// Manually add a surface element of a given type to an existing mesh object
DLL_HEADER void Ng_AddSurfaceElement (Ng_Mesh * mesh, Ng_Surface_Element_Type et,
int * pi)
{
Mesh * m = (Mesh*)mesh;
Element2d el (3);
el.SetIndex (1);
el.PNum(1) = pi[0];
el.PNum(2) = pi[1];
el.PNum(3) = pi[2];
m->AddSurfaceElement (el);
}
/*
Philippose Rajan - 11 June 2009
Added an initial experimental function for
generating prismatic boundary layers on
a given set of surfaces.
The number of layers, height of the first layer
and the growth / shrink factor can be specified
by the user
Currently, the layer height is calculated using:
height = h_first_layer * (growth_factor^(num_layers - 1))
*/
void GenerateBoundaryLayer (Mesh & mesh, MeshingParameters & mp)
{
int i, j;
ofstream dbg("BndLayerDebug.log");
// Angle between a surface element and a growth-vector below which
// a prism is project onto that surface as a quad
// (in degrees)
double angleThreshold = 5.0;
cout << "Generate Prismatic Boundary Layers (Experimental)...." << endl;
// Use an array to support creation of boundary
// layers for multiple surfaces in the future...
Array<int> surfid;
int surfinp = 0;
int prismlayers = 1;
double hfirst = 0.01;
double growthfactor = 1.0;
// Monitor and print out the number of prism and quad elements
// added to the mesh
int numprisms = 0;
int numquads = 0;
while(surfinp >= 0)
{
cout << "Enter Surface ID (-1 to end list): ";
cin >> surfinp;
if(surfinp >= 0) surfid.Append(surfinp);
}
cout << "Number of surfaces entered = " << surfid.Size() << endl;
cout << "Selected surfaces are:" << endl;
for(i = 1; i <= surfid.Size(); i++)
{
cout << "Surface " << i << ": " << surfid.Elem(i) << endl;
}
cout << endl << "Enter number of prism layers: ";
cin >> prismlayers;
if(prismlayers < 1) prismlayers = 1;
cout << "Enter height of first layer: ";
cin >> hfirst;
if(hfirst <= 0.0) hfirst = 0.01;
cout << "Enter layer growth / shrink factor: ";
cin >> growthfactor;
if(growthfactor <= 0.0) growthfactor = 0.5;
cout << "Old NP: " << mesh.GetNP() << endl;
cout << "Old NSE: " << mesh.GetNSE() << endl;
for(int layer = prismlayers; layer >= 1; layer--)
{
cout << "Generating layer: " << layer << endl;
const MeshTopology& meshtopo = mesh.GetTopology();
const_cast<MeshTopology &> (meshtopo).SetBuildEdges(true);
const_cast<MeshTopology &> (meshtopo).SetBuildFaces(true);
const_cast<MeshTopology &> (meshtopo).Update();
double layerht = hfirst;
if(growthfactor == 1)
{
layerht = layer * hfirst;
}
else
{
layerht = hfirst*(pow(growthfactor,(layer+1)) - 1)/(growthfactor - 1);
}
cout << "Layer Height = " << layerht << endl;
// Need to store the old number of points and
// surface elements because there are new points and
// surface elements being added during the process
int np = mesh.GetNP();
int nse = mesh.GetNSE();
// Safety measure to ensure no issues with mesh
// consistency
int nseg = mesh.GetNSeg();
// Indicate which points need to be remapped
BitArray bndnodes(np);
// Map of the old points to the new points
Array<int> mapto(np);
// Growth vectors for the prismatic layer based on
// the effective surface normal at a given point
Array<Vec3d> growthvectors(np);
// Bit array to identify all the points belonging
// to the surface of interest
bndnodes.Clear();
// Run through all the surface elements and mark the points
// belonging to those where a boundary layer has to be created.
// In addition, also calculate the effective surface normal
// vectors at each of those points to determine the mesh motion
// direction
cout << "Marking points for remapping...." << endl;
for (i = 1; i <= nse; i++)
{
int snr = mesh.SurfaceElement(i).GetIndex();
// cout << "snr = " << snr << endl;
if (surfid.Contains(snr))
{
Element2d & sel = mesh.SurfaceElement(i);
int selNP = sel.GetNP();
for(j = 1; j <= selNP; j++)
{
// Set the bitarray to indicate that the
// point is part of the required set
bndnodes.Set(sel.PNum(j));
// Vec3d& surfacenormal = Vec3d(); ????
Vec3d surfacenormal;
// Calculate the surface normal at the current point
// with respect to the current surface element
GetSurfaceNormal(mesh,sel,j,surfacenormal);
// Add the surface normal to the already existent one
// (This gives the effective normal direction at corners
// and curved areas)
growthvectors.Elem(sel.PNum(j)) = growthvectors.Elem(sel.PNum(j))
+ surfacenormal;
}
}
}
// Add additional points into the mesh structure in order to
// clone the surface elements.
