaces.reserve( 6 );
TopExp_Explorer exp;
int iFace, nbFaces = 0;
for ( exp.Init(theShape, TopAbs_FACE); exp.More(); exp.Next(), ++nbFaces )
{
_QuadFaceGrid f;
if ( !f.Init( TopoDS::Face( exp.Current() )))
//return error (COMPERR_BAD_SHAPE);
return false;
bool isContinuous = false;
for ( int i=0; i < boxFaces.size() && !isContinuous; ++i )
isContinuous = boxFaces[ i ].AddContinuousFace( f );
if ( !isContinuous )
boxFaces.push_back( f );
}
// Check what we have
if ( boxFaces.size() != 6 && nbFaces != 6)
//return error
// (COMPERR_BAD_SHAPE,
// SMESH_Comment("Can't find 6 sides of a box. Number of found sides - ")<<boxFaces.size());
return false;
if ( boxFaces.size() != 6 && nbFaces == 6 ) { // strange ordinary box with continuous faces
boxFaces.resize( 6 );
iFace = 0;
for ( exp.Init(theShape, TopAbs_FACE); exp.More(); exp.Next(), ++iFace )
boxFaces[ iFace ].Init( TopoDS::Face( exp.Current() ) );
}
// ----------------------------------------
// Find out position of faces within a box
// ----------------------------------------
_QuadFaceGrid *fBottom, *fTop, *fFront, *fBack, *fLeft, *fRight;
// start from a bottom face
fBottom = &boxFaces[0];
// find vertical faces
fFront = fBottom->FindAdjacentForSide( Q_BOTTOM, boxFaces );
fLeft = fBottom->FindAdjacentForSide( Q_RIGHT, boxFaces );
fBack = fBottom->FindAdjacentForSide( Q_TOP, boxFaces );
fRight = fBottom->FindAdjacentForSide( Q_LEFT, boxFaces );
// check the found
if ( !fFront || !fBack || !fLeft || !fRight )
//return error(COMPERR_BAD_SHAPE);
return false;
// top face
fTop = 0;
int i = 1;
for(; i < boxFaces.size() && !fTop; ++i ) {
fTop = & boxFaces[ i ];
if ( fTop==fFront || fTop==fLeft || fTop==fBack || fTop==fRight )
fTop = 0;
}
// set bottom of the top side
if ( !fTop->SetBottomSide( fFront->GetSide( Q_TOP ) )) {
if ( !fFront->IsComplex() )
//return error( ERR_LI("Error in StdMeshers_CompositeHexa_3D::Compute()"));
return false;
else {
_QuadFaceGrid::TChildIterator chIt = fFront->GetChildren();
while ( chIt.more() ) {
const _QuadFaceGrid& frontChild = chIt.next();
if ( fTop->SetBottomSide( frontChild.GetSide( Q_TOP )))
break;
}
}
}
if ( !fTop )
//return error(COMPERR_BAD_SHAPE);
return false;
TopTools_SequenceOfShape BottomFaces;
_QuadFaceGrid::TChildIterator aCI = fBottom->GetChildren();
while( aCI.more() ) {
const _QuadFaceGrid& currChild = aCI.next();
BottomFaces.Append(currChild.GetFace());
}
// find boundary edges and internal nodes for bottom face
TopTools_SequenceOfShape BndEdges;
int nb0d_in = 0;
//TopTools_MapOfShape BndEdges;
for(i=1; i<=BottomFaces.Length(); i++) {
for (TopExp_Explorer exp(BottomFaces.Value(i), TopAbs_EDGE); exp.More(); exp.Next()) {
int nb0 = 0;
SMESH_subMesh *sm = theMesh.GetSubMesh(exp.Current());
if( sm ) {
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MapShapeNbElemsItr anIt = aResMap.find(sm);
if( anIt == aResMap.end() ) continue;
std::vector<int> aVec = (*anIt).second;
nb0 = aVec[SMDSEntity_Node];
}
int j = 1;
for(; j<=BndEdges.Length(); j++) {
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if( BndEdges.Value(j) == exp.Current() ) {
// internal edge => remove it
BndEdges.Remove(j);
nb0d_in += nb0;
break;
}
}
if( j > BndEdges.Length() ) {
2009-12-08 18:11:42 +05:00
BndEdges.Append(exp.Current());
}
//if( BndEdges.Contains(exp.Current()) ) {
//BndEdges.Remove( exp.Current() );
//}
//else {
//BndEdges.Add( exp.Current() );
//}
}
}
// find number of 1d elems for bottom face
int nb1d = 0;
for(i=1; i<=BndEdges.Length(); i++) {
SMESH_subMesh *sm = theMesh.GetSubMesh(BndEdges.Value(i));
if( sm ) {
MapShapeNbElemsItr anIt = aResMap.find(sm);
