static double LC_MVertex_CURV(GEntity *ge, double U, double V)
{
double Crv = 0;
switch(ge->dim()){
case 0:
Crv = max_edge_curvature((const GVertex *)ge);
//Crv = std::max(max_surf_curvature_vertex((const GVertex *)ge), Crv);
// Crv = max_surf_curvature((const GVertex *)ge);
break;
case 1:
{
GEdge *ged = (GEdge *)ge;
Crv = ged->curvature(U);
Crv = std::max(Crv, max_surf_curvature(ged, U));
// Crv = max_surf_curvature(ged, U);
}
break;
case 2:
{
GFace *gf = (GFace *)ge;
Crv = gf->curvature(SPoint2(U, V));
}
break;
}
double lc = Crv > 0 ? 2 * M_PI / Crv / CTX::instance()->mesh.minCircPoints : MAX_LC;
return lc;
}
// compute the mesh size at a given vertex due to prescribed sizes at
// mesh vertices
static double LC_MVertex_PNTS(GEntity *ge, double U, double V)
{
switch(ge->dim()){
case 0:
{
GVertex *gv = (GVertex *)ge;
double lc = gv->prescribedMeshSizeAtVertex();
// FIXME we might want to remove this to make all lc treatment consistent
if(lc >= MAX_LC) return CTX::instance()->lc / 10.;
return lc;
}
case 1:
{
GEdge *ged = (GEdge *)ge;
GVertex *v1 = ged->getBeginVertex();
GVertex *v2 = ged->getEndVertex();
if (v1 && v2){
Range<double> range = ged->parBounds(0);
double a = (U - range.low()) / (range.high() - range.low());
double lc = (1 - a) * v1->prescribedMeshSizeAtVertex() +
(a) * v2->prescribedMeshSizeAtVertex() ;
// FIXME we might want to remove this to make all lc treatment consistent
if(lc >= MAX_LC) return CTX::instance()->lc / 10.;
return lc;
}
else
return MAX_LC;
}
default:
return MAX_LC;
}
}
GEdgeLoop::GEdgeLoop(const std::list<GEdge*> &cwire)
{
// Sometimes OCC puts a nasty degenerated edge in the middle of the
// wire ... pushing it to front fixes the problem as it concerns
// gmsh
std::list<GEdge*> wire;
std::vector<GEdge*> degenerated;
GEdge *degeneratedToInsert = 0;
for (std::list<GEdge*>::const_iterator it = cwire.begin(); it != cwire.end(); ++it){
GEdge *ed = *it;
if (ed->degenerate(0))degenerated.push_back(ed);
else wire.push_back(ed);
}
if (degenerated.size() == 1){
wire.push_front(degenerated[0]);
}
else if (degenerated.size() == 2){
degeneratedToInsert = degenerated[1];
wire.push_front(degenerated[0]);
}
else if (degenerated.size() > 2){
Msg::Error("More than two degenerated edges in one model face");
}
while (!wire.empty()){
// printf("wire.size = %d\n",wire.size());
loopTheLoop(wire,loop,°eneratedToInsert);
// break;
}
}
GEdge *GNode< Point >::Search( Long n, Long i ) const {
GEdge *p;
for (p=adjacents; p != NULL; p=p->Next())
if (( p->Item() == i) && (p->Node() == n))
break;
return p;
}
/**
* Destructor for node - removes edge controls on incidient edges and disconnects item from scene
*/
GNode::~GNode()
{
graph()->invalidateRanking();
if ( ( isEdgeControl() || isEdgeLabel())
&& isNotNullP( firstPred())
&& isNotNullP( firstSucc())
&& isNotNullP( firstPred()->pred())
&& isNotNullP( firstSucc()->succ()))