// Also invert the growth vectors so that they point inwards,
// and normalize them
cout << "Cloning points and calculating growth vectors...." << endl;
for (i = 1; i <= np; i++)
{
if (bndnodes.Test(i))
{
mapto.Elem(i) = mesh.AddPoint (mesh.Point (i));
growthvectors.Elem(i).Normalize();
growthvectors.Elem(i) *= -1.0;
}
else
{
mapto.Elem(i) = 0;
growthvectors.Elem(i) = Vec3d(0,0,0);
}
}
// Add quad surface elements at edges for surfaces which
// dont have boundary layers
// Bit array to keep track of segments already processed
BitArray segsel(nseg);
// Set them all to "1" to initially activate all segments
segsel.Set();
cout << "Adding 2D Quad elements on required surfaces...." << endl;
for (i = 1; i <= nseg; i++)
{
int seg_p1 = mesh.LineSegment(i)[0];
int seg_p2 = mesh.LineSegment(i)[1];
// Only go in if the segment is still active, and if both its
// surface index is part of the "hit-list"
if(segsel.Test(i) && surfid.Contains(mesh.LineSegment(i).si))
{
// clear the bit to indicate that this segment has been processed
segsel.Clear(i);
// Find matching segment pair on other surface
for(j = 1; j <= nseg; j++)
{
int segpair_p1 = mesh.LineSegment(j)[1];
int segpair_p2 = mesh.LineSegment(j)[0];
// Find the segment pair on the neighbouring surface element
// Identified by: seg1[0] = seg_pair[1] and seg1[1] = seg_pair[0]
if(segsel.Test(j) && ((segpair_p1 == seg_p1) && (segpair_p2 == seg_p2)))
{
// clear bit to indicate that processing of this segment is done
segsel.Clear(j);
// Only worry about those surfaces which are not in the
// boundary layer list
if(!surfid.Contains(mesh.LineSegment(j).si))
{
int pnt_commelem = 0;
int pnum_commelem = 0;
Array<int> pnt1_elems;
Array<int> pnt2_elems;
meshtopo.GetVertexSurfaceElements(segpair_p1,pnt1_elems);
meshtopo.GetVertexSurfaceElements(segpair_p2,pnt2_elems);
for(int k = 1; k <= pnt1_elems.Size(); k++)
{
Element2d pnt1_sel = mesh.SurfaceElement(pnt1_elems.Elem(k));
for(int l = 1; l <= pnt2_elems.Size(); l++)
{
Element2d pnt2_sel = mesh.SurfaceElement(pnt2_elems.Elem(l));
if((pnt1_sel.GetIndex() == mesh.LineSegment(j).si)
&& (pnt2_sel.GetIndex() == mesh.LineSegment(j).si)
&& (pnt1_elems.Elem(k) == pnt2_elems.Elem(l)))
{
pnt_commelem = pnt1_elems.Elem(k);
}
}
}
for(int k = 1; k <= mesh.SurfaceElement(pnt_commelem).GetNP(); k++)
{
if((mesh.SurfaceElement(pnt_commelem).PNum(k) != segpair_p1)
&& (mesh.SurfaceElement(pnt_commelem).PNum(k) != segpair_p2))
{
pnum_commelem = mesh.SurfaceElement(pnt_commelem).PNum(k);
}
}
Vec3d surfelem_vect, surfelem_vect1;
Element2d & commsel = mesh.SurfaceElement(pnt_commelem);
dbg << "NP= " << commsel.GetNP() << " : ";
for(int k = 1; k <= commsel.GetNP(); k++)
{
GetSurfaceNormal(mesh,commsel,k,surfelem_vect1);
surfelem_vect += surfelem_vect1;
}
surfelem_vect.Normalize();
double surfangle = Angle(growthvectors.Elem(segpair_p1),surfelem_vect);
dbg << "V1= " << surfelem_vect1
<< " : V2= " << surfelem_vect1
<< " : V= " << surfelem_vect
<< " : GV= " << growthvectors.Elem(segpair_p1)
<< " : Angle= " << surfangle * 180 / 3.141592;
// remap the segments to the new points
mesh.LineSegment(i)[0] = mapto.Get(seg_p1);
mesh.LineSegment(i)[1] = mapto.Get(seg_p2);
mesh.LineSegment(j)[1] = mapto.Get(seg_p1);
mesh.LineSegment(j)[0] = mapto.Get(seg_p2);
if((surfangle < (90 + angleThreshold) * 3.141592 / 180.0)
&& (surfangle > (90 - angleThreshold) * 3.141592 / 180.0))
{
dbg << " : quad\n";
// Since the surface is lower than the threshold, change the effective
// prism growth vector to match with the surface vector, so that
// the Quad which is created lies on the original surface
//growthvectors.Elem(segpair_p1) = surfelem_vect;