if( anIt == aResMap.end() ) continue;
std::vector<int> aVec = (*anIt).second;
nb1d += Max(aVec[SMDSEntity_Edge],aVec[SMDSEntity_Quad_Edge]);
}
}
// find number of 2d elems on side faces
int nb2d = 0;
nb2d += GetNb2d(fFront, theMesh, aResMap);
nb2d += GetNb2d(fRight, theMesh, aResMap);
nb2d += GetNb2d(fBack, theMesh, aResMap);
nb2d += GetNb2d(fLeft, theMesh, aResMap);
// find number of 2d elems and nodes on bottom faces
int nb0d=0, nb2d_3=0, nb2d_4=0;
for(i=1; i<=BottomFaces.Length(); i++) {
SMESH_subMesh *sm = theMesh.GetSubMesh(BottomFaces.Value(i));
if( sm ) {
MapShapeNbElemsItr anIt = aResMap.find(sm);
if( anIt == aResMap.end() ) continue;
std::vector<int> aVec = (*anIt).second;
nb0d += aVec[SMDSEntity_Node];
nb2d_3 += Max(aVec[SMDSEntity_Triangle], aVec[SMDSEntity_Quad_Triangle]);
nb2d_4 += Max(aVec[SMDSEntity_Quadrangle], aVec[SMDSEntity_Quad_Quadrangle]);
}
}
nb0d += nb0d_in;
std::vector<int> aResVec(SMDSEntity_Last);
for(int i=SMDSEntity_Node; i<SMDSEntity_Last; i++) aResVec[i] = 0;
if(_quadraticMesh) {
aResVec[SMDSEntity_Quad_Penta] = nb2d_3 * ( nb2d/nb1d );
aResVec[SMDSEntity_Quad_Hexa] = nb2d_4 * ( nb2d/nb1d );
aResVec[SMDSEntity_Node] = nb0d * ( 2*nb2d/nb1d - 1 );
}
else {
aResVec[SMDSEntity_Node] = nb0d * ( nb2d/nb1d - 1 );
aResVec[SMDSEntity_Penta] = nb2d_3 * ( nb2d/nb1d );
aResVec[SMDSEntity_Hexa] = nb2d_4 * ( nb2d/nb1d );
}
SMESH_subMesh * sm = theMesh.GetSubMesh(theShape);
aResMap.insert(std::make_pair(sm,aResVec));
return true;
}
2009-02-17 10:27:49 +05:00
//================================================================================
/*!
* \brief constructor of non-initialized _QuadFaceGrid
*/
//================================================================================
_QuadFaceGrid::_QuadFaceGrid():
myReverse(false), myRightBrother(0), myUpBrother(0), myIndexer(0,0), myID(B_UNDEFINED)
{
}
//================================================================================
/*!
* \brief Initialization
*/
//================================================================================
bool _QuadFaceGrid::Init(const TopoDS_Face& f)
{
myFace = f;
mySides = _FaceSide();
myReverse = false;
myLeftBottomChild = myRightBrother = myUpBrother = 0;
myChildren.clear();
myGrid.clear();
//if ( myFace.Orientation() != TopAbs_FORWARD )
//myFace.Reverse();
TopoDS_Vertex V;
list< TopoDS_Edge > edges;
list< int > nbEdgesInWire;
int nbWire = SMESH_Block::GetOrderedEdges (myFace, V, edges, nbEdgesInWire);
if ( nbWire != 1 )
return false;
list< TopoDS_Edge >::iterator edgeIt = edges.begin();
if ( nbEdgesInWire.front() == 4 ) // exactly 4 edges
{
for ( ; edgeIt != edges.end(); ++edgeIt )
mySides.AppendSide( _FaceSide( *edgeIt ));
}
else if ( nbEdgesInWire.front() > 4 ) { // more than 4 edges - try to unite some
list< TopoDS_Edge > sideEdges;
while ( !edges.empty()) {
sideEdges.clear();
sideEdges.splice( sideEdges.end(), edges, edges.begin());// edges.front()->sideEdges.back()
while ( !edges.empty() ) {
if ( SMESH_Algo::IsContinuous( sideEdges.back(), edges.front() )) {
sideEdges.splice( sideEdges.end(), edges, edges.begin());
}
else if ( SMESH_Algo::IsContinuous( sideEdges.front(), edges.back() )) {
sideEdges.splice( sideEdges.begin(), edges, --edges.end());
}
else {
break;
}
}
mySides.AppendSide( _FaceSide( sideEdges ));
}
}
if (mySides.size() != 4)
return false;
#ifdef _DEBUG_
mySides.GetSide( Q_BOTTOM )->SetID( Q_BOTTOM );
mySides.GetSide( Q_RIGHT )->SetID( Q_RIGHT );
mySides.GetSide( Q_TOP )->SetID( Q_TOP );
mySides.GetSide( Q_LEFT )->SetID( Q_LEFT );
#endif
return true;
}
//================================================================================
/*!
