netgen/libsrc/meshing/topology.cpp
2019-03-20 17:06:57 +01:00

2021 lines
57 KiB
C++

#include <mystdlib.h>
#include "meshing.hpp"
namespace netgen
{
template <class T>
void QuickSortRec (FlatArray<T> data,
int left, int right)
{
int i = left;
int j = right;
T midval = data[(left+right)/2];
do
{
while (data[i] < midval) i++;
while (midval < data[j]) j--;
if (i <= j)
{
Swap (data[i], data[j]);
i++; j--;
}
}
while (i <= j);
if (left < j) QuickSortRec (data, left, j);
if (i < right) QuickSortRec (data, i, right);
}
template <class T>
void QuickSort (FlatArray<T> data)
{
if (data.Size() > 1)
QuickSortRec (data, 0, data.Size()-1);
}
MeshTopology :: MeshTopology (const Mesh & amesh)
: mesh(&amesh)
{
buildedges = true;
buildfaces = true;
timestamp = -1;
}
MeshTopology :: ~MeshTopology () { ; }
bool MeshTopology :: NeedsUpdate() const
{ return (timestamp <= mesh->GetTimeStamp()); }
template <typename FUNC>
void LoopOverEdges (const Mesh & mesh, MeshTopology & top, PointIndex v,
FUNC func)
{
for (ElementIndex elnr : top.GetVertexElements(v))
{
const Element & el = mesh[elnr];
int neledges = MeshTopology::GetNEdges (el.GetType());
const ELEMENT_EDGE * eledges = MeshTopology::GetEdges0 (el.GetType());
for (int k = 0; k < neledges; k++)
{
INDEX_2 edge(el[eledges[k][0]], el[eledges[k][1]]);
// edge.Sort();
int edgedir = (edge.I1() > edge.I2());
if (edgedir) swap (edge.I1(), edge.I2());
if (edge.I1() != v) continue;
func (edge, elnr, k, 3, edgedir);
}
}
for (SurfaceElementIndex elnr : top.GetVertexSurfaceElements(v))
{
const Element2d & el = mesh[elnr];
int neledges = MeshTopology::GetNEdges (el.GetType());
const ELEMENT_EDGE * eledges = MeshTopology::GetEdges0 (el.GetType());
for (int k = 0; k < neledges; k++)
{
INDEX_2 edge(el[eledges[k][0]], el[eledges[k][1]]);
// edge.Sort();
int edgedir = (edge.I1() > edge.I2());
if (edgedir) swap (edge.I1(), edge.I2());
if (edge.I1() != v) continue;
func (edge, elnr, k, 2, edgedir);
}
}
for (SegmentIndex elnr : top.GetVertexSegments(v))
{
const Segment & el = mesh[elnr];
INDEX_2 edge(el[0], el[1]);
int edgedir = (edge.I1() > edge.I2());
if (edgedir) swap (edge.I1(), edge.I2());
edge.Sort();
if (edge.I1() != v) continue;
func (edge, elnr, 0, 1, edgedir);
}
}
template <typename FUNC>
void LoopOverFaces (const Mesh & mesh, MeshTopology & top, PointIndex v,
FUNC func)
{
for (ElementIndex elnr : top.GetVertexElements(v))
{
const Element & el = mesh[elnr];
int nelfaces = MeshTopology::GetNFaces (el.GetType());
const ELEMENT_FACE * elfaces = MeshTopology::GetFaces0 (el.GetType());
for (int j = 0; j < nelfaces; j++)
if (elfaces[j][3] < 0)
{ // triangle
INDEX_4 face(el[elfaces[j][0]], el[elfaces[j][1]],
el[elfaces[j][2]], 0);
int facedir = 0;
if (face.I1() > face.I2())
{ swap (face.I1(), face.I2()); facedir += 1; }
if (face.I2() > face.I3())
{ swap (face.I2(), face.I3()); facedir += 2; }
if (face.I1() > face.I2())
{ swap (face.I1(), face.I2()); facedir += 4; }
if (face.I1() != v) continue;
func (face, elnr, j, true, facedir);
}
/*
if (pass == 1)
{
if (!vert2face.Used (face))
{
nfa++;
vert2face.Set (face, nfa);
INDEX_4 hface(face.I1(),face.I2(),face.I3(),0);
face2vert.Append (hface);
}
}
else
{
int facenum = vert2face.Get(face);
faces[elnr][j].fnr = facenum-1;
faces[elnr][j].forient = facedir;
}
*/
else
{
// quad
// int facenum;
INDEX_4 face4(el[elfaces[j][0]], el[elfaces[j][1]],
el[elfaces[j][2]], el[elfaces[j][3]]);
int facedir = 0;
if (min2 (face4.I1(), face4.I2()) >
min2 (face4.I4(), face4.I3()))
{ // z - flip
facedir += 1;
swap (face4.I1(), face4.I4());
swap (face4.I2(), face4.I3());
}
if (min2 (face4.I1(), face4.I4()) >
min2 (face4.I2(), face4.I3()))
{ // x - flip
facedir += 2;
swap (face4.I1(), face4.I2());
swap (face4.I3(), face4.I4());
}
if (face4.I2() > face4.I4())
{ // diagonal flip
facedir += 4;
swap (face4.I2(), face4.I4());
}
if (face4.I1() != v) continue;
func(face4, elnr, j, true, facedir);
/*
INDEX_3 face(face4.I1(), face4.I2(), face4.I3());
if (vert2face.Used (face))
{
facenum = vert2face.Get(face);
}
else
{
if (pass == 2) cout << "hier in pass 2" << endl;
nfa++;
vert2face.Set (face, nfa);
facenum = nfa;
INDEX_4 hface(face4.I1(),face4.I2(),face4.I3(),face4.I4());
face2vert.Append (hface);
}
faces[elnr][j].fnr = facenum-1;
faces[elnr][j].forient = facedir;
}
*/
}
}
for (SurfaceElementIndex elnr : top.GetVertexSurfaceElements(v))
{
const Element2d & el = mesh.SurfaceElement (elnr);
const ELEMENT_FACE * elfaces = MeshTopology::GetFaces1 (el.GetType());
if (elfaces[0][3] == 0)
{ // triangle
// int facenum;
int facedir;
INDEX_4 face(el.PNum(elfaces[0][0]),
el.PNum(elfaces[0][1]),
el.PNum(elfaces[0][2]),0);
facedir = 0;
if (face.I1() > face.I2())
{
swap (face.I1(), face.I2());
facedir += 1;
}
if (face.I2() > face.I3())
{
swap (face.I2(), face.I3());
facedir += 2;
}
if (face.I1() > face.I2())
{
swap (face.I1(), face.I2());
facedir += 4;
}
if (face.I1() != v) continue;
func(face, elnr, 0, false, facedir);
/*
if (vert2face.Used (face))
facenum = vert2face.Get(face);
else
{
nfa++;
vert2face.Set (face, nfa);
facenum = nfa;
INDEX_4 hface(face.I1(),face.I2(),face.I3(),0);
face2vert.Append (hface);
}
surffaces[elnr].fnr = facenum-1;
surffaces[elnr].forient = facedir;