// Add a quad element to account for the prism volume
// element which is going to be added
Element2d sel(QUAD);
sel.PNum(4) = mapto.Get(seg_p1);
sel.PNum(3) = mapto.Get(seg_p2);
sel.PNum(2) = segpair_p2;
sel.PNum(1) = segpair_p1;
sel.SetIndex(mesh.LineSegment(j).si);
mesh.AddSurfaceElement(sel);
numquads++;
}
else
{
dbg << "\n";
for (int k = 1; k <= pnt1_elems.Size(); k++)
{
Element2d & pnt_sel = mesh.SurfaceElement(pnt1_elems.Elem(k));
if(pnt_sel.GetIndex() == mesh.LineSegment(j).si)
{
for(int l = 1; l <= pnt_sel.GetNP(); l++)
{
if(pnt_sel.PNum(l) == segpair_p1)
{
pnt_sel.PNum(l) = mapto.Get(seg_p1);
}
else if(pnt_sel.PNum(l) == segpair_p2)
{
pnt_sel.PNum(l) = mapto.Get(seg_p2);
}
}
}
}
for (int k = 1; k <= pnt2_elems.Size(); k++)
{
Element2d & pnt_sel = mesh.SurfaceElement(pnt2_elems.Elem(k));
if(pnt_sel.GetIndex() == mesh.LineSegment(j).si)
{
for(int l = 1; l <= pnt_sel.GetNP(); l++)
{
if(pnt_sel.PNum(l) == segpair_p1)
{
pnt_sel.PNum(l) = mapto.Get(seg_p1);
}
else if(pnt_sel.PNum(l) == segpair_p2)
{
pnt_sel.PNum(l) = mapto.Get(seg_p2);
}
}
}
}
}
}
else
{
// If the code comes here, it indicates that we are at
// a line segment pair which is at the intersection
// of two surfaces, both of which have to grow boundary
// layers.... here too, remapping the segments to the
// new points is required
mesh.LineSegment(i)[0] = mapto.Get(seg_p1);
mesh.LineSegment(i)[1] = mapto.Get(seg_p2);
mesh.LineSegment(j)[1] = mapto.Get(seg_p1);
mesh.LineSegment(j)[0] = mapto.Get(seg_p2);
}
}
}
}
}
// Add prismatic cells at the boundaries
cout << "Generating prism boundary layer volume elements...." << endl;
for (i = 1; i <= nse; i++)
{
Element2d & sel = mesh.SurfaceElement(i);
if(surfid.Contains(sel.GetIndex()))
{
Element el(PRISM);
for (j = 1; j <= sel.GetNP(); j++)
{
// Check (Doublecheck) if the corresponding point has a
// copy available for remapping
if (mapto.Get(sel.PNum(j)))
{
// Define the points of the newly added Prism cell
el.PNum(j+3) = mapto.Get(sel.PNum(j));
el.PNum(j) = sel.PNum(j);
}
}
el.SetIndex(1);
el.Invert();
mesh.AddVolumeElement(el);
numprisms++;
}
}
// Finally switch the point indices of the surface elements
// to the newly added ones
cout << "Transferring boundary layer surface elements to new vertex references...." << endl;
for (i = 1; i <= nse; i++)
{
Element2d & sel = mesh.SurfaceElement(i);
if(surfid.Contains(sel.GetIndex()))
{
for (j = 1; j <= sel.GetNP(); j++)
{
// Check (Doublecheck) if the corresponding point has a
// copy available for remapping
if (mapto.Get(sel.PNum(j)))
{
// Map the surface elements to the new points
sel.PNum(j) = mapto.Get(sel.PNum(j));
}
}
}
}
// Lock all the prism points so that the rest of the mesh can be
// optimised without invalidating the entire mesh
for (PointIndex pi = mesh.Points().Begin(); pi < mesh.Points().End(); pi++)
{
if(bndnodes.Test(i)) mesh.AddLockedPoint(pi);
}
// Now, actually pull back the old surface points to create
// the actual boundary layers
cout << "Moving and optimising boundary layer points...." << endl;
for (i = 1; i <= np; i++)
{
Array<ElementIndex> vertelems;
if(bndnodes.Test(i))
{
MeshPoint pointtomove;
pointtomove = mesh.Point(i);
if(layer == prismlayers)
{
mesh.Point(i).SetPoint(pointtomove + layerht * growthvectors.Elem(i));
meshtopo.GetVertexElements(i,vertelems);
for(j = 1; j <= vertelems.Size(); j++)
{
// double sfact = 0.9;
Element volel = mesh.VolumeElement(vertelems.Elem(j));
if(((volel.GetType() == TET) || (volel.GetType() == TET10)) && (!volel.IsDeleted()))
{
//while((volel.Volume(mesh.Points()) <= 0.0) && (sfact >= 0.0))
//{
// mesh.Point(i).SetPoint(pointtomove + (sfact * layerht * growthvectors.Elem(i)));
// mesh.ImproveMesh();