{
GRAPH_ASSERTD( areEqP( firstPred()->style(), firstSucc()->style()),
"Different styles on the same edge");
GEdge *e = graph()->newEdge( firstPred()->pred(), firstSucc()->succ());
e->setStyle( firstPred()->style());
} else if ( isSimple())
{
QList< GNode *> nodes;
GEdge* edge;
Marker m = graph()->newMarker();
for ( edge = firstSucc(); isNotNullP( edge); edge = edge->nextSucc())
{
edge->item()->adjust();
GNode* succ = edge->succ();
while ( succ->isEdgeControl() || succ->isEdgeLabel())
{
assert( isNotNullP( succ->firstSucc()));
if ( succ->mark( m))
{
nodes << succ;
}
succ = succ->firstSucc()->succ();
}
}
for ( edge = firstPred(); isNotNullP( edge); edge = edge->nextPred())
{
if ( edge->isSelf()) // We've already processed this one in previous loop
continue;
edge->item()->adjust();
GNode* pred = edge->pred();
while ( pred->isEdgeControl() || pred->isEdgeLabel())
{
assert( isNotNullP( pred->firstPred()));
if ( pred->mark( m))
{
nodes << pred;
}
pred = pred->firstPred()->pred();
}
}
foreach ( GNode *n, nodes)
{
graph()->deleteNode( n);
}
graph()->freeMarker( m);
}
/**
* Change edge's style
*/
void GGraph::setEdgeStyle( GStyle *style)
{
if ( sel_edges.isEmpty())
return;
GEdge* edge = sel_edges.first();
edge->setStyle( style);
edge->item()->adjust();
}
GEdge * Graph::getEdge(long firstNode, long secondNode){
GEdge *p = tnode[firstNode]->getIncidentEdges();
while(p){
if (p->IncidentNode() == secondNode)
return p;
else
p=p->Next();
}
return NULL;
}
bool reparamMeshVertexOnFace(MVertex *v, const GFace *gf, SPoint2 ¶m,
bool onSurface)
{
if (gf->geomType() == GEntity::CompoundSurface ){
GFaceCompound *gfc = (GFaceCompound*) gf;
param = gfc->parFromVertex(v);
return true;
}
if(v->onWhat()->geomType() == GEntity::DiscreteCurve ||
v->onWhat()->geomType() == GEntity::BoundaryLayerCurve){
param = gf->parFromPoint(SPoint3(v->x(), v->y(), v->z()), onSurface);
return true;
}
if(v->onWhat()->dim() == 0){
GVertex *gv = (GVertex*)v->onWhat();
// hack for bug in periodic curves
if (gv->getNativeType() == GEntity::GmshModel && gf->geomType() == GEntity::Plane)
param = gf->parFromPoint(SPoint3(v->x(), v->y(), v->z()), onSurface);
else
param = gv->reparamOnFace(gf, 1);
// shout, we could be on a seam
std::list<GEdge*> ed = gv->edges();
for(std::list<GEdge*>::iterator it = ed.begin(); it != ed.end(); it++)
if((*it)->isSeam(gf)) return false;
}
else if(v->onWhat()->dim() == 1){
GEdge *ge = (GEdge*)v->onWhat();
double t;
v->getParameter(0, t);
param = ge->reparamOnFace(gf, t, 1);
if(!v->getParameter(0,t)) {
Msg::Error("Vertex %p not MEdgeVertex", v);
return false;
//param = gf->parFromPoint(SPoint3(v->x(), v->y(), v->z()), onSurface);
}
// shout, we are on a seam
if(ge->isSeam(gf))
return false;
}
else{
double uu, vv;
if(v->onWhat() == gf && v->getParameter(0, uu) && v->getParameter(1, vv)){
param = SPoint2(uu, vv);
}
else {
// brute force!