*/
}
else
{
// quad
// int facenum;
int facedir;
INDEX_4 face4(el.PNum(elfaces[0][0]),
el.PNum(elfaces[0][1]),
el.PNum(elfaces[0][2]),
el.PNum(elfaces[0][3]));
facedir = 0;
if (min2 (face4.I1(), face4.I2()) >
min2 (face4.I4(), face4.I3()))
{ // z - orientation
facedir += 1;
swap (face4.I1(), face4.I4());
swap (face4.I2(), face4.I3());
}
if (min2 (face4.I1(), face4.I4()) >
min2 (face4.I2(), face4.I3()))
{ // x - orientation
facedir += 2;
swap (face4.I1(), face4.I2());
swap (face4.I3(), face4.I4());
}
if (face4.I2() > face4.I4())
{
facedir += 4;
swap (face4.I2(), face4.I4());
}
if (face4.I1() != v) continue;
func(face4, elnr, 0, false, facedir);
/*
INDEX_3 face(face4.I1(), face4.I2(), face4.I3());
if (vert2face.Used (face))
facenum = vert2face.Get(face);
else
{
nfa++;
vert2face.Set (face, nfa);
facenum = nfa;
INDEX_4 hface(face4.I1(),face4.I2(),face4.I3(),face4.I4());
face2vert.Append (hface);
}
surffaces[elnr].fnr = facenum-1;
surffaces[elnr].forient = facedir;
}
*/
}
}
}
void MeshTopology :: Update (TaskManager tm, Tracer tracer)
{
static int timer = NgProfiler::CreateTimer ("topology");
NgProfiler::RegionTimer reg (timer);
#ifdef PARALLEL
// ParallelMeshTopology & paralleltop = mesh.GetParallelTopology();
#endif
auto id = this->mesh->GetCommunicator().Rank();
auto ntasks = this->mesh->GetCommunicator().Size();
if (timestamp > mesh->GetTimeStamp()) return;
int ne = mesh->GetNE();
int nse = mesh->GetNSE();
int nseg = mesh->GetNSeg();
int np = mesh->GetNP();
int nv = mesh->GetNV();
if (id == 0)
PrintMessage (3, "Update mesh topology");
(*testout) << " UPDATE MESH TOPOLOGY " << endl;
(*testout) << "ne = " << ne << endl;
(*testout) << "nse = " << nse << endl;
(*testout) << "nseg = " << nseg << endl;
(*testout) << "np = " << np << endl;
(*testout) << "nv = " << nv << endl;
(*tracer) ("Topology::Update setup tables", false);
Array<int,PointIndex::BASE> cnt(nv);
Array<int> vnums;
/*
generate:
vertex to element
vertex to surface element
vertex to segment
*/
cnt = 0;
/*
for (ElementIndex ei = 0; ei < ne; ei++)
{
const Element & el = (*mesh)[ei];
for (int j = 0; j < el.GetNV(); j++)
cnt[el[j]]++;
}
*/
ParallelForRange
(tm, ne,
[&] (size_t begin, size_t end)
{
for (ElementIndex ei = begin; ei < end; ei++)
{
const Element & el = (*mesh)[ei];
for (int j = 0; j < el.GetNV(); j++)
AsAtomic(cnt[el[j]])++;
}
});
vert2element = TABLE<ElementIndex,PointIndex::BASE> (cnt);
/*
for (ElementIndex ei = 0; ei < ne; ei++)
{
const Element & el = (*mesh)[ei];
for (int j = 0; j < el.GetNV(); j++)
vert2element.AddSave (el[j], ei);
}
*/
ParallelForRange
(tm, ne,
[&] (size_t begin, size_t end)
{
for (ElementIndex ei = begin; ei < end; ei++)
{
const Element & el = (*mesh)[ei];
for (int j = 0; j < el.GetNV(); j++)
vert2element.ParallelAdd (el[j], ei);
}
});
cnt = 0;
/*
for (SurfaceElementIndex sei = 0; sei < nse; sei++)
{
const Element2d & el = (*mesh)[sei];
for (int j = 0; j < el.GetNV(); j++)
cnt[el[j]]++;
}
*/
ParallelForRange
(tm, nse,
[&] (size_t begin, size_t end)
{
for (SurfaceElementIndex ei = begin; ei < end; ei++)
{
const Element2d & el = (*mesh)[ei];
for (int j = 0; j < el.GetNV(); j++)
AsAtomic(cnt[el[j]])++;
}
});
vert2surfelement = TABLE<SurfaceElementIndex,PointIndex::BASE> (cnt);
/*
for (SurfaceElementIndex sei = 0; sei < nse; sei++)
{
const Element2d & el = (*mesh)[sei];
for (int j = 0; j < el.GetNV(); j++)
vert2surfelement.AddSave (el[j], sei);
}
*/
ParallelForRange
(tm, nse,
[&] (size_t begin, size_t end)
{
for (SurfaceElementIndex sei = begin; sei < end; sei++)
{
const Element2d & el = (*mesh)[sei];
for (int j = 0; j < el.GetNV(); j++)
vert2surfelement.ParallelAdd (el[j], sei);
}
});
cnt = 0;
for (SegmentIndex si = 0; si < nseg; si++)
{
const Segment & seg = mesh->LineSegment(si);
cnt[seg[0]]++;
cnt[seg[1]]++;
}
vert2segment = TABLE<SegmentIndex,PointIndex::BASE> (cnt);
for (SegmentIndex si = 0; si < nseg; si++)
{
const Segment & seg = mesh->LineSegment(si);
vert2segment.AddSave (seg[0], si);
vert2segment.AddSave (seg[1], si);
}
cnt = 0;
for (int pei = 0; pei < mesh->pointelements.Size(); pei++)
{
const Element0d & pointel = mesh->pointelements[pei];
cnt[pointel.pnum]++;
}
vert2pointelement = TABLE<int,PointIndex::BASE> (cnt);
for (int pei = 0; pei < mesh->pointelements.Size(); pei++)
{
const Element0d & pointel = mesh->pointelements[pei];
vert2pointelement.AddSave (pointel.pnum, pei);
}
(*tracer) ("Topology::Update setup tables", true);
if (buildedges)
{
static int timer1 = NgProfiler::CreateTimer ("topology::buildedges");
NgProfiler::RegionTimer reg1 (timer1);
if (id == 0)
PrintMessage (5, "Update edges ");
edges.SetSize(ne);
surfedges.SetSize(nse);
segedges.SetSize(nseg);
for (int i = 0; i < ne; i++)
for (int j = 0; j < 12; j++)
edges[i][j].nr = -1;
for (int i = 0; i < nse; i++)
for (int j = 0; j < 4; j++)
surfedges[i][j].nr = -1;
// keep existing edges
cnt = 0;
for (int i = 0; i < edge2vert.Size(); i++)
cnt[edge2vert[i][0]]++;
TABLE<int,PointIndex::BASE> vert2edge (cnt);
for (int i = 0; i < edge2vert.Size(); i++)
vert2edge.AddSave (edge2vert[i][0], i);
// ensure all coarse grid and intermediate level edges
cnt = 0;
for (int i = mesh->mlbetweennodes.Begin(); i < mesh->mlbetweennodes.End(); i++)