* \brief Try to unite self with other ordinary face
*/
//================================================================================
bool _QuadFaceGrid::AddContinuousFace( const _QuadFaceGrid& other )
{
for ( int i = 0; i < 4; ++i ) {
const _FaceSide& otherSide = other.GetSide( i );
int iMyCommon;
if ( mySides.Contain( otherSide, &iMyCommon ) ) {
// check if normals of two faces are collinear at all vertices of a otherSide
const double angleTol = PI / 180 / 2;
int iV, nbV = otherSide.NbVertices(), nbCollinear = 0;
for ( iV = 0; iV < nbV; ++iV )
{
TopoDS_Vertex v = otherSide.Vertex( iV );
gp_Vec n1, n2;
if ( !GetNormal( v, n1 ) || !other.GetNormal( v, n2 ))
continue;
if ( n1 * n2 < 0 )
n1.Reverse();
if ( n1.Angle(n2) < angleTol )
nbCollinear++;
else
break;
}
if ( nbCollinear > 1 ) { // this face becomes composite if not yet is
DUMP_VERT("Cont 1", mySides.GetSide(iMyCommon)->FirstVertex());
DUMP_VERT("Cont 2", mySides.GetSide(iMyCommon)->LastVertex());
DUMP_VERT("Cont 3", otherSide.FirstVertex());
DUMP_VERT("Cont 4", otherSide.LastVertex());
if ( myChildren.empty() ) {
myChildren.push_back( *this );
myFace.Nullify();
}
myChildren.push_back( other );
int otherBottomIndex = ( 4 + i - iMyCommon + 2 ) % 4;
myChildren.back().SetBottomSide( other.GetSide( otherBottomIndex ));
// collect vertices in mySides
mySides.AppendSide( other.GetSide(0) );
mySides.AppendSide( other.GetSide(1) );
mySides.AppendSide( other.GetSide(2) );
mySides.AppendSide( other.GetSide(3) );
return true;
}
}
}
return false;
}
//================================================================================
/*!
* \brief Try to set the side as bottom hirizontal side
*/
//================================================================================
bool _QuadFaceGrid::SetBottomSide(const _FaceSide& bottom, int* sideIndex)
{
myLeftBottomChild = myRightBrother = myUpBrother = 0;
int myBottomIndex;
if ( myChildren.empty() )
{
if ( mySides.Contain( bottom, &myBottomIndex )) {
mySides.SetBottomSide( myBottomIndex );
if ( sideIndex )
*sideIndex = myBottomIndex;
return true;
}
}
else
{
TChildren::iterator childFace = myChildren.begin(), childEnd = myChildren.end();
for ( ; childFace != childEnd; ++childFace )
{
if ( childFace->SetBottomSide( bottom, &myBottomIndex ))
{
TChildren::iterator orientedCild = childFace;
for ( childFace = myChildren.begin(); childFace != childEnd; ++childFace ) {
if ( childFace != orientedCild )
childFace->SetBottomSide( childFace->GetSide( myBottomIndex ));
}
if ( sideIndex )
*sideIndex = myBottomIndex;
return true;
}
}
}
return false;
}
//================================================================================
/*!
* \brief Return face adjacent to i-th side of this face, (0<i<4)
*/
//================================================================================
_QuadFaceGrid* _QuadFaceGrid::FindAdjacentForSide(int i, vector<_QuadFaceGrid>& faces) const
{
for ( int iF = 0; iF < faces.size(); ++iF ) {
_QuadFaceGrid* f = &faces[ iF ];
if ( f != this && f->SetBottomSide( GetSide( i )))
return f;
}
return (_QuadFaceGrid*) 0;
}
//================================================================================
/*!
* \brief Return i-th side
*/
//================================================================================
const _FaceSide& _QuadFaceGrid::GetSide(int i) const
{
if ( myChildren.empty() )
return *mySides.GetSide(i);
_QuadFaceGrid* me = const_cast<_QuadFaceGrid*>(this);
if ( !me->locateChildren() || !myLeftBottomChild )
return *mySides.GetSide(i);
const _QuadFaceGrid* child = myLeftBottomChild;
switch ( i ){
case Q_BOTTOM:
case Q_LEFT:
break;
case Q_RIGHT:
while ( child->myRightBrother )
child = child->myRightBrother;
break;
case Q_TOP:
while ( child->myUpBrother )
child = child->myUpBrother;
break;
default: ;
}
return child->GetSide( i );
}
//================================================================================
/*!
* \brief Reverse edges in order to have them oriented along axes of the unit box
*/
//================================================================================
void _QuadFaceGrid::ReverseEdges(/*int e1, int e2*/)
{
myReverse = !myReverse;
// #ifdef DEB_FACES
// if ( !myFace.IsNull() )
// TopAbs::Print(myFace.Orientation(), cout);
// #endif
if ( myChildren.empty() )
{
// mySides.GetSide( e1 )->Reverse();
// mySides.GetSide( e2 )->Reverse();
DumpVertices();
}
else
{
DumpVertices();
TChildren::iterator child = myChildren.begin(), childEnd = myChildren.end();
for ( ; child != childEnd; ++child )
child->ReverseEdges( /*e1, e2*/ );
}
}
//================================================================================
/*!