param = gf->parFromPoint(SPoint3(v->x(), v->y(), v->z()), onSurface);
}
}
return true;
}
double distanceToGeometry(GModel *gm, int dim, int tag, int distType,
double tol, int meshDiscr, int geomDiscr)
{
double maxDist = 0.;
if (dim == 2) {
GEdge *ge = gm->getEdgeByTag(tag);
if (ge->geomType() == GEntity::Line) return 0.;
for (unsigned int i = 0; i < ge->lines.size(); i++) {
double dist;
switch (distType) {
case CADDIST_TAYLOR:
dist = taylorDistanceEdge(ge->lines[i], ge);
break;
case CADDIST_FRECHET:
dist = discreteFrechetDistanceEdge(ge->lines[i], ge,
tol, meshDiscr, geomDiscr);
break;
case CADDIST_HAUSFAST:
dist = discreteHausdorffDistanceFastEdge(ge->lines[i], ge,
tol, meshDiscr, geomDiscr);
break;
case CADDIST_HAUSBRUTE:
dist = discreteHausdorffDistanceBruteEdge(ge->lines[i], ge,
tol, meshDiscr, geomDiscr);
break;
default:
Msg::Error("Wrong CAD distance type in distanceToGeometry");
return -1.;
break;
}
maxDist = std::max(dist, maxDist);
}
}
else if (dim == 3) {
if (distType == CADDIST_TAYLOR) {
GFace *gf = gm->getFaceByTag(tag);
if (gf->geomType() == GEntity::Plane) return 0.;
for (unsigned int i = 0; i < gf->triangles.size(); i++)
maxDist = std::max(taylorDistanceFace(gf->triangles[i], gf), maxDist);
for (unsigned int i = 0; i < gf->quadrangles.size(); i++)
maxDist = std::max(taylorDistanceFace(gf->quadrangles[i], gf), maxDist);
}
else {
Msg::Error("CAD distance type %i not implemented for surfaces", distType);
return -1.;
}
}
else {
Msg::Error("CAD distance cannot be computed for dimension %i", dim);
return -1.;
}
return maxDist;
}
GEdgeSigned nextOne(GEdgeSigned *thisOne, std::list<GEdge*> &wire)
{
if(!thisOne){
GEdge *ge = *(wire.begin());
wire.erase(wire.begin());
return GEdgeSigned(1, ge);
}
GVertex *gv = thisOne->getEndVertex();
std::list<GEdge*> possibleChoices;
std::list<GEdge*>::iterator it = wire.begin();
std::list<GEdge*>::iterator ite = wire.end();
while(it != ite){
GEdge *ge = *it;
GVertex *v1 = ge->getBeginVertex();
GVertex *v2 = ge->getEndVertex();
if(v1 == gv || v2 == gv) possibleChoices.push_back(ge);
++it;
}
it = possibleChoices.begin();
ite = possibleChoices.end();
while(it != ite){
GEdge *ge = *it;
if(countInList(possibleChoices, ge) == 2){
wire.erase(std::remove_if(wire.begin(), wire.end(),
std::bind2nd(std::equal_to<GEdge*>(), ge)),
wire.end());
wire.push_back(ge);
GVertex *v1 = ge->getBeginVertex();
GVertex *v2 = ge->getEndVertex();
if(v1 == gv) return GEdgeSigned(1, ge);
if(v2 == gv) return GEdgeSigned(-1, ge);
Msg::Error("Something wrong in edge loop 1");
thisOne->print();
}
++it;
}
it = possibleChoices.begin();
ite = possibleChoices.end();
while(it != ite){
GEdge *ge = *it;
if(ge != thisOne->ge){
wire.erase(std::remove_if(wire.begin(),wire.end(),
std::bind2nd(std::equal_to<GEdge*>(), ge)),
wire.end());
GVertex *v1 = ge->getBeginVertex();
GVertex *v2 = ge->getEndVertex();
if(v1 == gv) return GEdgeSigned(1, ge);
if(v2 == gv) return GEdgeSigned(-1, ge);
Msg::Error("Something wrong in edge loop 2");
thisOne->print();
}
++it;
}
// should never end up here
return GEdgeSigned(0, 0);
}
void Centerline::importFile(std::string fileName)
{
current = GModel::current();
std::vector<GFace*> currentFaces(current->firstFace(), current->lastFace());
for (unsigned int i = 0; i < currentFaces.size(); i++){
GFace *gf = currentFaces[i];
if (gf->geomType() == GEntity::DiscreteSurface){
for(unsigned int j = 0; j < gf->triangles.size(); j++)
triangles.push_back(gf->triangles[j]);
if (is_cut){
gf->triangles.clear();
gf->deleteVertexArrays();
current->remove(gf);
}
}
}
if(triangles.empty()){
Msg::Error("Current GModel has no triangles ...");
return;
}
mod = new GModel();
mod->load(fileName);
mod->removeDuplicateMeshVertices(1.e-8);
current->setAsCurrent();
current->setVisibility(1);
int maxN = 0.0;
std::vector<GEdge*> modEdges(mod->firstEdge(), mod->lastEdge());
MVertex *vin = modEdges[0]->lines[0]->getVertex(0);
ptin = SPoint3(vin->x(), vin->y(), vin->z());
for (unsigned int i = 0; i < modEdges.size(); i++){
GEdge *ge = modEdges[i];
for(unsigned int j = 0; j < ge->lines.size(); j++){
MLine *l = ge->lines[j];
MVertex *v0 = l->getVertex(0);
MVertex *v1 = l->getVertex(1);
std::map<MVertex*, int>::iterator it0 = colorp.find(v0);
std::map<MVertex*, int>::iterator it1 = colorp.find(v1);
if (it0 == colorp.end() || it1 == colorp.end()){
lines.push_back(l);
colorl.insert(std::make_pair(l, ge->tag()));
maxN = std::max(maxN, ge->tag());
}
if (it0 == colorp.end()) colorp.insert(std::make_pair(v0, ge->tag()));
if (it1 == colorp.end()) colorp.insert(std::make_pair(v1, ge->tag()));
}
}
createBranches(maxN);
}
/*
* Removes the node `n' in graph.