{
INDEX_2 parents = Sort (mesh->mlbetweennodes[i]);
if (parents[0] >= PointIndex::BASE) cnt[parents[0]]++;
}
TABLE<int,PointIndex::BASE> vert2vertcoarse (cnt);
for (int i = mesh->mlbetweennodes.Begin(); i < mesh->mlbetweennodes.End(); i++)
{
INDEX_2 parents = Sort (mesh->mlbetweennodes[i]);
if (parents[0] >= PointIndex::BASE) vert2vertcoarse.AddSave (parents[0], parents[1]);
}
int max_edge_on_vertex = 0;
for (int i = PointIndex::BASE; i < nv+PointIndex::BASE; i++)
{
int onv = vert2edge[i].Size() + vert2vertcoarse[i].Size() +
4*(vert2element)[i].Size() + 2*(vert2surfelement)[i].Size() + (vert2segment)[i].Size();
max_edge_on_vertex = max (onv, max_edge_on_vertex);
}
// count edges associated with vertices
cnt = 0;
ParallelForRange
(tm, mesh->GetNV(), // Points().Size(),
[&] (size_t begin, size_t end)
{
INDEX_CLOSED_HASHTABLE<int> v2eht(2*max_edge_on_vertex+10);
for (PointIndex v = begin+PointIndex::BASE;
v < end+PointIndex::BASE; v++)
{
v2eht.DeleteData();
for (int ednr : vert2edge[v])
{
int v2 = edge2vert[ednr][1];
v2eht.Set (v2, ednr);
}
int cnti = 0;
for (int v2 : vert2vertcoarse[v])
if (!v2eht.Used(v2))
{
cnti++;
v2eht.Set (v2, 33); // some value
}
LoopOverEdges (*mesh, *this, v,
[&] (INDEX_2 edge, int elnr, int loc_edge, int element_dim, int edgedir)
{
if (!v2eht.Used (edge.I2()))
{
cnti++;
v2eht.Set (edge.I2(), 33); // something
}
});
cnt[v] = cnti;
}
} );
// accumulate number of edges
int ned = edge2vert.Size();
// for (size_t v = 0; v < mesh->GetNV(); v++)
for (size_t v : cnt.Range())
{
auto hv = cnt[v];
cnt[v] = ned;
ned += hv;
}
edge2vert.SetSize(ned);
// INDEX_CLOSED_HASHTABLE<int> v2eht(2*max_edge_on_vertex+10);
// Array<int> vertex2;
// for (PointIndex v = PointIndex::BASE; v < nv+PointIndex::BASE; v++)
ParallelForRange
(tm, mesh->GetNV(), // Points().Size(),
[&] (size_t begin, size_t end)
{
INDEX_CLOSED_HASHTABLE<int> v2eht(2*max_edge_on_vertex+10);
Array<int> vertex2;
for (PointIndex v = begin+PointIndex::BASE;
v < end+PointIndex::BASE; v++)
{
int ned = cnt[v];
v2eht.DeleteData();
vertex2.SetSize (0);
for (int ednr : vert2edge[v])
{
int v2 = edge2vert[ednr][1];
v2eht.Set (v2, ednr);
}
for (int v2 : vert2vertcoarse[v])
if (!v2eht.Used(v2))
{
v2eht.Set (v2, 33); // some value
vertex2.Append (v2);
}
LoopOverEdges (*mesh, *this, v,
[&](INDEX_2 edge, int elnr, int loc_edge, int element_dim, int edgedir)
{
if (!v2eht.Used(edge.I2()))
{
vertex2.Append (edge.I2());
v2eht.Set (edge.I2(), 33);
}
});
QuickSort (vertex2);
for (int j = 0; j < vertex2.Size(); j++)
{
v2eht.Set (vertex2[j], ned);
edge2vert[ned] = INDEX_2 (v, vertex2[j]);
ned++;
}
LoopOverEdges (*mesh, *this, v,
[&](INDEX_2 edge, int elnr, int loc_edge, int element_dim, int edgedir)
{
int edgenum = v2eht.Get(edge.I2());
switch (element_dim)
{
case 3:
edges[elnr][loc_edge].nr = edgenum;
// edges[elnr][loc_edge].orient = edgedir;
break;
case 2:
surfedges[elnr][loc_edge].nr = edgenum;
// surfedges[elnr][loc_edge].orient = edgedir;
break;
case 1:
segedges[elnr].nr = edgenum;
// segedges[elnr].orient = edgedir;
break;
}
});
}
} );
}
// generate faces
if (buildfaces)
{
static int timer2 = NgProfiler::CreateTimer ("topology::buildfaces");
static int timer2a = NgProfiler::CreateTimer ("topology::buildfacesa");
static int timer2b = NgProfiler::CreateTimer ("topology::buildfacesb");
static int timer2b1 = NgProfiler::CreateTimer ("topology::buildfacesb1");
static int timer2c = NgProfiler::CreateTimer ("topology::buildfacesc");
NgProfiler::RegionTimer reg2 (timer2);
if (id == 0)
PrintMessage (5, "Update faces ");
NgProfiler::StartTimer (timer2a);
faces.SetSize(ne);
surffaces.SetSize(nse);
cnt = 0;
for (int i = 0; i < face2vert.Size(); i++)
cnt[face2vert[i][0]]++;
TABLE<int,PointIndex::BASE> vert2oldface(cnt);
for (int i = 0; i < face2vert.Size(); i++)
vert2oldface.AddSave (face2vert[i][0], i);
for (int elnr = 0; elnr < ne; elnr++)
for (int j = 0; j < 6; j++)
faces[elnr][j].fnr = -1;
int max_face_on_vertex = 0;
for (int i = PointIndex::BASE; i < nv+PointIndex::BASE; i++)
{
int onv = vert2oldface[i].Size() + vert2element[i].Size() + vert2surfelement[i].Size();
max_face_on_vertex = max (onv, max_face_on_vertex);
}
NgProfiler::StopTimer (timer2a);
NgProfiler::StartTimer (timer2b);
INDEX_3_CLOSED_HASHTABLE<int> vert2face(2*max_face_on_vertex+10);
int oldnfa = face2vert.Size();
// count faces associated with vertices
cnt = 0;
// for (auto v : mesh.Points().Range())
NgProfiler::StartTimer (timer2b1);
ParallelForRange
(tm, mesh->GetNV(), // Points().Size(),
[&] (size_t begin, size_t end)
{
INDEX_3_CLOSED_HASHTABLE<int> vert2face(2*max_face_on_vertex+10);
for (PointIndex v = begin+PointIndex::BASE;
v < end+PointIndex::BASE; v++)
{
vert2face.DeleteData();
for (int j = 0; j < vert2oldface[v].Size(); j++)
{
int fnr = vert2oldface[v][j];
INDEX_3 face (face2vert[fnr].I1(),
face2vert[fnr].I2(),
face2vert[fnr].I3());
vert2face.Set (face, 33); // something
}
int cnti = 0;
LoopOverFaces (*mesh, *this, v,
[&] (INDEX_4 i4, int elnr, int j, bool volume, int facedir)
{
INDEX_3 face(i4.I1(), i4.I2(), i4.I3());
if (!vert2face.Used (face))
{
cnti++;
vert2face.Set (face, 33); // something
}
});
cnt[v] = cnti;
}
} );
NgProfiler::StopTimer (timer2b1);