* \brief Load nodes of a mesh
*/
//================================================================================
bool _QuadFaceGrid::LoadGrid( SMESH_Mesh& mesh )
{
if ( !myChildren.empty() )
{
// Let child faces load their grids
TChildren::iterator child = myChildren.begin(), childEnd = myChildren.end();
for ( ; child != childEnd; ++child ) {
child->SetID( myID );
if ( !child->LoadGrid( mesh ) )
return error( child->GetError() );
}
// Fill myGrid with nodes of patches
return loadCompositeGrid( mesh );
}
// ---------------------------------------
// Fill myGrid with nodes bound to myFace
// ---------------------------------------
if ( !myGrid.empty() )
return true;
2010-06-10 15:43:07 +06:00
SMESHDS_SubMesh* faceSubMesh = mesh.GetSubMesh( myFace )->GetSubMeshDS();
// check that all faces are quadrangular
SMDS_ElemIteratorPtr fIt = faceSubMesh->GetElements();
while ( fIt->more() )
if ( fIt->next()->NbNodes() % 4 > 0 )
return error("Non-quadrangular mesh faces are not allowed on sides of a composite block");
2009-02-17 10:27:49 +05:00
myIndexer._xSize = 1 + mySides.GetSide( Q_BOTTOM )->GetNbSegments( mesh );
myIndexer._ySize = 1 + mySides.GetSide( Q_LEFT )->GetNbSegments( mesh );
myGrid.resize( myIndexer.size() );
// strore nodes bound to the bottom edge
mySides.GetSide( Q_BOTTOM )->StoreNodes( mesh, myGrid, myReverse );
// store the rest nodes row by row
SMDS_MeshNode dummy(0,0,0);
const SMDS_MeshElement* firstQuad = &dummy;// most left face above the last row of found nodes
int nbFoundNodes = myIndexer._xSize;
while ( nbFoundNodes != myGrid.size() )
{
// first and last nodes of the last filled row of nodes
const SMDS_MeshNode* n1down = myGrid[ nbFoundNodes - myIndexer._xSize ];
const SMDS_MeshNode* n2down = myGrid[ nbFoundNodes - myIndexer._xSize + 1];
const SMDS_MeshNode* n1downLast = myGrid[ nbFoundNodes-1 ];
// find the first face above the row by the first two left nodes
//
// n1up n2up
// o---o
// | |
// o---o o o o o
//n1down n2down
//
TIDSortedElemSet emptySet, avoidSet;
avoidSet.insert( firstQuad );
firstQuad = SMESH_MeshEditor::FindFaceInSet( n1down, n2down, emptySet, avoidSet);
2009-03-16 21:11:22 +05:00
while ( firstQuad && !faceSubMesh->Contains( firstQuad )) {
2009-02-17 10:27:49 +05:00
avoidSet.insert( firstQuad );
firstQuad = SMESH_MeshEditor::FindFaceInSet( n1down, n2down, emptySet, avoidSet);
}
if ( !firstQuad || !faceSubMesh->Contains( firstQuad ))
return error(ERR_LI("Error in _QuadFaceGrid::LoadGrid()"));
// find the node of quad bound to the left geom edge
int i2down = firstQuad->GetNodeIndex( n2down );
const SMDS_MeshNode* n1up = firstQuad->GetNode(( i2down+2 ) % 4 );
myGrid[ nbFoundNodes++ ] = n1up;
// the 4-the node of the first quad
int i1down = firstQuad->GetNodeIndex( n1down );
const SMDS_MeshNode* n2up = firstQuad->GetNode(( i1down+2 ) % 4 );
myGrid[ nbFoundNodes++ ] = n2up;
n1down = n2down;
n1up = n2up;
const SMDS_MeshElement* quad = firstQuad;
// find the rest nodes by remaining faces above the row
//
// n1up
// o---o--o
// | | | ->
// o---o--o o o o
// n1downLast
//
while ( n1down != n1downLast )
{
// next face
avoidSet.clear(); avoidSet.insert( quad );
quad = SMESH_MeshEditor::FindFaceInSet( n1down, n1up, emptySet, avoidSet );
if ( !quad || quad->NbNodes() % 4 > 0)
return error(ERR_LI("Error in _QuadFaceGrid::LoadGrid()"));
// next node
if ( quad->GetNode( i1down ) != n1down ) // check already found index
i1down = quad->GetNodeIndex( n1down );
n2up = quad->GetNode(( i1down+2 ) % 4 );
myGrid[ nbFoundNodes++ ] = n2up;
n1down = myGrid[ nbFoundNodes - myIndexer._xSize - 1 ];
n1up = n2up;
}
}
DumpGrid(); // debug
return true;
}
//================================================================================
/*!