// // Try to move the point back by one step but
// // if the volume drops to below zero, double back
// mesh.Point(i).SetPoint(pointtomove + ((sfact + 0.1) * layerht * growthvectors.Elem(i)));
// if(volel.Volume(mesh.Points()) <= 0.0)
// {
// mesh.Point(i).SetPoint(pointtomove + (sfact * layerht * growthvectors.Elem(i)));
// }
// sfact -= 0.1;
//}
volel.Delete();
}
}
mesh.Compress();
}
else
{
mesh.Point(i).SetPoint(pointtomove + layerht * growthvectors.Elem(i));
}
}
}
}
// Optimise the tet part of the volume mesh after all the modifications
// to the system are completed
//OptimizeVolume(mparam,mesh);
cout << "New NP: " << mesh.GetNP() << endl;
cout << "Num of Quads: " << numquads << endl;
cout << "Num of Prisms: " << numprisms << endl;
cout << "Boundary Layer Generation....Done!" << endl;
dbg.close();
}
void RefinePrisms (Mesh & mesh, const CSGeometry * geom,
ZRefinementOptions & opt)
{
int i, j;
bool found, change;
int cnt = 0;
// markers for z-refinement: p1, p2, levels
// p1-p2 is an edge to be refined
ARRAY<INDEX_3> ref_uniform;
ARRAY<INDEX_3> ref_singular;
ARRAY<INDEX_4 > ref_slices;
BitArray first_id(geom->identifications.Size());
first_id.Set();
INDEX_2_HASHTABLE<int> & identpts =
mesh.GetIdentifications().GetIdentifiedPoints ();
if (&identpts)
{
for (i = 1; i <= identpts.GetNBags(); i++)
for (j = 1; j <= identpts.GetBagSize(i); j++)
{
INDEX_2 pair;
int idnr;
identpts.GetData(i, j, pair, idnr);
const CloseSurfaceIdentification * csid =
dynamic_cast<const CloseSurfaceIdentification*>
(geom->identifications.Get(idnr));
if (csid)
{
if (!csid->GetSlices().Size())
{
if (first_id.Test (idnr))
{
first_id.Clear(idnr);
ref_uniform.Append (INDEX_3 (pair.I1(), pair.I2(), csid->RefLevels()));
ref_singular.Append (INDEX_3 (pair.I1(), pair.I2(), csid->RefLevels1()));
ref_singular.Append (INDEX_3 (pair.I2(), pair.I1(), csid->RefLevels2()));
}
}
else
{
//const ARRAY<double> & slices = csid->GetSlices();
INDEX_4 i4;
i4[0] = pair.I1();
i4[1] = pair.I2();
i4[2] = idnr;
i4[3] = csid->GetSlices().Size();
ref_slices.Append (i4);
}
}
}
}
ARRAY<EdgePointGeomInfo> epgi;
while (1)
{
cnt++;
PrintMessage (3, "Z-Refinement, level = ", cnt);
INDEX_2_HASHTABLE<int> refedges(mesh.GetNSE()+1);
found = 0;
// mark prisms due to close surface flags:
int oldsize = ref_uniform.Size();
for (i = 1; i <= oldsize; i++)
{
int pi1 = ref_uniform.Get(i).I1();
int pi2 = ref_uniform.Get(i).I2();
int levels = ref_uniform.Get(i).I3();
if (levels > 0)
{
const Point3d & p1 = mesh.Point(pi1);
const Point3d & p2 = mesh.Point(pi2);
int npi(0);
INDEX_2 edge(pi1, pi2);
edge.Sort();
if (!refedges.Used(edge))
{
Point3d np = Center (p1, p2);
npi = mesh.AddPoint (np);
refedges.Set (edge, npi);
found = 1;
}
ref_uniform.Elem(i) = INDEX_3(pi1, npi, levels-1);
ref_uniform.Append (INDEX_3(pi2, npi, levels-1));
}
}
for (i = 1; i <= ref_singular.Size(); i++)
{
int pi1 = ref_singular.Get(i).I1();
int pi2 = ref_singular.Get(i).I2();
int levels = ref_singular.Get(i).I3();
if (levels > 0)
{
const Point3d & p1 = mesh.Point(pi1);
const Point3d & p2 = mesh.Point(pi2);
int npi;
INDEX_2 edge(pi1, pi2);
edge.Sort();
if (!refedges.Used(edge))
{
Point3d np = Center (p1, p2);
npi = mesh.AddPoint (np);
refedges.Set (edge, npi);
found = 1;
}
else
npi = refedges.Get (edge);
ref_singular.Elem(i) = INDEX_3(pi1, npi, levels-1);
}
}
for (i = 1; i <= ref_slices.Size(); i++)
{
int pi1 = ref_slices.Get(i)[0];
int pi2 = ref_slices.Get(i)[1];
int idnr = ref_slices.Get(i)[2];
int slicenr = ref_slices.Get(i)[3];
if (slicenr > 0)
{
const Point3d & p1 = mesh.Point(pi1);
const Point3d & p2 = mesh.Point(pi2);
int npi;
const CloseSurfaceIdentification * csid =