// accumulate number of faces
int nfa = oldnfa;
// for (auto v : Range(mesh->GetNV())) // Points().Range())
// for (size_t v = 0; v < mesh->GetNV(); v++)
for (auto v : cnt.Range())
{
auto hv = cnt[v];
cnt[v] = nfa;
nfa += hv;
}
face2vert.SetSize(nfa);
// for (auto v : mesh.Points().Range())
ParallelForRange
(tm, mesh->GetNV(), // Points().Size(),
[&] (size_t begin, size_t end)
{
INDEX_3_CLOSED_HASHTABLE<int> vert2face(2*max_face_on_vertex+10);
for (PointIndex v = begin+PointIndex::BASE;
v < end+PointIndex::BASE; v++)
{
int first_fa = cnt[v];
int nfa = first_fa;
vert2face.DeleteData();
for (int j = 0; j < vert2oldface[v].Size(); j++)
{
int fnr = vert2oldface[v][j];
INDEX_3 face (face2vert[fnr].I1(),
face2vert[fnr].I2(),
face2vert[fnr].I3());
vert2face.Set (face, fnr);
}
LoopOverFaces (*mesh, *this, v,
[&] (INDEX_4 i4, int elnr, int j, bool volume, int facedir)
{
INDEX_3 face(i4.I1(), i4.I2(), i4.I3());
if (!vert2face.Used (face))
{
face2vert[nfa] = i4;
vert2face.Set (face, nfa);
nfa++;
}
});
QuickSort (face2vert.Range(first_fa, nfa));
for (int j = first_fa; j < nfa; j++)
{
if (face2vert[j][0] == v)
{
INDEX_3 face (face2vert[j].I1(),
face2vert[j].I2(),
face2vert[j].I3());
vert2face.Set (face, j);
}
else
break;
}
LoopOverFaces (*mesh, *this, v,
[&] (INDEX_4 i4, int elnr, int j, bool volume, int facedir)
{
INDEX_3 face(i4.I1(), i4.I2(), i4.I3());
int facenum = vert2face.Get(face);
if (volume)
{
faces[elnr][j].fnr = facenum;
// faces[elnr][j].forient = facedir;
}
else
{
surffaces[elnr].fnr = facenum;
// surffaces[elnr].forient = facedir;
}
});
}
});
/*
int oldnfa = face2vert.Size();
int nfa = oldnfa;
INDEX_3_CLOSED_HASHTABLE<int> vert2face(2*max_face_on_vertex+10);
for (auto v : mesh.Points().Range())
{
int first_fa = nfa;
vert2face.DeleteData();
for (int j = 0; j < vert2oldface[v].Size(); j++)
{
int fnr = vert2oldface[v][j];
INDEX_3 face (face2vert[fnr].I1(),
face2vert[fnr].I2(),
face2vert[fnr].I3());
vert2face.Set (face, fnr+1);
}
for (int pass = 1; pass <= 2; pass++)
{
for (ElementIndex elnr : (*vert2element)[v])
{
const Element & el = mesh[elnr];
int nelfaces = GetNFaces (el.GetType());
const ELEMENT_FACE * elfaces = GetFaces0 (el.GetType());
for (int j = 0; j < nelfaces; j++)
if (elfaces[j][3] < 0)
{ // triangle
INDEX_3 face(el[elfaces[j][0]], el[elfaces[j][1]],
el[elfaces[j][2]]);
int facedir = 0;
if (face.I1() > face.I2())
{ swap (face.I1(), face.I2()); facedir += 1; }
if (face.I2() > face.I3())
{ swap (face.I2(), face.I3()); facedir += 2; }
if (face.I1() > face.I2())
{ swap (face.I1(), face.I2()); facedir += 4; }
if (face.I1() != v) continue;
if (pass == 1)
{
if (!vert2face.Used (face))
{
nfa++;
vert2face.Set (face, nfa);
INDEX_4 hface(face.I1(),face.I2(),face.I3(),0);
face2vert.Append (hface);
}
}
else
{
int facenum = vert2face.Get(face);
faces[elnr][j].fnr = facenum-1;
faces[elnr][j].forient = facedir;
}
}
else
{
// quad
int facenum;
INDEX_4Q face4(el[elfaces[j][0]], el[elfaces[j][1]],
el[elfaces[j][2]], el[elfaces[j][3]]);
int facedir = 0;
if (min2 (face4.I1(), face4.I2()) >
min2 (face4.I4(), face4.I3()))
{ // z - flip
facedir += 1;
swap (face4.I1(), face4.I4());
swap (face4.I2(), face4.I3());
}
if (min2 (face4.I1(), face4.I4()) >
min2 (face4.I2(), face4.I3()))
{ // x - flip
facedir += 2;
swap (face4.I1(), face4.I2());
swap (face4.I3(), face4.I4());
}
if (face4.I2() > face4.I4())
{ // diagonal flip
facedir += 4;
swap (face4.I2(), face4.I4());
}
INDEX_3 face(face4.I1(), face4.I2(), face4.I3());
if (face.I1() != v) continue;
if (vert2face.Used (face))
{
facenum = vert2face.Get(face);
}
else
{
if (pass == 2) cout << "hier in pass 2" << endl;
nfa++;
vert2face.Set (face, nfa);
facenum = nfa;
INDEX_4 hface(face4.I1(),face4.I2(),face4.I3(),face4.I4());
face2vert.Append (hface);
}
faces[elnr][j].fnr = facenum-1;
faces[elnr][j].forient = facedir;
}
}
for (int j = 0; j < (*vert2surfelement)[v].Size(); j++)
{
SurfaceElementIndex elnr = (*vert2surfelement)[v][j];
const Element2d & el = mesh.SurfaceElement (elnr);
const ELEMENT_FACE * elfaces = GetFaces1 (el.GetType());
if (elfaces[0][3] == 0)
{ // triangle
int facenum;
int facedir;
INDEX_3 face(el.PNum(elfaces[0][0]),
el.PNum(elfaces[0][1]),
el.PNum(elfaces[0][2]));
facedir = 0;
if (face.I1() > face.I2())
{
swap (face.I1(), face.I2());
facedir += 1;
}
if (face.I2() > face.I3())
{
swap (face.I2(), face.I3());
facedir += 2;
}
if (face.I1() > face.I2())
{
swap (face.I1(), face.I2());
facedir += 4;
}
if (face.I1() != v) continue;
if (vert2face.Used (face))
facenum = vert2face.Get(face);
else
{
nfa++;
vert2face.Set (face, nfa);
facenum = nfa;
INDEX_4 hface(face.I1(),face.I2(),face.I3(),0);
face2vert.Append (hface);
}
surffaces[elnr].fnr = facenum-1;
surffaces[elnr].forient = facedir;
}
else
{
// quad
int facenum;
int facedir;
INDEX_4Q face4(el.PNum(elfaces[0][0]),
el.PNum(elfaces[0][1]),
el.PNum(elfaces[0][2]),
el.PNum(elfaces[0][3]));
facedir = 0;
if (min2 (face4.I1(), face4.I2()) >
min2 (face4.I4(), face4.I3()))
{ // z - orientation
facedir += 1;
swap (face4.I1(), face4.I4());
swap (face4.I2(), face4.I3());
}
if (min2 (face4.I1(), face4.I4()) >
min2 (face4.I2(), face4.I3()))
{ // x - orientation
facedir += 2;
swap (face4.I1(), face4.I2());
swap (face4.I3(), face4.I4());