* \brief Find out mutual location of children: find their right and up brothers
*/
//================================================================================
bool _QuadFaceGrid::locateChildren()
{
if ( myLeftBottomChild )
return true;
TChildren::iterator child = myChildren.begin(), childEnd = myChildren.end();
// find a child sharing it's first bottom vertex with no other brother
myLeftBottomChild = 0;
for ( ; !myLeftBottomChild && child != childEnd; ++child )
{
TopoDS_Vertex leftVertex = child->GetSide( Q_BOTTOM ).FirstVertex();
bool sharedVertex = false;
TChildren::iterator otherChild = myChildren.begin();
for ( ; otherChild != childEnd && !sharedVertex; ++otherChild )
if ( otherChild != child )
sharedVertex = otherChild->mySides.Contain( leftVertex );
if ( !sharedVertex ) {
myLeftBottomChild = & (*child);
DUMP_VERT("0 left bottom Vertex: ",leftVertex );
}
}
if (!myLeftBottomChild)
return error(ERR_LI("Error in locateChildren()"));
set< _QuadFaceGrid* > notLocatedChilren;
for (child = myChildren.begin() ; child != childEnd; ++child )
notLocatedChilren.insert( & (*child));
// connect myLeftBottomChild to it's right and upper brothers
notLocatedChilren.erase( myLeftBottomChild );
myLeftBottomChild->setBrothers( notLocatedChilren );
if ( !notLocatedChilren.empty() )
return error(ERR_LI("Error in locateChildren()"));
return true;
}
//================================================================================
/*!
* \brief Fill myGrid with nodes of patches
*/
//================================================================================
bool _QuadFaceGrid::loadCompositeGrid(SMESH_Mesh& mesh)
{
// Find out mutual location of children: find their right and up brothers
if ( !locateChildren() )
return false;
// Load nodes according to mutual location of children
// grid size
myIndexer._xSize = 1 + myLeftBottomChild->GetNbHoriSegments(mesh, /*withBrothers=*/true);
myIndexer._ySize = 1 + myLeftBottomChild->GetNbVertSegments(mesh, /*withBrothers=*/true);
myGrid.resize( myIndexer.size() );
int fromX = myReverse ? myIndexer._xSize : 0;
if (!myLeftBottomChild->fillGrid( mesh, myGrid, myIndexer, fromX, 0 ))
return error( myLeftBottomChild->GetError() );
DumpGrid();
return true;
}
//================================================================================
/*!
* \brief Find right an upper brothers among notLocatedBrothers
*/
//================================================================================
void _QuadFaceGrid::setBrothers( set< _QuadFaceGrid* >& notLocatedBrothers )
{
if ( !notLocatedBrothers.empty() )
{
// find right brother
TopoDS_Vertex rightVertex = GetSide( Q_BOTTOM ).LastVertex();
DUMP_VERT("1 right bottom Vertex: ",rightVertex );
set< _QuadFaceGrid* >::iterator brIt, brEnd = notLocatedBrothers.end();
for ( brIt = notLocatedBrothers.begin(); !myRightBrother && brIt != brEnd; ++brIt )
{
_QuadFaceGrid* brother = *brIt;
TopoDS_Vertex brotherLeftVertex = brother->GetSide( Q_BOTTOM ).FirstVertex();
DUMP_VERT( "brother left bottom: ", brotherLeftVertex );
if ( rightVertex.IsSame( brotherLeftVertex )) {
myRightBrother = brother;
notLocatedBrothers.erase( myRightBrother );
}
}
// find upper brother
TopoDS_Vertex upVertex = GetSide( Q_LEFT ).FirstVertex();
DUMP_VERT("1 left up Vertex: ",upVertex);
brIt = notLocatedBrothers.begin(), brEnd = notLocatedBrothers.end();
for ( ; !myUpBrother && brIt != brEnd; ++brIt )
{
_QuadFaceGrid* brother = *brIt;
TopoDS_Vertex brotherLeftVertex = brother->GetSide( Q_BOTTOM ).FirstVertex();
DUMP_VERT("brother left bottom: ", brotherLeftVertex);
if ( upVertex.IsSame( brotherLeftVertex )) {
myUpBrother = brother;
notLocatedBrothers.erase( myUpBrother );
}
}
// recursive call
if ( myRightBrother )
myRightBrother->setBrothers( notLocatedBrothers );
if ( myUpBrother )
myUpBrother->setBrothers( notLocatedBrothers );
}
}
//================================================================================
/*!
* \brief Store nodes of a simple face into grid starting from (x,y) position
*/
//================================================================================
bool _QuadFaceGrid::fillGrid(SMESH_Mesh& theMesh,
vector<const SMDS_MeshNode*> & theGrid,
const _Indexer& theIndexer,
int theX,
int theY)
{
if ( myGrid.empty() && !LoadGrid( theMesh ))
return false;
// store my own grid in the global grid
int fromX = myReverse ? theX - myIndexer._xSize: theX;
for ( int i = 0, x = fromX; i < myIndexer._xSize; ++i, ++x )
for ( int j = 0, y = theY; j < myIndexer._ySize; ++j, ++y )
theGrid[ theIndexer( x, y )] = myGrid[ myIndexer( i, j )];
// store grids of my right and upper brothers
if ( myRightBrother )
{
if ( myReverse )
fromX += 1;
else
fromX += myIndexer._xSize - 1;
if ( !myRightBrother->fillGrid( theMesh, theGrid, theIndexer, fromX, theY ))
return error( myRightBrother->GetError() );
}
if ( myUpBrother )
{
if ( !myUpBrother->fillGrid( theMesh, theGrid, theIndexer,
theX, theY + myIndexer._ySize - 1))
return error( myUpBrother->GetError() );
}
return true;
}
//================================================================================
/*!