* -> Removes all refences in its
* neighbourhood nodes.
*/
Errc Graph3d::Del( Long n ) {
GEdge *p;
if (!tnode[n])
return FAILURE;
for (p=tnode[n]->Neighbours(); p!=NULL;p=p->Next()){
tnode[p->Node()]->Del(n);
}
delete tnode[n];
tnode[n]=NULL;
return SUCCESS;
}
void Centerline::createSplitCompounds()
{
//number of discrete vertices, edges, faces and regions for the mesh
NV = current->getMaxElementaryNumber(0);
NE = current->getMaxElementaryNumber(1);
NF = current->getMaxElementaryNumber(2);
NR = current->getMaxElementaryNumber(3);
// Remesh new faces (Compound Lines and Compound Surfaces)
Msg::Info("Centerline: creating split compounds ...");
//Parametrize Compound Lines
for (int i=0; i < NE; i++){
std::vector<GEdge*>e_compound;
GEdge *pe = current->getEdgeByTag(i+1);//current edge
e_compound.push_back(pe);
int num_gec = NE+i+1;
Msg::Info("Create Compound Line (%d) = %d discrete edge",
num_gec, pe->tag());
GEdge *gec = current->addCompoundEdge(e_compound,num_gec);
if (CTX::instance()->mesh.algo2d != ALGO_2D_BAMG){
gec->meshAttributes.method = MESH_TRANSFINITE;
gec->meshAttributes.nbPointsTransfinite = nbPoints+1;
gec->meshAttributes.typeTransfinite = 0;
gec->meshAttributes.coeffTransfinite = 1.0;
}
}
// Parametrize Compound surfaces
std::list<GEdge*> U0;
for (int i=0; i < NF; i++){
std::vector<GFace*> f_compound;
GFace *pf = current->getFaceByTag(i+1);//current face
f_compound.push_back(pf);
int num_gfc = NF+i+1;
Msg::Info("Create Compound Surface (%d) = %d discrete face",
num_gfc, pf->tag());
//1=conf_spectral 4=convex_circle, 7=conf_fe
GFace *gfc = current->addCompoundFace(f_compound, 7, 0, num_gfc);
gfc->meshAttributes.recombine = recombine;
gfc->addPhysicalEntity(1);
current->setPhysicalName("wall", 2, 1);//tag 1
}
}
/*
* Creates a copy of graph g.
*/
Graph3d &Graph3d::operator=( const Graph3d &g ) {
Long i;
GEdge *l;
New(g.size,g.ndep,g.nrow,g.ncol);
for (i=0; i<size; i++){
if (g[i] != NULL){
Add(i,g[i]->Item(),g[i]->seed);
tnode[i]->value=g[i]->value;
for (l=g[i]->Neighbours(); l!=NULL; l=l->Next()){
if (i>l->Node())
Link(i,l->Node(),l->Item(),l->weight);
}
}
}
return *this;
}
static double _relocateVertex(GFace *gf, MVertex *ver,
const std::vector<MElement *> <, double tol)
{
if(ver->onWhat()->dim() != 2) return 2.0;
SPoint2 p1(0, 0);
SPoint2 p2;
if(ver->getParameter(0, p2[0])) {
ver->getParameter(1, p2[1]);
}
else {
return _relocateVertex2(gf, ver, lt, tol);
}
std::size_t counter = 0;
for(std::size_t i = 0; i < lt.size(); i++) {
for(std::size_t j = 0; j < lt[i]->getNumVertices(); j++) {
MVertex *v = lt[i]->getVertex(j);
SPoint2 pp;
reparamMeshVertexOnFace(v, gf, pp);
counter++;
if(v->onWhat()->dim() == 1) {
GEdge *ge = dynamic_cast<GEdge *>(v->onWhat());
// do not take any chance
if(ge->isSeam(gf)) return 2.0;
}
p1 += pp;
}
}
p1 *= 1. / (double)counter;
double worst;
double xi = Maximize_Quality_Golden_Section(ver, gf, p1, p2, lt, tol, worst);
// if (xi != 0) printf("xi = %g\n",xi);
SPoint2 p = p1 * (1 - xi) + p2 * xi;
GPoint pp = gf->point(p);
if(!pp.succeeded()) return 2.0;
ver->x() = pp.x();
ver->y() = pp.y();
ver->z() = pp.z();
ver->setParameter(0, pp.u());
ver->setParameter(1, pp.v());
return worst;
}