dynamic_cast<const CloseSurfaceIdentification*>
(geom->identifications.Get(idnr));
INDEX_2 edge(pi1, pi2);
edge.Sort();
if (!refedges.Used(edge))
{
const ARRAY<double> & slices = csid->GetSlices();
//(*testout) << "idnr " << idnr << " i " << i << endl;
//(*testout) << "slices " << slices << endl;
double slicefac = slices.Get(slicenr);
double slicefaclast =
(slicenr == slices.Size()) ? 1 : slices.Get(slicenr+1);
Point3d np = p1 + (slicefac / slicefaclast) * (p2-p1);
//(*testout) << "slicenr " << slicenr << " slicefac " << slicefac << " quot " << (slicefac / slicefaclast) << " np " << np << endl;
npi = mesh.AddPoint (np);
refedges.Set (edge, npi);
found = 1;
}
else
npi = refedges.Get (edge);
ref_slices.Elem(i)[1] = npi;
ref_slices.Elem(i)[3] --;
}
}
for (i = 1; i <= mesh.GetNE(); i++)
{
Element & el = mesh.VolumeElement (i);
if (el.GetType() != PRISM)
continue;
for (j = 1; j <= 3; j++)
{
int pi1 = el.PNum(j);
int pi2 = el.PNum(j+3);
const Point3d & p1 = mesh.Point(pi1);
const Point3d & p2 = mesh.Point(pi2);
bool ref = 0;
/*
if (Dist (p1, p2) > mesh.GetH (Center (p1, p2)))
ref = 1;
*/
/*
if (cnt <= opt.minref)
ref = 1;
*/
/*
if ((pi1 == 460 || pi2 == 460 ||
pi1 == 461 || pi2 == 461) && cnt <= 8) ref = 1;
*/
if (ref == 1)
{
INDEX_2 edge(pi1, pi2);
edge.Sort();
if (!refedges.Used(edge))
{
Point3d np = Center (p1, p2);
int npi = mesh.AddPoint (np);
refedges.Set (edge, npi);
found = 1;
}
}
}
}
if (!found) break;
// build closure:
PrintMessage (5, "start closure");
do
{
PrintMessage (5, "start loop");
change = 0;
for (i = 1; i <= mesh.GetNE(); i++)
{
Element & el = mesh.VolumeElement (i);
if (el.GetType() != PRISM)
continue;
bool hasref = 0, hasnonref = 0;
for (j = 1; j <= 3; j++)
{
int pi1 = el.PNum(j);
int pi2 = el.PNum(j+3);
if (pi1 != pi2)
{
INDEX_2 edge(pi1, pi2);
edge.Sort();
if (refedges.Used(edge))
hasref = 1;
else
hasnonref = 1;
}
}
if (hasref && hasnonref)
{
// cout << "el " << i << " in closure" << endl;
change = 1;
for (j = 1; j <= 3; j++)
{
int pi1 = el.PNum(j);
int pi2 = el.PNum(j+3);
const Point3d & p1 = mesh.Point(pi1);
const Point3d & p2 = mesh.Point(pi2);
INDEX_2 edge(pi1, pi2);
edge.Sort();
if (!refedges.Used(edge))
{
Point3d np = Center (p1, p2);
int npi = mesh.AddPoint (np);
refedges.Set (edge, npi);
}
}
}
}
}
while (change);
PrintMessage (5, "Do segments");
// (*testout) << "closure formed, np = " << mesh.GetNP() << endl;
int oldns = mesh.GetNSeg();
for (i = 1; i <= oldns; i++)
{
const Segment & el = mesh.LineSegment(i);
INDEX_2 i2(el.p1, el.p2);
i2.Sort();
int pnew;
EdgePointGeomInfo ngi;
if (refedges.Used(i2))
{
pnew = refedges.Get(i2);
// ngi = epgi.Get(pnew);
}
else
{
continue;
// Point3d pb;
// /*
// geom->PointBetween (mesh.Point (el.p1),
// mesh.Point (el.p2),
// el.surfnr1, el.surfnr2,
// el.epgeominfo[0], el.epgeominfo[1],
// pb, ngi);
// */
// pb = Center (mesh.Point (el.p1), mesh.Point (el.p2));
// pnew = mesh.AddPoint (pb);
// refedges.Set (i2, pnew);
// if (pnew > epgi.Size())
// epgi.SetSize (pnew);
// epgi.Elem(pnew) = ngi;
}
Segment ns1 = el;
Segment ns2 = el;
ns1.p2 = pnew;
ns1.epgeominfo[1] = ngi;
ns2.p1 = pnew;
ns2.epgeominfo[0] = ngi;
mesh.LineSegment(i) = ns1;
mesh.AddSegment (ns2);
}
PrintMessage (5, "Segments done, NSeg = ", mesh.GetNSeg());
// do refinement
int oldne = mesh.GetNE();
for (i = 1; i <= oldne; i++)
{
Element & el = mesh.VolumeElement (i);
if (el.GetNP() != 6)
continue;
int npi[3];
for (j = 1; j <= 3; j++)
{
int pi1 = el.PNum(j);
int pi2 = el.PNum(j+3);
if (pi1 == pi2)
npi[j-1] = pi1;
else
{
INDEX_2 edge(pi1, pi2);
edge.Sort();
if (refedges.Used (edge))
npi[j-1] = refedges.Get(edge);
else
{
/*
(*testout) << "ERROR: prism " << i << " has hanging node !!"