* \brief Return number of segments on the hirizontal sides
*/
//================================================================================
int _QuadFaceGrid::GetNbHoriSegments(SMESH_Mesh& mesh, bool withBrothers) const
{
int nbSegs = 0;
if ( myLeftBottomChild )
{
nbSegs += myLeftBottomChild->GetNbHoriSegments( mesh, true );
}
else
{
nbSegs = mySides.GetSide( Q_BOTTOM )->GetNbSegments(mesh);
if ( withBrothers && myRightBrother )
nbSegs += myRightBrother->GetNbHoriSegments( mesh, withBrothers );
}
return nbSegs;
}
//================================================================================
/*!
* \brief Return number of segments on the vertical sides
*/
//================================================================================
int _QuadFaceGrid::GetNbVertSegments(SMESH_Mesh& mesh, bool withBrothers) const
{
int nbSegs = 0;
if ( myLeftBottomChild )
{
nbSegs += myLeftBottomChild->GetNbVertSegments( mesh, true );
}
else
{
nbSegs = mySides.GetSide( Q_LEFT )->GetNbSegments(mesh);
if ( withBrothers && myUpBrother )
nbSegs += myUpBrother->GetNbVertSegments( mesh, withBrothers );
}
return nbSegs;
}
//================================================================================
/*!
* \brief Return a node by its position
*/
//================================================================================
const SMDS_MeshNode* _QuadFaceGrid::GetNode(int iHori, int iVert) const
{
return myGrid[ myIndexer( iHori, iVert )];
}
//================================================================================
/*!
* \brief Return node coordinates by its position
*/
//================================================================================
gp_XYZ _QuadFaceGrid::GetXYZ(int iHori, int iVert) const
{
const SMDS_MeshNode* n = myGrid[ myIndexer( iHori, iVert )];
return gp_XYZ( n->X(), n->Y(), n->Z() );
}
//================================================================================
/*!
* \brief Return normal to the face at vertex v
*/
//================================================================================
bool _QuadFaceGrid::GetNormal( const TopoDS_Vertex& v, gp_Vec& n ) const
{
if ( myChildren.empty() )
{
if ( mySides.Contain( v )) {
try {
gp_Pnt2d uv = BRep_Tool::Parameters( v, myFace );
BRepAdaptor_Surface surface( myFace );
gp_Pnt p; gp_Vec d1u, d1v;
surface.D1( uv.X(), uv.Y(), p, d1u, d1v );
n = d1u.Crossed( d1v );
return true;
}
catch (Standard_Failure) {
return false;
}
}
}
else
{
TChildren::const_iterator child = myChildren.begin(), childEnd = myChildren.end();
for ( ; child != childEnd; ++child )
if ( child->GetNormal( v, n ))
return true;
}
return false;
}
//================================================================================
/*!
* \brief Dumps coordinates of grid nodes
*/
//================================================================================
void _QuadFaceGrid::DumpGrid() const
{
#ifdef DEB_GRID
const char* names[] = { "B_BOTTOM", "B_RIGHT", "B_TOP", "B_LEFT", "B_FRONT", "B_BACK" };
cout << "****** Face " << names[ myID ] << endl;
if ( myChildren.empty() || !myGrid.empty() )
{
cout << "x size: " << myIndexer._xSize << "; y size: " << myIndexer._ySize << endl;
for ( int y = 0; y < myIndexer._ySize; ++y ) {
cout << "-- row " << y << endl;
for ( int x = 0; x < myIndexer._xSize; ++x ) {
const SMDS_MeshNode* n = myGrid[ myIndexer( x, y ) ];
cout << x << " ( " << n->X() << ", " << n->Y() << ", " << n->Z() << " )" << endl;
}
}
}
else
{
cout << "Nb children: " << myChildren.size() << endl;
TChildren::const_iterator child = myChildren.begin(), childEnd = myChildren.end();
for ( int i=0; child != childEnd; ++child, ++i ) {
cout << " *** SUBFACE " << i+1 << endl;
((_QuadFaceGrid&)(*child)).SetID( myID );
child->DumpGrid();
}
}
#endif
}
//================================================================================
/*!