GEdge *GNode::UnConnect( long incidentNode ) {
GEdge *p = getIncidentEdges();
GEdge *q;
if (!p) return NULL;
if(p->IncidentNode() == incidentNode){
adjacents = p->Next();
delete p;
}
return adjacents;
while (p->Next())
{
if(p->Next()->IncidentNode() == incidentNode){
q = p->Next();
p->Next(q->Next());
delete q;
}else
p = p->Next();
}
return adjacents;
}
static void getAllParameters(MVertex *v, GFace *gf, std::vector<SPoint2> ¶ms)
{
params.clear();
if (gf->geomType() == GEntity::CompoundSurface ){
GFaceCompound *gfc = (GFaceCompound*) gf;
params.push_back(gfc->parFromVertex(v));
return;
}
if(v->onWhat()->dim() == 0){
GVertex *gv = (GVertex*)v->onWhat();
std::list<GEdge*> ed = gv->edges();
bool seam = false;
for(std::list<GEdge*>::iterator it = ed.begin(); it != ed.end(); it++){
if((*it)->isSeam(gf)) {
Range<double> range = (*it)->parBounds(0);
if (gv == (*it)->getBeginVertex()){
params.push_back((*it)->reparamOnFace(gf, range.low(),-1));
params.push_back((*it)->reparamOnFace(gf, range.low(), 1));
}
if (gv == (*it)->getEndVertex()){
params.push_back((*it)->reparamOnFace(gf, range.high(),-1));
params.push_back((*it)->reparamOnFace(gf, range.high(), 1));
}
if (gv != (*it)->getBeginVertex() && gv != (*it)->getEndVertex()){
Msg::Warning("Strange!");
}
seam = true;
}
}
if (!seam)
params.push_back(gv->reparamOnFace(gf, 1));
}
else if(v->onWhat()->dim() == 1){
GEdge *ge = (GEdge*)v->onWhat();
if(!ge->haveParametrization()) return;
double UU;
v->getParameter(0, UU);
if (UU == 0.0)
UU = ge->parFromPoint(v->point());
params.push_back(ge->reparamOnFace(gf, UU, 1));
if(ge->isSeam(gf))
params.push_back(ge->reparamOnFace(gf, UU, -1));
}
else{
double UU, VV;
if(v->onWhat() == gf && v->getParameter(0, UU) && v->getParameter(1, VV))
params.push_back(SPoint2(UU, VV));
}
}
GEdge *GNode< Point >::Del( Long n ) {
GEdge *p = Neighbours();
GEdge *q;
if (!p) return NULL;
while (p && ( p->Node() == n ))
{
etrash.push_back(p);
p = p->Next();
adjacents = p;
}
for ( q=p; q != NULL ; q=q->Next() ) {
if ( q->Node() == n ) {
p->Next(q->Next());
etrash.push_back(q);
// delete(q); // Problem when using Neighbours() list: cannot delete
}
else p=q;
}
return adjacents;
}
void Mesh::approximationErrorAndGradients(int iEl, double &f, std::vector<double> &gradF, double eps,
simpleFunction<double> &fct)
{
std::vector<SPoint3> _xyz_temp;
for (int iV = 0; iV < nVert(); iV++){
_xyz_temp.push_back(SPoint3( _vert[iV]->x(), _vert[iV]->y(), _vert[iV]->z()));
_vert[iV]->setXYZ(_xyz[iV].x(),_xyz[iV].y(),_xyz[iV].z());
}
MElement *element = _el[iEl];
f = approximationError (fct, element);
// FIME
// if (iEl < 1)printf("approx error elem %d = %g\n",iEl,f);
int currentId = 0;
// compute the size of the gradient
// depends on how many dofs exist per vertex (0,1,2 or 3)
for (size_t i = 0; i < element->getNumVertices(); ++i) {
if (_el2FV[iEl][i] >= 0) {// some free coordinates
currentId += _nPCFV[_el2FV[iEl][i]];
}
}
gradF.clear();
gradF.resize(currentId, 0.);
currentId = 0;
for (size_t i = 0; i < element->getNumVertices(); ++i) {
if (_el2FV[iEl][i] >= 0) {// some free coordinates
MVertex *v = element->getVertex(i);
// vertex classified on a model edge
if (_nPCFV[_el2FV[iEl][i]] == 1){
double t = _uvw[_el2FV[iEl][i]].x();