<< ", edge = " << edge << endl;
cerr << "ERROR: prism " << i << " has hanging node !!" << endl;
*/
npi[j-1] = 0;
}
}
}
if (npi[0])
{
Element nel1(6), nel2(6);
for (j = 1; j <= 3; j++)
{
nel1.PNum(j) = el.PNum(j);
nel1.PNum(j+3) = npi[j-1];
nel2.PNum(j) = npi[j-1];
nel2.PNum(j+3) = el.PNum(j+3);
}
nel1.SetIndex (el.GetIndex());
nel2.SetIndex (el.GetIndex());
mesh.VolumeElement (i) = nel1;
mesh.AddVolumeElement (nel2);
}
}
PrintMessage (5, "Elements done, NE = ", mesh.GetNE());
// do surface elements
int oldnse = mesh.GetNSE();
// cout << "oldnse = " << oldnse << endl;
for (i = 1; i <= oldnse; i++)
{
Element2d & el = mesh.SurfaceElement (i);
if (el.GetType() != QUAD)
continue;
int index = el.GetIndex();
int npi[2];
for (j = 1; j <= 2; j++)
{
int pi1, pi2;
if (j == 1)
{
pi1 = el.PNum(1);
pi2 = el.PNum(4);
}
else
{
pi1 = el.PNum(2);
pi2 = el.PNum(3);
}
if (pi1 == pi2)
npi[j-1] = pi1;
else
{
INDEX_2 edge(pi1, pi2);
edge.Sort();
if (refedges.Used (edge))
npi[j-1] = refedges.Get(edge);
else
{
npi[j-1] = 0;
}
}
}
if (npi[0])
{
Element2d nel1(QUAD), nel2(QUAD);
for (j = 1; j <= 4; j++)
{
nel1.PNum(j) = el.PNum(j);
nel2.PNum(j) = el.PNum(j);
}
nel1.PNum(3) = npi[1];
nel1.PNum(4) = npi[0];
nel2.PNum(1) = npi[0];
nel2.PNum(2) = npi[1];
/*
for (j = 1; j <= 2; j++)
{
nel1.PNum(j) = el.PNum(j);
nel1.PNum(j+2) = npi[j-1];
nel2.PNum(j) = npi[j-1];
nel2.PNum(j+2) = el.PNum(j+2);
}
*/
nel1.SetIndex (el.GetIndex());
nel2.SetIndex (el.GetIndex());
mesh.SurfaceElement (i) = nel1;
mesh.AddSurfaceElement (nel2);
int si = mesh.GetFaceDescriptor (index).SurfNr();
Point<3> hp = mesh.Point(npi[0]);
geom->GetSurface(si)->Project (hp);
mesh.Point (npi[0]).SetPoint (hp);
hp = mesh.Point(npi[1]);
geom->GetSurface(si)->Project (hp);
mesh.Point (npi[1]).SetPoint (hp);
// geom->GetSurface(si)->Project (mesh.Point(npi[0]));
// geom->GetSurface(si)->Project (mesh.Point(npi[1]));
}
}
PrintMessage (5, "Surface elements done, NSE = ", mesh.GetNSE());
}
}
void MeshOptimize2d :: GenericImprove (Mesh & mesh)
{
if (!faceindex)
{
if (writestatus)
PrintMessage (3, "Generic Improve");
for (faceindex = 1; faceindex <= mesh.GetNFD(); faceindex++)
GenericImprove (mesh);
faceindex = 0;
}
// int j, k, l, ri;
int np = mesh.GetNP();
int ne = mesh.GetNSE();
// SurfaceElementIndex sei;
// for (SurfaceElementIndex sei = 0; sei < ne; sei++)
// {
// const Element2d & el = mesh[sei];
// (*testout) << "element " << sei << ": " <<flush;
// for(int j=0; j<el.GetNP(); j++)
// (*testout) << el[j] << " " << flush;
// (*testout) << "IsDeleted() " << el.IsDeleted()<< endl;
// }
bool ok;
int olddef, newdef;
ARRAY<ImprovementRule*> rules;
ARRAY<SurfaceElementIndex> elmap;
ARRAY<int> elrot;
ARRAY<PointIndex> pmap;
ARRAY<PointGeomInfo> pgi;
int surfnr = mesh.GetFaceDescriptor (faceindex).SurfNr();
ImprovementRule * r1;
// 2 triangles to quad
r1 = new ImprovementRule;
r1->oldels.Append (Element2d (1, 2, 3));
r1->oldels.Append (Element2d (3, 2, 4));
r1->newels.Append (Element2d (1, 2, 4, 3));
r1->deledges.Append (INDEX_2 (2,3));
r1->onp = 4;
r1->bonus = 2;
rules.Append (r1);
// 2 quad to 1 quad
r1 = new ImprovementRule;
r1->oldels.Append (Element2d (1, 2, 3, 4));
r1->oldels.Append (Element2d (4, 3, 2, 5));
r1->newels.Append (Element2d (1, 2, 5, 4));
r1->deledges.Append (INDEX_2 (2, 3));
r1->deledges.Append (INDEX_2 (3, 4));
r1->onp = 5;
r1->bonus = 0;
rules.Append (r1);
// swap quads
r1 = new ImprovementRule;
r1->oldels.Append (Element2d (1, 2, 3, 4));
r1->oldels.Append (Element2d (3, 2, 5, 6));
r1->newels.Append (Element2d (1, 6, 3, 4));
r1->newels.Append (Element2d (1, 2, 5, 6));
r1->deledges.Append (INDEX_2 (2, 3));
r1->onp = 6;
r1->bonus = 0;
rules.Append (r1);
// three quads to 2
r1 = new ImprovementRule;
r1->oldels.Append (Element2d (1, 2, 3, 4));
r1->oldels.Append (Element2d (2, 5, 6, 3));
r1->oldels.Append (Element2d (3, 6, 7, 4));
r1->newels.Append (Element2d (1, 2, 5, 4));