* \brief Dump vertices
*/
//================================================================================
void _QuadFaceGrid::DumpVertices() const
{
#ifdef DEB_FACES
cout << "****** Face ";
const char* names[] = { "B_BOTTOM", "B_RIGHT", "B_TOP", "B_LEFT", "B_FRONT", "B_BACK" };
if ( myID >= B_BOTTOM && myID < B_BACK )
cout << names[ myID ] << endl;
else
cout << "UNDEFINED" << endl;
if ( myChildren.empty() )
{
for ( int i = 0; i < 4; ++i )
{
cout << " Side "; mySides.GetSide( i )->Dump();
}
}
else
{
cout << "-- Nb children: " << myChildren.size() << endl;
TChildren::const_iterator child = myChildren.begin(), childEnd = myChildren.end();
for ( int i=0; child != childEnd; ++child, ++i ) {
cout << " *** SUBFACE " << i+1 << endl;
((_QuadFaceGrid&)(*child)).SetID( myID );
child->DumpVertices();
}
}
#endif
}
//=======================================================================
//function : _FaceSide
//purpose : copy constructor
//=======================================================================
_FaceSide::_FaceSide(const _FaceSide& other)
{
myEdge = other.myEdge;
myChildren = other.myChildren;
myNbChildren = other.myNbChildren;
myVertices.Assign( other.myVertices );
myID = other.myID;
}
//================================================================================
/*!
* \brief Construct a face side of one edge
*/
//================================================================================
_FaceSide::_FaceSide(const TopoDS_Edge& edge):
myEdge( edge ), myNbChildren(0)
{
if ( !edge.IsNull() )
for ( TopExp_Explorer exp( edge, TopAbs_VERTEX ); exp.More(); exp.Next() )
//myVertices.insert( ptr ( exp.Current() ));
myVertices.Add( exp.Current() );
}
//================================================================================
/*!
* \brief Construct a face side of several edges
*/
//================================================================================
_FaceSide::_FaceSide(const list<TopoDS_Edge>& edges):
myNbChildren(0)
{
list<TopoDS_Edge>::const_iterator edge = edges.begin(), eEnd = edges.end();
for ( ; edge != eEnd; ++edge ) {
myChildren.push_back( _FaceSide( *edge ));
myNbChildren++;
// myVertices.insert( myChildren.back().myVertices.begin(),
// myChildren.back().myVertices.end() );
myVertices.Add( myChildren.back().FirstVertex() );
myVertices.Add( myChildren.back().LastVertex() );
myChildren.back().SetID( Q_CHILD ); // not to splice them
}
}
//=======================================================================
//function : GetSide
//purpose :
//=======================================================================
_FaceSide* _FaceSide::GetSide(const int i)
{
if ( i >= myNbChildren )
return 0;
list< _FaceSide >::iterator side = myChildren.begin();
if ( i )
std::advance( side, i );
return & (*side);
}
//=======================================================================
//function : GetSide
//purpose :
//=======================================================================
const _FaceSide* _FaceSide::GetSide(const int i) const
{
return const_cast< _FaceSide* >(this)->GetSide(i);
}
//=======================================================================
//function : NbVertices
//purpose : return nb of vertices in the side
//=======================================================================
int _FaceSide::NbVertices() const
{
if ( myChildren.empty() )
return myVertices.Extent();
// return myVertices.size();
return myNbChildren + 1;
}
//=======================================================================
//function : FirstVertex
//purpose :
//=======================================================================
TopoDS_Vertex _FaceSide::FirstVertex() const
{
if ( myChildren.empty() )
return TopExp::FirstVertex( myEdge, Standard_True );
return myChildren.front().FirstVertex();
}
//=======================================================================
//function : LastVertex
//purpose :
//=======================================================================
TopoDS_Vertex _FaceSide::LastVertex() const
{
if ( myChildren.empty() )
return TopExp::LastVertex( myEdge, Standard_True );
return myChildren.back().LastVertex();
}
//=======================================================================
//function : Vertex
//purpose :
//=======================================================================
TopoDS_Vertex _FaceSide::Vertex(int i) const
{
if ( myChildren.empty() )
return i ? LastVertex() : FirstVertex();
if ( i >= myNbChildren )
return myChildren.back().LastVertex();
return GetSide(i)->FirstVertex();
}
//=======================================================================
//function : Contain
//purpose :
//=======================================================================
bool _FaceSide::Contain( const _FaceSide& side, int* which ) const
{
if ( !which || myChildren.empty() )
{
if ( which )
*which = 0;
int nbCommon = 0;
// set<const TopoDS_TShape*>::iterator v, vEnd = side.myVertices.end();