GEdge *ge = (GEdge*)v->onWhat();
SPoint3 p (v->x(),v->y(),v->z());
GPoint d = ge->point(t+eps);
v->setXYZ(d.x(),d.y(),d.z());
double f_d = approximationError (fct, element);
gradF[currentId++] = (f_d-f)/eps;
if (iEl < 1)printf("df = %g\n",(f_d-f)/eps);
v->setXYZ(p.x(),p.y(),p.z());
}
else if (_nPCFV[_el2FV[iEl][i]] == 2){
double uu = _uvw[_el2FV[iEl][i]].x();
double vv = _uvw[_el2FV[iEl][i]].y();
GFace *gf = (GFace*)v->onWhat();
SPoint3 p (v->x(),v->y(),v->z());
GPoint d = gf->point(uu+eps,vv);
v->setXYZ(d.x(),d.y(),d.z());
double f_u = approximationError (fct, element);
gradF[currentId++] = (f_u-f)/eps;
d = gf->point(uu,vv+eps);
v->setXYZ(d.x(),d.y(),d.z());
double f_v = approximationError (fct, element);
gradF[currentId++] = (f_v-f)/eps;
v->setXYZ(p.x(),p.y(),p.z());
// if (iEl < 1)printf("df = %g %g\n",(f_u-f)/eps,(f_v-f)/eps);
}
}
}
for (int iV = 0; iV < nVert(); iV++)
_vert[iV]->setXYZ(_xyz_temp[iV].x(),_xyz_temp[iV].y(),_xyz_temp[iV].z());
}
void
TestParser::parseLine( QString line)
{
QString n_str("Node ");
QString e_str("Edge ");
/** Node recognition */
QRegExp node_rx("CF ?(Enter)? ?(\\w*) Node (\\d+)");
/** Edge recognition */
QRegExp edge_rx("CF EDGE (\\d+) \\[(\\d+)->(\\d+)\\]");
QTextStream stream( stdout);
/** Expression recognition */
int pos = 0;
if ( edge_rx.indexIn( line) != -1)
{
QString name = e_str.append( edge_rx.cap(1));
QString pred_name("Node ");
pred_name.append( edge_rx.cap( 2));
QString succ_name("Node ");
succ_name.append( edge_rx.cap( 3));
/** Back edge */
QRegExp back_rx("Back");
/** Add edge to symtab */
if ( symtab.find( name) == symtab.end()
&& symtab.find( pred_name) != symtab.end()
&& symtab.find( succ_name) != symtab.end())
{
SymEdge *edge = new SymEdge( name);
edge->setPred( pred_name);
edge->setSucc( succ_name);
symtab[ name] = edge;
/** Add edge to graph */
GNode* pred = static_cast< SymNode *>( symtab[ pred_name])->node();
GNode* succ = static_cast< SymNode *>( symtab[ succ_name])->node();
GEdge* e = graph->graph()->newEdge( pred, succ);
#ifdef _DEBUG
//stream << name << ": " << pred_name << "->" << succ_name << endl;
#endif
if ( back_rx.indexIn( line) != -1 && !e->isSelf())
{
GNode* label = e->insertLabelNode( QPointF( 0,0));
label->item()->setPlainText( "Back");
}
}
} else if ( node_rx.indexIn( line) != -1 )
{
bool good_id = false;
int ir_id = node_rx.cap(3).toInt( &good_id);
QString text = QString("Node ").append( node_rx.cap(3));
QString name = n_str.append( node_rx.cap(3));
if ( !node_rx.cap( 1).isEmpty())
{
text.append("\n").append( node_rx.cap(1));
}
if ( !node_rx.cap( 2).isEmpty())
{
text.append("\n").append( node_rx.cap(2));
}
/** Add node to symtab */
if ( symtab.find( name ) == symtab.end())
{
SymNode* node = new SymNode( name);
curr_node = static_cast<CFNode *>( graph->graph()->newNode());
curr_node->setDoc( new QTextDocument());
node->setNode( curr_node);
node->node()->item()->setPlainText( text);
if ( good_id)
{
node->node()->setIRId( ir_id);
}
symtab[ name] = node;
#ifdef _DEBUG
//stream << name << endl;
#endif
}
} else
{
if ( !isStateNode())
setStateDefault();
}
if ( isStateNode())
{
node_text.append( line).append( "\n");
}
}