r1->newels.Append (Element2d (4, 5, 6, 7));
r1->deledges.Append (INDEX_2 (2, 3));
r1->deledges.Append (INDEX_2 (3, 4));
r1->deledges.Append (INDEX_2 (3, 6));
r1->onp = 7;
r1->bonus = -1;
rules.Append (r1);
// quad + 2 connected trigs to quad
r1 = new ImprovementRule;
r1->oldels.Append (Element2d (1, 2, 3, 4));
r1->oldels.Append (Element2d (2, 5, 3));
r1->oldels.Append (Element2d (3, 5, 4));
r1->newels.Append (Element2d (1, 2, 5, 4));
r1->deledges.Append (INDEX_2 (2, 3));
r1->deledges.Append (INDEX_2 (3, 4));
r1->deledges.Append (INDEX_2 (3, 5));
r1->onp = 5;
r1->bonus = 0;
rules.Append (r1);
// quad + 2 non-connected trigs to quad (a and b)
r1 = new ImprovementRule;
r1->oldels.Append (Element2d (1, 2, 3, 4));
r1->oldels.Append (Element2d (2, 6, 3));
r1->oldels.Append (Element2d (1, 4, 5));
r1->newels.Append (Element2d (1, 3, 4, 5));
r1->newels.Append (Element2d (1, 2, 6, 3));
r1->deledges.Append (INDEX_2 (1, 4));
r1->deledges.Append (INDEX_2 (2, 3));
r1->onp = 6;
r1->bonus = 0;
rules.Append (r1);
r1 = new ImprovementRule;
r1->oldels.Append (Element2d (1, 2, 3, 4));
r1->oldels.Append (Element2d (2, 6, 3));
r1->oldels.Append (Element2d (1, 4, 5));
r1->newels.Append (Element2d (1, 2, 4, 5));
r1->newels.Append (Element2d (4, 2, 6, 3));
r1->deledges.Append (INDEX_2 (1, 4));
r1->deledges.Append (INDEX_2 (2, 3));
r1->onp = 6;
r1->bonus = 0;
rules.Append (r1);
// two quad + trig -> one quad + trig
r1 = new ImprovementRule;
r1->oldels.Append (Element2d (1, 2, 3, 4));
r1->oldels.Append (Element2d (2, 5, 6, 3));
r1->oldels.Append (Element2d (4, 3, 6));
r1->newels.Append (Element2d (1, 2, 6, 4));
r1->newels.Append (Element2d (2, 5, 6));
r1->deledges.Append (INDEX_2 (2, 3));
r1->deledges.Append (INDEX_2 (3, 4));
r1->deledges.Append (INDEX_2 (3, 6));
r1->onp = 6;
r1->bonus = -1;
rules.Append (r1);
// swap quad + trig (a and b)
r1 = new ImprovementRule;
r1->oldels.Append (Element2d (1, 2, 3, 4));
r1->oldels.Append (Element2d (2, 5, 3));
r1->newels.Append (Element2d (2, 5, 3, 4));
r1->newels.Append (Element2d (1, 2, 4));
r1->deledges.Append (INDEX_2 (2, 3));
r1->onp = 5;
r1->bonus = 0;
rules.Append (r1);
r1 = new ImprovementRule;
r1->oldels.Append (Element2d (1, 2, 3, 4));
r1->oldels.Append (Element2d (2, 5, 3));
r1->newels.Append (Element2d (1, 2, 5, 3));
r1->newels.Append (Element2d (1, 3, 4));
r1->deledges.Append (INDEX_2 (2, 3));
r1->onp = 5;
r1->bonus = 0;
rules.Append (r1);
// 2 quads to quad + 2 trigs
r1 = new ImprovementRule;
r1->oldels.Append (Element2d (1, 2, 3, 4));
r1->oldels.Append (Element2d (3, 2, 5, 6));
r1->newels.Append (Element2d (1, 5, 6, 4));
r1->newels.Append (Element2d (1, 2, 5));
r1->newels.Append (Element2d (4, 6, 3));
r1->deledges.Append (INDEX_2 (2, 3));
r1->onp = 6;
r1->bonus = 0;
// rules.Append (r1);
ARRAY<int> mapped(rules.Size());
ARRAY<int> used(rules.Size());
used = 0;
mapped = 0;
for (int ri = 0; ri < rules.Size(); ri++)
{
ImprovementRule & rule = *rules[ri];
rule.incelsonnode.SetSize (rule.onp);
rule.reused.SetSize (rule.onp);
for (int j = 1; j <= rule.onp; j++)
{
rule.incelsonnode.Elem(j) = 0;
rule.reused.Elem(j) = 0;
}
for (int j = 1; j <= rule.oldels.Size(); j++)
{
const Element2d & el = rule.oldels.Elem(j);
for (int k = 1; k <= el.GetNP(); k++)
rule.incelsonnode.Elem(el.PNum(k))--;
}
for (int j = 1; j <= rule.newels.Size(); j++)
{
const Element2d & el = rule.newels.Elem(j);
for (int k = 1; k <= el.GetNP(); k++)
{
rule.incelsonnode.Elem(el.PNum(k))++;
rule.reused.Elem(el.PNum(k)) = 1;
}
}
}
TABLE<int,PointIndex::BASE> elonnode(np);
ARRAY<int,PointIndex::BASE> nelonnode(np);
TABLE<SurfaceElementIndex> nbels(ne);
nelonnode = -4;
for (SurfaceElementIndex sei = 0; sei < ne; sei++)
{
const Element2d & el = mesh[sei];
if (el.GetIndex() == faceindex && !el.IsDeleted())
{
for (int j = 0; j < el.GetNP(); j++)
elonnode.Add (el[j], sei);
}
if(!el.IsDeleted())
{