}
if (face4.I2() > face4.I4())
{
facedir += 4;
swap (face4.I2(), face4.I4());
}
INDEX_3 face(face4.I1(), face4.I2(), face4.I3());
if (face.I1() != v) continue;
if (vert2face.Used (face))
facenum = vert2face.Get(face);
else
{
nfa++;
vert2face.Set (face, nfa);
facenum = nfa;
INDEX_4 hface(face4.I1(),face4.I2(),face4.I3(),face4.I4());
face2vert.Append (hface);
}
surffaces[elnr].fnr = facenum-1;
surffaces[elnr].forient = facedir;
}
}
// sort faces
if (pass == 1)
{
QuickSort (face2vert.Range(first_fa, nfa));
for (int j = first_fa; j < face2vert.Size(); j++)
{
if (face2vert[j][0] == v)
{
INDEX_3 face (face2vert[j].I1(),
face2vert[j].I2(),
face2vert[j].I3());
vert2face.Set (face, j+1);
}
else
break;
}
}
}
}
face2vert.SetAllocSize (nfa);
*/
// *testout << "face2vert = " << endl << face2vert << endl;
NgProfiler::StopTimer (timer2b);
NgProfiler::StartTimer (timer2c);
face2surfel.SetSize (nfa);
face2surfel = 0;
for (int i = 1; i <= nse; i++)
face2surfel.Elem(GetSurfaceElementFace(i)) = i;
/*
cout << "build table complete" << endl;
cout << "faces = " << endl;
cout << "face2vert = " << endl << face2vert << endl;
cout << "surffaces = " << endl << surffaces << endl;
cout << "face2surfel = " << endl << face2surfel << endl;
*/
surf2volelement.SetSize (nse);
for (int i = 1; i <= nse; i++)
{
surf2volelement.Elem(i)[0] = 0;
surf2volelement.Elem(i)[1] = 0;
}
(*tracer) ("Topology::Update build surf2vol", false);
for (int i = 1; i <= ne; i++)
for (int j = 0; j < 6; j++)
{
// int fnum = (faces.Get(i)[j]+7) / 8;
int fnum = faces.Get(i)[j].fnr+1;
if (fnum > 0 && face2surfel.Elem(fnum))
{
int sel = face2surfel.Elem(fnum);
surf2volelement.Elem(sel)[1] =
surf2volelement.Elem(sel)[0];
surf2volelement.Elem(sel)[0] = i;
}
}
(*tracer) ("Topology::Update build surf2vol", true);
face2vert.SetAllocSize (face2vert.Size());
// face table complete
#ifdef PARALLEL
// (*testout) << " RESET Paralleltop" << endl;
// paralleltop.Reset ();
#endif
(*tracer) ("Topology::Update count face_els", false);
Array<short int> face_els(nfa), face_surfels(nfa);
face_els = 0;
face_surfels = 0;
/*
Array<int> hfaces;
for (int i = 1; i <= ne; i++)
{
GetElementFaces (i, hfaces);
for (int j = 0; j < hfaces.Size(); j++)
face_els[hfaces[j]-1]++;
}
*/
ParallelForRange
(tm, ne,
[&] (size_t begin, size_t end)
{
Array<int> hfaces;
for (ElementIndex ei = begin; ei < end; ei++)
{
GetElementFaces (ei+1, hfaces);
for (auto f : hfaces)
AsAtomic(face_els[f-1])++;
}
});
for (int i = 1; i <= nse; i++)
face_surfels[GetSurfaceElementFace (i)-1]++;
(*tracer) ("Topology::Update count face_els", true);
if (ne)
{
int cnt_err = 0;
for (int i = 0; i < nfa; i++)
{
/*
(*testout) << "face " << i << " has " << int(face_els[i]) << " els, "
<< int(face_surfels[i]) << " surfels, tot = "
<< face_els[i] + face_surfels[i] << endl;
*/
if (face_els[i] + face_surfels[i] == 1)
{
cnt_err++;
#ifdef PARALLEL
if ( ntasks > 1 )
{
continue;
// if ( !paralleltop.DoCoarseUpdate() ) continue;
}
else
#endif
{
(*testout) << "illegal face : " << i << endl;
(*testout) << "points = " << face2vert[i] << endl;
(*testout) << "pos = ";
for (int j = 0; j < 4; j++)
if (face2vert[i].I(j+1) >= 1)
(*testout) << (*mesh)[(PointIndex)face2vert[i].I(j+1)] << " ";
(*testout) << endl;
FlatArray<ElementIndex> vertels = GetVertexElements (face2vert[i].I(1));
for (int k = 0; k < vertels.Size(); k++)
{
int elfaces[10], orient[10];
int nf = GetElementFaces (vertels[k]+1, elfaces, orient);
for (int l = 0; l < nf; l++)
if (elfaces[l] == i)
{
// (*testout) << "is face of element " << vertels[k] << endl;
if (mesh->coarsemesh && mesh->hpelements->Size() == mesh->GetNE() )
{
const HPRefElement & hpref_el =
(*mesh->hpelements) [ (*mesh)[vertels[k]].hp_elnr];
(*testout) << "coarse eleme = " << hpref_el.coarse_elnr << endl;
}
}
}
}
}
}
if (cnt_err && ntasks == 1)
cout << cnt_err << " elements are not matching !!!" << endl;
}
NgProfiler::StopTimer (timer2c);
}
#ifdef PARALLEL
if (id != 0)
{
// if ( paralleltop.DoCoarseUpdate() )
// paralleltop.UpdateCoarseGrid();
}
#endif
/*
for (i = 1; i <= ne; i++)
{
(*testout) << "Element " << i << endl;
(*testout) << "PNums " << endl;
for( int l=1;l<=8;l++) *testout << mesh.VolumeElement(i).PNum(l) << "\t";
*testout << endl;
(*testout) << "edges: " << endl;
for (j = 0; j < 9; j++)
(*testout) << edges.Elem(i)[j] << " ";
(*testout) << "faces: " << endl;
for (j = 0; j < 6; j++)m
(*testout) << faces.Elem(i)[j] << " ";
}
for (i = 1; i <= nse; i++)
{
(*testout) << "SElement " << i << endl;
(*testout) << "PNums " << endl;
for( int l=1;l<=4;l++) *testout << mesh.SurfaceElement(i).PNum(l) << "\t";
*testout << endl;
}
*/
timestamp = NextTimeStamp();
}
const Point3d * MeshTopology :: GetVertices (ELEMENT_TYPE et)
{
static Point3d segm_points [] =
{ Point3d (1, 0, 0),
Point3d (0, 0, 0) };
static Point3d trig_points [] =
{ Point3d ( 1, 0, 0 ),
Point3d ( 0, 1, 0 ),
Point3d ( 0, 0, 0 ) };
static Point3d quad_points [] =
{ Point3d ( 0, 0, 0 ),
Point3d ( 1, 0, 0 ),
Point3d ( 1, 1, 0 ),
Point3d ( 0, 1, 0 ) };
static Point3d tet_points [] =
{ Point3d ( 1, 0, 0 ),
Point3d ( 0, 1, 0 ),
Point3d ( 0, 0, 1 ),
Point3d ( 0, 0, 0 ) };
static Point3d pyramid_points [] =
{
Point3d ( 0, 0, 0 ),