bool OptHOM::addBndObjGrad(double factor, double &Obj, alglib::real_1d_array &gradObj)
{
// set the mesh to its present position
std::vector<SPoint3> xyz,uvw;
mesh.getGEntityPositions(xyz,uvw);
mesh.updateGEntityPositions();
//could be better (e.g. store the model in the Mesh:: datastrucure)
GModel *gm = GModel::current();
// for all model edges, compute the error between the geometry and the mesh
maxDistCAD = 0.0;
double distCAD = 0.0;
for (GModel::eiter it = gm->firstEdge(); it != gm->lastEdge(); ++it){
// do not do straight lines
if ((*it)->geomType() == GEntity::Line)continue;
// look at all mesh lines
std::vector<bool> doWeCompute((*it)->lines.size());
for (unsigned int i=0;i<(*it)->lines.size(); i++){
doWeCompute[i] = false;
for (unsigned int j=0;j<(*it)->lines[i]->getNumVertices(); j++){
int index = mesh.getFreeVertexStartIndex((*it)->lines[i]->getVertex(j));
if (index >=0){
doWeCompute[i] = true;
continue;
}
}
}
std::vector<double> dist((*it)->lines.size());
for (unsigned int i=0;i<(*it)->lines.size(); i++){
if (doWeCompute[i]){
// compute the distance from the geometry to the mesh
dist[i] = MLineGEdgeDistance ( (*it)->lines[i] , *it );
maxDistCAD = std::max(maxDistCAD,dist[i]);
distCAD += dist [i] * factor;
}
}
// be clever to compute the derivative : iterate on all
// Distance = \sum_{lines} Distance (line, GEdge)
// For a high order vertex, we compute the derivative only by
// recomputing the distance to one only line
const double eps = 1.e-6;
for (unsigned int i=0;i<(*it)->lines.size(); i++){
if (doWeCompute[i]){
for (int j=2 ; j<(*it)->lines[i]->getNumVertices() ; j++){
MVertex *v = (*it)->lines[i]->getVertex(j);
int index = mesh.getFreeVertexStartIndex(v);
// printf("%d %d (%d %d)\n",v->getNum(),index,v->onWhat()->tag(),v->onWhat()->dim());
if (index >= 0){
double t;
v->getParameter(0,t);
SPoint3 pp (v->x(),v->y(),v->z());
GPoint gp = (*it)->point(t+eps);
v->setParameter(0,t+eps);
v->setXYZ(gp.x(),gp.y(),gp.z());
double dist2 = MLineGEdgeDistance ( (*it)->lines[i] , *it );
double deriv = (dist2 - dist[i])/eps;
v->setXYZ(pp.x(),pp.y(),pp.z());
v->setParameter(0,t);
// printf("%g %g %g\n",dist[i],dist2, MLineGEdgeDistance ( (*it)->lines[i] , *it ));
// get the index of the vertex
gradObj[index] += deriv * factor;
}
}
}
// printf("done\n");
// For a low order vertex classified on the GEdge, we recompute
// two distances for the two MLines connected to the vertex
for (unsigned int i=0;i<(*it)->lines.size()-1; i++){
MVertex *v = (*it)->lines[i]->getVertex(1);
int index = mesh.getFreeVertexStartIndex(v);
if (index >= 0){
double t;
v->getParameter(0,t);
SPoint3 pp (v->x(),v->y(),v->z());
GPoint gp = (*it)->point(t+eps);
v->setParameter(0,t+eps);
v->setXYZ(gp.x(),gp.y(),gp.z());
MLine *l1 = (*it)->lines[i];
MLine *l2 = (*it)->lines[i+1];
// printf("%d %d -- %d %d\n",l1->getVertex(0)->getNum(),l1->getVertex(1)->getNum(),l2->getVertex(0)->getNum(),l2->getVertex(1)->getNum());
double deriv =
(MLineGEdgeDistance ( l1 , *it ) - dist[i]) /eps +
(MLineGEdgeDistance ( l2 , *it ) - dist[i+1])/eps;
v->setXYZ(pp.x(),pp.y(),pp.z());
v->setParameter(0,t);
gradObj[index] += deriv * factor;
}
}
}
}
// printf("computing distance : 1D part %12.5E\n",distCAD);
// now the 3D part !