for (int j = 0; j < el.GetNP(); j++)
nelonnode[el[j]]++;
}
}
for (SurfaceElementIndex sei = 0; sei < ne; sei++)
{
const Element2d & el = mesh[sei];
if (el.GetIndex() == faceindex && !el.IsDeleted())
{
for (int j = 0; j < el.GetNP(); j++)
{
for (int k = 0; k < elonnode[el[j]].Size(); k++)
{
int nbel = elonnode[el[j]] [k];
bool inuse = false;
for (int l = 0; l < nbels[sei].Size(); l++)
if (nbels[sei][l] == nbel)
inuse = true;
if (!inuse)
nbels.Add (sei, nbel);
}
}
}
}
for (int ri = 0; ri < rules.Size(); ri++)
{
const ImprovementRule & rule = *rules[ri];
elmap.SetSize (rule.oldels.Size());
elrot.SetSize (rule.oldels.Size());
pmap.SetSize (rule.onp);
pgi.SetSize (rule.onp);
for (SurfaceElementIndex sei = 0; sei < ne; sei++)
{
if (multithread.terminate)
break;
if (mesh[sei].IsDeleted()) continue;
elmap[0] = sei;
FlatArray<SurfaceElementIndex> neighbours = nbels[sei];
for (elrot[0] = 0; elrot[0] < mesh[sei].GetNP(); elrot[0]++)
{
const Element2d & el0 = mesh[sei];
const Element2d & rel0 = rule.oldels[0];
if (el0.GetIndex() != faceindex) continue;
if (el0.IsDeleted()) continue;
if (el0.GetNP() != rel0.GetNP()) continue;
pmap = -1;
for (int k = 0; k < el0.GetNP(); k++)
{
pmap.Elem(rel0[k]) = el0.PNumMod(k+elrot[0]+1);
pgi.Elem(rel0[k]) = el0.GeomInfoPiMod(k+elrot[0]+1);
}
ok = 1;
for (int i = 1; i < elmap.Size(); i++)
{
// try to find a mapping for reference-element i
const Element2d & rel = rule.oldels[i];
bool possible = 0;
for (elmap[i] = 0; elmap[i] < neighbours.Size(); elmap[i]++)
{
const Element2d & el = mesh[neighbours[elmap[i]]];
if (el.IsDeleted()) continue;
if (el.GetNP() != rel.GetNP()) continue;
for (elrot[i] = 0; elrot[i] < rel.GetNP(); elrot[i]++)
{
possible = 1;
for (int k = 0; k < rel.GetNP(); k++)
if (pmap.Elem(rel[k]) != -1 &&
pmap.Elem(rel[k]) != el.PNumMod (k+elrot[i]+1))
possible = 0;
if (possible)
{
for (int k = 0; k < el.GetNP(); k++)
{
pmap.Elem(rel[k]) = el.PNumMod(k+elrot[i]+1);
pgi.Elem(rel[k]) = el.GeomInfoPiMod(k+elrot[i]+1);
}
break;
}
}
if (possible) break;
}
if (!possible)
{
ok = 0;
break;
}
elmap[i] = neighbours[elmap[i]];
}
for(int i=0; ok && i<rule.deledges.Size(); i++)
{
ok = !mesh.IsSegment(pmap.Elem(rule.deledges[i].I1()),
pmap.Elem(rule.deledges[i].I2()));
}
if (!ok) continue;
mapped[ri]++;
olddef = 0;
for (int j = 1; j <= pmap.Size(); j++)
olddef += sqr (nelonnode[pmap.Get(j)]);
olddef += rule.bonus;
newdef = 0;
for (int j = 1; j <= pmap.Size(); j++)
if (rule.reused.Get(j))
newdef += sqr (nelonnode[pmap.Get(j)] +
rule.incelsonnode.Get(j));
if (newdef > olddef)
continue;
// calc metric badness
double bad1 = 0, bad2 = 0;
Vec<3> n;
SelectSurfaceOfPoint (mesh.Point(pmap.Get(1)), pgi.Get(1));
GetNormalVector (surfnr, mesh.Point(pmap.Get(1)), pgi.Elem(1), n);
for (int j = 1; j <= rule.oldels.Size(); j++)
bad1 += mesh.SurfaceElement(elmap.Get(j)).CalcJacobianBadness (mesh.Points(), n);
// check new element:
for (int j = 1; j <= rule.newels.Size(); j++)
{
const Element2d & rnel = rule.newels.Get(j);
Element2d nel(rnel.GetNP());
for (int k = 1; k <= rnel.GetNP(); k++)
nel.PNum(k) = pmap.Get(rnel.PNum(k));
bad2 += nel.CalcJacobianBadness (mesh.Points(), n);
}
if (bad2 > 1e3) continue;
if (newdef == olddef && bad2 > bad1) continue;
// generate new element:
for (int j = 1; j <= rule.newels.Size(); j++)
{
const Element2d & rnel = rule.newels.Get(j);
Element2d nel(rnel.GetNP());
nel.SetIndex (faceindex);
for (int k = 1; k <= rnel.GetNP(); k++)
{
nel.PNum(k) = pmap.Get(rnel.PNum(k));
nel.GeomInfoPi(k) = pgi.Get(rnel.PNum(k));
}
mesh.AddSurfaceElement(nel);
}
for (int j = 0; j < rule.oldels.Size(); j++)
mesh.DeleteSurfaceElement ( elmap[j] );
for (int j = 1; j <= pmap.Size(); j++)
nelonnode[pmap.Get(j)] += rule.incelsonnode.Get(j);
used[ri]++;
}
}
}
mesh.Compress();
for (int ri = 0; ri < rules.Size(); ri++)
{
PrintMessage (5, "rule ", ri+1, " ",
mapped[ri], "/", used[ri], " mapped/used");
}
}