Point3d ( 1, 0, 0 ),
Point3d ( 1, 1, 0 ),
Point3d ( 0, 1, 0 ),
Point3d ( 0, 0, 1-1e-7 ),
};
static Point3d prism_points[] =
{
Point3d ( 1, 0, 0 ),
Point3d ( 0, 1, 0 ),
Point3d ( 0, 0, 0 ),
Point3d ( 1, 0, 1 ),
Point3d ( 0, 1, 1 ),
Point3d ( 0, 0, 1 )
};
static Point3d hex_points [] =
{ Point3d ( 0, 0, 0 ),
Point3d ( 1, 0, 0 ),
Point3d ( 1, 1, 0 ),
Point3d ( 0, 1, 0 ),
Point3d ( 0, 0, 1 ),
Point3d ( 1, 0, 1 ),
Point3d ( 1, 1, 1 ),
Point3d ( 0, 1, 1 ) };
switch (et)
{
case SEGMENT:
case SEGMENT3:
return segm_points;
case TRIG:
case TRIG6:
return trig_points;
case QUAD:
case QUAD6:
case QUAD8:
return quad_points;
case TET:
case TET10:
return tet_points;
case PYRAMID:
return pyramid_points;
case PRISM:
case PRISM12:
return prism_points;
case HEX:
return hex_points;
default:
cerr << "Ng_ME_GetVertices, illegal element type " << et << endl;
}
return 0;
}
void MeshTopology :: GetElementEdges (int elnr, Array<int> & eledges) const
{
int ned = GetNEdges (mesh->VolumeElement(elnr).GetType());
eledges.SetSize (ned);
for (int i = 0; i < ned; i++)
eledges[i] = edges.Get(elnr)[i].nr+1;
// eledges[i] = abs (edges.Get(elnr)[i]);
}
void MeshTopology :: GetElementFaces (int elnr, Array<int> & elfaces, bool withorientation) const
{
int nfa = GetNFaces (mesh->VolumeElement(elnr).GetType());
elfaces.SetSize (nfa);
if (!withorientation)
for (int i = 1; i <= nfa; i++)
{
// elfaces.Elem(i) = (faces.Get(elnr)[i-1]-1) / 8 + 1;
elfaces.Elem(i) = faces.Get(elnr)[i-1].fnr+1;
}
else
{
cerr << "GetElementFaces with orientation currently not supported" << endl;
/*
for (int i = 1; i <= nfa; i++)
{
elfaces.Elem(i) = (faces.Get(elnr)[i-1]-1) / 8 + 1;
int orient = (faces.Get(elnr)[i-1]-1) % 8;
if(orient == 1 || orient == 2 || orient == 4 || orient == 7)
elfaces.Elem(i) *= -1;
}
*/
}
}
void MeshTopology :: GetElementEdgeOrientations (int elnr, Array<int> & eorient) const
{
int ned = GetNEdges (mesh->VolumeElement(elnr).GetType());
eorient.SetSize (ned);
for (int i = 1; i <= ned; i++)
// eorient.Elem(i) = (edges.Get(elnr)[i-1] > 0) ? 1 : -1;
// eorient.Elem(i) = (edges.Get(elnr)[i-1].orient) ? -1 : 1;
eorient.Elem(i) = GetElementEdgeOrientation (elnr, i-1) ? -1 : 1;
}
void MeshTopology :: GetElementFaceOrientations (int elnr, Array<int> & forient) const
{
int nfa = GetNFaces (mesh->VolumeElement(elnr).GetType());
forient.SetSize (nfa);
for (int i = 1; i <= nfa; i++)
// forient.Elem(i) = faces.Get(elnr)[i-1].forient;
// forient.Elem(i) = (faces.Get(elnr)[i-1]-1) % 8;
forient.Elem(i) = GetElementFaceOrientation(elnr, i-1);
}
int MeshTopology :: GetElementEdges (int elnr, int * eledges, int * orient) const
{
// int ned = GetNEdges (mesh.VolumeElement(elnr).GetType());
if (mesh->GetDimension()==3 || 1)
{
if (orient)
{
for (int i = 0; i < 12; i++)
{
/*
if (!edges.Get(elnr)[i]) return i;
eledges[i] = abs (edges.Get(elnr)[i]);
orient[i] = (edges.Get(elnr)[i] > 0 ) ? 1 : -1;
*/
if (edges.Get(elnr)[i].nr == -1) return i;
eledges[i] = edges.Get(elnr)[i].nr+1;
// orient[i] = edges.Get(elnr)[i].orient ? -1 : 1;
orient[i] = GetElementEdgeOrientation(elnr, i) ? -1 : 1;
}
}
else
{
for (int i = 0; i < 12; i++)
{
// if (!edges.Get(elnr)[i]) return i;
// eledges[i] = abs (edges.Get(elnr)[i]);
if (edges.Get(elnr)[i].nr == -1) return i;
eledges[i] = edges.Get(elnr)[i].nr+1;
}
}
return 12;
}
else
{
throw NgException("rethink implementation");
/*
if (orient)
{
for (i = 0; i < 4; i++)
{
if (!surfedges.Get(elnr)[i]) return i;
eledges[i] = abs (surfedges.Get(elnr)[i]);
orient[i] = (surfedges.Get(elnr)[i] > 0 ) ? 1 : -1;
}
}
else
{
if (!surfedges.Get(elnr)[i]) return i;
for (i = 0; i < 4; i++)
eledges[i] = abs (surfedges.Get(elnr)[i]);
}
*/
return 4;
// return GetSurfaceElementEdges (elnr, eledges, orient);
}
}
int MeshTopology :: GetElementFaces (int elnr, int * elfaces, int * orient) const
{
// int nfa = GetNFaces (mesh.VolumeElement(elnr).GetType());
if (orient)
{
for (int i = 0; i < 6; i++)
{
/*
if (!faces.Get(elnr)[i]) return i;
elfaces[i] = (faces.Get(elnr)[i]-1) / 8 + 1;
orient[i] = (faces.Get(elnr)[i]-1) % 8;
*/
if (faces.Get(elnr)[i].fnr == -1) return i;
elfaces[i] = faces.Get(elnr)[i].fnr+1;
// orient[i] = faces.Get(elnr)[i].forient;
orient[i] = GetElementFaceOrientation (elnr, i);
}
}
else
{
for (int i = 0; i < 6; i++)
{
// if (!faces.Get(elnr)[i]) return i;
// elfaces[i] = (faces.Get(elnr)[i]-1) / 8 + 1;
if (faces.Get(elnr)[i].fnr == -1) return i;
elfaces[i] = faces.Get(elnr)[i].fnr+1;
}
}
return 6;
}
void MeshTopology :: GetSurfaceElementEdges (int elnr, Array<int> & eledges) const
{
int ned = GetNEdges (mesh->SurfaceElement(elnr).GetType());
eledges.SetSize (ned);
for (int i = 0; i < ned; i++)
// eledges[i] = abs (surfedges.Get(elnr)[i]);
eledges[i] = surfedges.Get(elnr)[i].nr+1;
}
void MeshTopology :: GetEdges (SurfaceElementIndex elnr, Array<int> & eledges) const
{
int ned = GetNEdges ( (*mesh)[elnr].GetType());
eledges.SetSize (ned);
for (int i = 0; i < ned; i++)
// eledges[i] = abs (surfedges[elnr][i])-1;
eledges[i] = surfedges[elnr][i].nr;
}
int MeshTopology :: GetSurfaceElementFace (int elnr) const
{
return surffaces.Get(elnr).fnr+1;
}
/*
int MeshTopology :: GetFace (SurfaceElementIndex elnr) const
{
return surffaces[elnr].fnr;
}
*/