// for ( v = side.myVertices.begin(); v != vEnd; ++v )
// nbCommon += ( myVertices.find( *v ) != myVertices.end() );
TopTools_MapIteratorOfMapOfShape vIt ( side.myVertices );
for ( ; vIt.More(); vIt.Next() )
nbCommon += ( myVertices.Contains( vIt.Key() ));
return (nbCommon > 1);
}
list< _FaceSide >::const_iterator mySide = myChildren.begin(), sideEnd = myChildren.end();
for ( int i = 0; mySide != sideEnd; ++mySide, ++i ) {
if ( mySide->Contain( side )) {
*which = i;
return true;
}
}
return false;
}
//=======================================================================
//function : Contain
//purpose :
//=======================================================================
bool _FaceSide::Contain( const TopoDS_Vertex& vertex ) const
{
return myVertices.Contains( vertex );
// return myVertices.find( ptr( vertex )) != myVertices.end();
}
//=======================================================================
//function : AppendSide
//purpose :
//=======================================================================
void _FaceSide::AppendSide( const _FaceSide& side )
{
if ( !myEdge.IsNull() )
{
myChildren.push_back( *this );
myNbChildren = 1;
myEdge.Nullify();
}
myChildren.push_back( side );
myNbChildren++;
//myVertices.insert( side.myVertices.begin(), side.myVertices.end() );
TopTools_MapIteratorOfMapOfShape vIt ( side.myVertices );
for ( ; vIt.More(); vIt.Next() )
myVertices.Add( vIt.Key() );
myID = Q_PARENT;
myChildren.back().SetID( EQuadSides( myNbChildren-1 ));
}
//=======================================================================
//function : SetBottomSide
//purpose :
//=======================================================================
void _FaceSide::SetBottomSide( int i )
{
if ( i > 0 && myID == Q_PARENT ) {
list< _FaceSide >::iterator sideEnd, side = myChildren.begin();
std::advance( side, i );
myChildren.splice( myChildren.begin(), myChildren, side, myChildren.end() );
side = myChildren.begin(), sideEnd = myChildren.end();
for ( int i = 0; side != sideEnd; ++side, ++i ) {
side->SetID( EQuadSides(i) );
side->SetBottomSide(i);
}
}
}
//=======================================================================
//function : GetNbSegments
//purpose :
//=======================================================================
int _FaceSide::GetNbSegments(SMESH_Mesh& mesh) const
{
int nb = 0;
if ( myChildren.empty() )
{
nb = mesh.GetSubMesh(myEdge)->GetSubMeshDS()->NbElements();
}
else
{
list< _FaceSide >::const_iterator side = myChildren.begin(), sideEnd = myChildren.end();
for ( ; side != sideEnd; ++side )
nb += side->GetNbSegments(mesh);
}
return nb;
}
//=======================================================================
//function : StoreNodes
//purpose :
//=======================================================================
bool _FaceSide::StoreNodes(SMESH_Mesh& mesh,
vector<const SMDS_MeshNode*>& myGrid,
bool reverse )
{
list< TopoDS_Edge > edges;
if ( myChildren.empty() )
{
edges.push_back( myEdge );
}
else
{
list< _FaceSide >::const_iterator side = myChildren.begin(), sideEnd = myChildren.end();
for ( ; side != sideEnd; ++side )
if ( reverse )
edges.push_front( side->myEdge );
else
edges.push_back ( side->myEdge );
}
int nbNodes = 0;
list< TopoDS_Edge >::iterator edge = edges.begin(), eEnd = edges.end();
for ( ; edge != eEnd; ++edge )
{
map< double, const SMDS_MeshNode* > nodes;
bool ok = SMESH_Algo::GetSortedNodesOnEdge( mesh.GetMeshDS(),
*edge,
/*ignoreMediumNodes=*/true,
nodes);
if ( !ok ) return false;
bool forward = ( edge->Orientation() == TopAbs_FORWARD );
if ( reverse ) forward = !forward;
if ( forward )
{
map< double, const SMDS_MeshNode* >::iterator u_node, nEnd = nodes.end();
for ( u_node = nodes.begin(); u_node != nEnd; ++u_node )
myGrid[ nbNodes++ ] = u_node->second;
}
else
{
map< double, const SMDS_MeshNode* >::reverse_iterator u_node, nEnd = nodes.rend();
for ( u_node = nodes.rbegin(); u_node != nEnd; ++u_node )
myGrid[ nbNodes++ ] = u_node->second;
}
nbNodes--; // node on vertex present in two adjacent edges
}
return nbNodes > 0;
}
//=======================================================================
//function : Dump
//purpose : dump end vertices
//=======================================================================
void _FaceSide::Dump() const
{
if ( myChildren.empty() )
{
const char* sideNames[] = { "Q_BOTTOM", "Q_RIGHT", "Q_TOP", "Q_LEFT", "Q_CHILD", "Q_PARENT" };
if ( myID >= Q_BOTTOM && myID < Q_PARENT )
cout << sideNames[ myID ] << endl;
else
cout << "<UNDEFINED ID>" << endl;
TopoDS_Vertex f = FirstVertex();
TopoDS_Vertex l = LastVertex();
gp_Pnt pf = BRep_Tool::Pnt(f);
gp_Pnt pl = BRep_Tool::Pnt(l);
cout << "\t ( "<< ptr( f ) << " - " << ptr( l )<< " )"
<< "\t ( "<< pf.X()<<", "<<pf.Y()<<", "<<pf.Z()<<" ) - "
<< " ( "<< pl.X()<<", "<<pl.Y()<<", "<<pl.Z()<<" )"<<endl;
}
else
{
list< _FaceSide >::const_iterator side = myChildren.begin(), sideEnd = myChildren.end();
for ( ; side != sideEnd; ++side ) {
side->Dump();
cout << "\t";
}
}
}