void MeshTopology ::
GetSurfaceElementEdgeOrientations (int elnr, Array<int> & eorient) const
{
int ned = GetNEdges (mesh->SurfaceElement(elnr).GetType());
eorient.SetSize (ned);
for (int i = 0; i < ned; i++)
// eorient[i] = (surfedges.Get(elnr)[i] > 0) ? 1 : -1;
// eorient[i] = (surfedges.Get(elnr)[i].orient) ? -1 : 1;
eorient[i] = GetSurfaceElementEdgeOrientation(elnr, i) ? -1 : 1;
}
int MeshTopology :: GetSurfaceElementFaceOrientation (int elnr) const
{
// return (surffaces.Get(elnr)-1) % 8;
// return surffaces.Get(elnr).forient;
return GetSurfaceElementFaceOrientation2(elnr);
}
int MeshTopology :: GetSurfaceElementEdges (int elnr, int * eledges, int * orient) const
{
int i;
if (mesh->GetDimension() == 3 || 1)
{
if (orient)
{
for (i = 0; i < 4; i++)
{
/*
if (!surfedges.Get(elnr)[i]) return i;
eledges[i] = abs (surfedges.Get(elnr)[i]);
orient[i] = (surfedges.Get(elnr)[i] > 0 ) ? 1 : -1;
*/
if (surfedges.Get(elnr)[i].nr == -1) return i;
eledges[i] = surfedges.Get(elnr)[i].nr+1;
// orient[i] = (surfedges.Get(elnr)[i].orient) ? -1 : 1;
orient[i] = GetSurfaceElementEdgeOrientation(elnr, i) ? -1 : 1;
}
}
else
{
for (i = 0; i < 4; i++)
{
/*
if (!surfedges.Get(elnr)[i]) return i;
eledges[i] = abs (surfedges.Get(elnr)[i]);
*/
if (surfedges.Get(elnr)[i].nr == -1) return i;
eledges[i] = surfedges.Get(elnr)[i].nr+1;
}
}
return 4;
}
else
{
/*
eledges[0] = abs (segedges.Get(elnr));
if (orient)
orient[0] = segedges.Get(elnr) > 0 ? 1 : -1;
*/
eledges[0] = segedges.Get(elnr).nr+1;
if (orient)
// orient[0] = segedges.Get(elnr).orient ? -1 : 1;
orient[0] = GetSegmentEdgeOrientation(elnr) ? -1 : 1;
}
return 1;
}
int MeshTopology :: GetElementEdgeOrientation (int elnr, int locedgenr) const
{
const Element & el = mesh->VolumeElement (elnr);
const ELEMENT_EDGE * eledges = MeshTopology::GetEdges0 (el.GetType());
int k = locedgenr;
INDEX_2 edge(el[eledges[k][0]], el[eledges[k][1]]);
int edgedir = (edge.I1() > edge.I2());
return edgedir;
}
int MeshTopology :: GetElementFaceOrientation (int elnr, int locfacenr) const
{
const Element & el = mesh->VolumeElement (elnr);
const ELEMENT_FACE * elfaces = MeshTopology::GetFaces0 (el.GetType());
int j = locfacenr;
if (elfaces[j][3] < 0)
{ // triangle
INDEX_4 face(el[elfaces[j][0]], el[elfaces[j][1]],
el[elfaces[j][2]], 0);
int facedir = 0;
if (face.I1() > face.I2())
{ swap (face.I1(), face.I2()); facedir += 1; }
if (face.I2() > face.I3())
{ swap (face.I2(), face.I3()); facedir += 2; }
if (face.I1() > face.I2())
{ swap (face.I1(), face.I2()); facedir += 4; }
return facedir;
}
else
{
// quad
// int facenum;
INDEX_4 face4(el[elfaces[j][0]], el[elfaces[j][1]],
el[elfaces[j][2]], el[elfaces[j][3]]);
int facedir = 0;
if (min2 (face4.I1(), face4.I2()) >
min2 (face4.I4(), face4.I3()))
{ // z - flip
facedir += 1;
swap (face4.I1(), face4.I4());
swap (face4.I2(), face4.I3());
}
if (min2 (face4.I1(), face4.I4()) >
min2 (face4.I2(), face4.I3()))
{ // x - flip
facedir += 2;
swap (face4.I1(), face4.I2());
swap (face4.I3(), face4.I4());
}
if (face4.I2() > face4.I4())
{ // diagonal flip
facedir += 4;
swap (face4.I2(), face4.I4());
}
return facedir;
}
}
int MeshTopology :: GetSurfaceElementEdgeOrientation (int elnr, int locedgenr) const
{
const Element2d & el = mesh->SurfaceElement (elnr);
const ELEMENT_EDGE * eledges = MeshTopology::GetEdges0 (el.GetType());
int k = locedgenr;
INDEX_2 edge(el[eledges[k][0]], el[eledges[k][1]]);
int edgedir = (edge.I1() > edge.I2());
return edgedir;
}
int MeshTopology :: GetSurfaceElementFaceOrientation2 (int elnr) const
{
const Element2d & el = mesh->SurfaceElement (elnr);
const ELEMENT_FACE * elfaces = MeshTopology::GetFaces0 (el.GetType());
int j = 0;
if (elfaces[j][3] < 0)
{ // triangle
INDEX_4 face(el[elfaces[j][0]], el[elfaces[j][1]],
el[elfaces[j][2]], 0);
int facedir = 0;
if (face.I1() > face.I2())
{ swap (face.I1(), face.I2()); facedir += 1; }
if (face.I2() > face.I3())
{ swap (face.I2(), face.I3()); facedir += 2; }
if (face.I1() > face.I2())
{ swap (face.I1(), face.I2()); facedir += 4; }
return facedir;
}
else
{
// quad
// int facenum;
INDEX_4 face4(el[elfaces[j][0]], el[elfaces[j][1]],
el[elfaces[j][2]], el[elfaces[j][3]]);
int facedir = 0;
if (min2 (face4.I1(), face4.I2()) >
min2 (face4.I4(), face4.I3()))
{ // z - flip
facedir += 1;
swap (face4.I1(), face4.I4());
swap (face4.I2(), face4.I3());
}
if (min2 (face4.I1(), face4.I4()) >
min2 (face4.I2(), face4.I3()))
{ // x - flip
facedir += 2;
swap (face4.I1(), face4.I2());
swap (face4.I3(), face4.I4());
}
if (face4.I2() > face4.I4())
{ // diagonal flip
facedir += 4;
swap (face4.I2(), face4.I4());
}
return facedir;
}
}
int MeshTopology :: GetSegmentEdgeOrientation (int elnr) const
{
const Segment & el = mesh->LineSegment (elnr);
const ELEMENT_EDGE * eledges = MeshTopology::GetEdges0 (el.GetType());
int k = 0;
INDEX_2 edge(el[eledges[k][0]], el[eledges[k][1]]);
int edgedir = (edge.I1() > edge.I2());
return edgedir;
}
void MeshTopology :: GetFaceVertices (int fnr, Array<int> & vertices) const
{
vertices.SetSize(4);
for (int i = 0; i < 4; i++)
vertices[i] = face2vert.Get(fnr)[i];
if (vertices[3] == 0)
vertices.SetSize(3);
}
void MeshTopology :: GetFaceVertices (int fnr, int * vertices) const
{
for (int i = 0; i <= 3; i++)
vertices[i] = face2vert.Get(fnr)[i];
}
void MeshTopology :: GetEdgeVertices (int ednr, int & v1, int & v2) const
{
// cout << "id = " << id << "getedgevertices, ednr = " << ednr << ", ned = " << edge2vert.Size() << "&v1 = " << &v1 << endl;
if (ednr < 1 || ednr > edge2vert.Size())
cerr << "illegal edge nr: " << ednr << ", numedges = " << edge2vert.Size()
<< " id = " << id
<< endl;
v1 = edge2vert.Get(ednr)[0];
v2 = edge2vert.Get(ednr)[1];
}
void MeshTopology :: GetEdgeVertices (int ednr, PointIndex & v1, PointIndex & v2) const
{
v1 = edge2vert.Get(ednr)[0];
v2 = edge2vert.Get(ednr)[1];
}
void MeshTopology :: GetFaceEdges (int fnr, Array<int> & fedges, bool withorientation) const
{
ArrayMem<int,4> pi(4);
ArrayMem<int,12> eledges;
fedges.SetSize (0);
GetFaceVertices(fnr, pi);
// Sort Edges according to global vertex numbers
// e1 = fmax, f2
// e2 = fmax, f1
// e3 = op e1(f2,f3)
// e4 = op e2(f1,f3)
/* ArrayMem<int,4> fp;
fp[0] = pi[0];
for(int k=1;k<pi.Size();k++)
if(fp[k]>fp[0]) swap(fp[k],fp[0]);
fp[1] = fp[0]+ */
// GetVertexElements (pi[0], els);
FlatArray<ElementIndex> els = GetVertexElements (pi[0]);
// find one element having all vertices of the face
for (int i = 0; i < els.Size(); i++)
{
const Element & el = (*mesh)[els[i]];
int nref_faces = GetNFaces (el.GetType());
const ELEMENT_FACE * ref_faces = GetFaces1 (el.GetType());
int nfa_ref_edges = GetNEdges (GetFaceType(fnr));
int cntv = 0,fa=-1;
for(int m=0;m<nref_faces;m++)
{
cntv=0;
for(int j=0;j<nfa_ref_edges && ref_faces[m][j]>0;j++)
for(int k=0;k<pi.Size();k++)
{
if(el[ref_faces[m][j]-1] == pi[k])
cntv++;
}
if (cntv == pi.Size())
{
fa=m;
break;
}
}
if(fa>=0)
{
const ELEMENT_EDGE * fa_ref_edges = GetEdges1 (GetFaceType(fnr));
fedges.SetSize(nfa_ref_edges);
GetElementEdges (els[i]+1, eledges);
for (int j = 0; j < eledges.Size(); j++)
{
int vi1, vi2;
GetEdgeVertices (eledges[j], vi1, vi2);
bool has1 = 0;
bool has2 = 0;
for (int k = 0; k < pi.Size(); k++)
{
if (vi1 == pi[k]) has1 = 1;
if (vi2 == pi[k]) has2 = 1;
}
if (has1 && has2) // eledges[j] is on face
{
// fedges.Append (eledges[j]);
for(int k=0;k<nfa_ref_edges;k++)
{
int w1 = el[ref_faces[fa][fa_ref_edges[k][0]-1]-1];
int w2 = el[ref_faces[fa][fa_ref_edges[k][1]-1]-1];
if(withorientation)
{
if(w1==vi1 && w2==vi2)
fedges[k] = eledges[j];
if(w1==vi2 && w2==vi1)
fedges[k] = -eledges[j];
}
else
if((w1==vi1 && w2==vi2) || (w1==vi2 && w2==vi1))
fedges[k] = eledges[j];
}
}
}
// *testout << " Face " << fnr << endl;
// *testout << " GetFaceEdges " << fedges << endl;
return;
}
}
int surfel = GetFace2SurfaceElement(fnr);
if (surfel != 0)
{
GetSurfaceElementEdges (surfel, fedges);
return;
}
}
/*
ELEMENT_TYPE MeshTopology :: GetFaceType (int fnr) const
{
if (face2vert.Get(fnr)[3] == 0) return TRIG; else return QUAD;
}
*/
void MeshTopology :: GetVertexElements (int vnr, Array<ElementIndex> & elements) const
{
if (vert2element.Size())
{
int ne = vert2element.EntrySize(vnr);
elements.SetSize(ne);
for (int i = 1; i <= ne; i++)
elements.Elem(i) = vert2element.Get(vnr, i);
}
}
/*
FlatArray<ElementIndex> MeshTopology :: GetVertexElements (int vnr) const
{
if (vert2element)
return (*vert2element)[vnr];
return FlatArray<ElementIndex> (0,0);
}
FlatArray<SurfaceElementIndex> MeshTopology :: GetVertexSurfaceElements (int vnr) const
{
if (vert2surfelement)
return (*vert2surfelement)[vnr];
return FlatArray<SurfaceElementIndex> (0,0);
}
FlatArray<SegmentIndex> MeshTopology :: GetVertexSegments (int vnr) const
{
if (vert2segment)
return (*vert2segment)[vnr];
return FlatArray<SegmentIndex> (0,0);
}
*/
void MeshTopology :: GetVertexSurfaceElements( int vnr,
Array<SurfaceElementIndex> & elements ) const
{
if (vert2surfelement.Size())
{
int i;
int ne = vert2surfelement.EntrySize(vnr);
elements.SetSize(ne);
for (i = 1; i <= ne; i++)
elements.Elem(i) = vert2surfelement.Get(vnr, i);
}
}
int MeshTopology :: GetVerticesEdge ( int v1, int v2 ) const
{
Array<ElementIndex> elements_v1;
Array<int> elementedges;
GetVertexElements ( v1, elements_v1);
int edv1, edv2;
for ( int i = 0; i < elements_v1.Size(); i++ )
{
GetElementEdges( elements_v1[i]+1, elementedges );
for ( int ed = 0; ed < elementedges.Size(); ed ++)
{
GetEdgeVertices( elementedges[ed], edv1, edv2 );
if ( ( edv1 == v1 && edv2 == v2 ) || ( edv1 == v2 && edv2 == v1 ) )
return elementedges[ed];
}
}
return -1;
}
void MeshTopology ::
GetSegmentVolumeElements ( int segnr, Array<ElementIndex> & volels ) const
{
int v1, v2;
GetEdgeVertices ( GetSegmentEdge (segnr), v1, v2 );
Array<ElementIndex> volels1, volels2;
GetVertexElements ( v1, volels1 );
GetVertexElements ( v2, volels2 );
volels.SetSize(0);
for ( int eli1=1; eli1 <= volels1.Size(); eli1++)
if ( volels2.Contains( volels1.Elem(eli1) ) )
volels.Append ( volels1.Elem(eli1) );
}
void MeshTopology ::
GetSegmentSurfaceElements (int segnr, Array<SurfaceElementIndex> & els) const
{
int v1, v2;
GetEdgeVertices ( GetSegmentEdge (segnr), v1, v2 );
Array<SurfaceElementIndex> els1, els2;
GetVertexSurfaceElements ( v1, els1 );
GetVertexSurfaceElements ( v2, els2 );
els.SetSize(0);
for ( int eli1=1; eli1 <= els1.Size(); eli1++)
if ( els2.Contains( els1.Elem(eli1) ) )
els.Append ( els1.Elem(eli1) );
}
}