std::vector<std::vector<SVector3> > gsfT;
computeGradSFAtNodes ( (*gm->firstFace())->triangles[0],gsfT);
std::map<MVertex*,SVector3> normalsToCAD;
for(GModel::fiter it = gm->firstFace(); it != gm->lastFace(); ++it){
// do not do plane surfaces
if ((*it)->geomType() == GEntity::Plane)continue;
std::map<MTriangle*,double> dist;
std::vector<bool> doWeCompute((*it)->triangles.size());
for (unsigned int i=0;i<(*it)->triangles.size(); i++){
doWeCompute[i] = false;
for (unsigned int j=0;j<(*it)->triangles[i]->getNumVertices(); j++){
int index = mesh.getFreeVertexStartIndex((*it)->triangles[i]->getVertex(j));
if (index >=0){
doWeCompute[i] = true;
}
}
if (doWeCompute[i]){
for (unsigned int j=0;j<(*it)->triangles[i]->getNumVertices(); j++){
MVertex *v = (*it)->triangles[i]->getVertex(j);
if (normalsToCAD.find(v) == normalsToCAD.end()){
SPoint2 p_cad;
reparamMeshVertexOnFace(v, *it, p_cad);
SVector3 tg_cad = (*it)->normal(p_cad);
tg_cad.normalize();
normalsToCAD[v] = tg_cad;
}
}
}
}
for (unsigned int i=0;i<(*it)->triangles.size(); i++){
// compute the distance from the geometry to the mesh
if(doWeCompute[i]){
const double d = MFaceGFaceDistanceOld((*it)->triangles[i], *it, &gsfT, &normalsToCAD);
dist[(*it)->triangles[i]] = d;
maxDistCAD = std::max(maxDistCAD,d);
distCAD += d * factor;
}
}
// be clever again to compute the derivatives
const double eps = 1.e-6;
for (unsigned int i=0;i<(*it)->triangles.size(); i++){
if(doWeCompute[i]){
for (unsigned int j=0;j<(*it)->triangles[i]->getNumVertices(); j++){
// for (; itm !=v2t.end(); ++itm){
MVertex *v = (*it)->triangles[i]->getVertex(j);
if(v->onWhat()->dim() == 1){
int index = mesh.getFreeVertexStartIndex(v);
if (index >= 0){
MTriangle *t = (*it)->triangles[i];
GEdge *ge = v->onWhat()->cast2Edge();
double t_;
v->getParameter(0,t_);
SPoint3 pp (v->x(),v->y(),v->z());
GPoint gp = ge->point(t_+eps);
v->setParameter(0,t_+eps);
v->setXYZ(gp.x(),gp.y(),gp.z());
const double distT = dist[t];
double deriv = (MFaceGFaceDistanceOld(t, *it, &gsfT, &normalsToCAD) - distT) /eps;
v->setXYZ(pp.x(),pp.y(),pp.z());
v->setParameter(0,t_);
gradObj[index] += deriv * factor;
}
}
if(v->onWhat() == *it){
int index = mesh.getFreeVertexStartIndex(v);
if (index >= 0){
MTriangle *t = (*it)->triangles[i];
double uu,vv;
v->getParameter(0,uu);
v->getParameter(1,vv);
SPoint3 pp (v->x(),v->y(),v->z());
const double distT = dist[t];
GPoint gp = (*it)->point(uu+eps,vv);
v->setParameter(0,uu+eps);
v->setXYZ(gp.x(),gp.y(),gp.z());
double deriv = (MFaceGFaceDistanceOld(t, *it, &gsfT, &normalsToCAD) - distT) /eps;
v->setXYZ(pp.x(),pp.y(),pp.z());
v->setParameter(0,uu);
gradObj[index] += deriv * factor;
gp = (*it)->point(uu,vv+eps);
v->setParameter(1,vv+eps);
v->setXYZ(gp.x(),gp.y(),gp.z());
deriv = (MFaceGFaceDistanceOld(t, *it, &gsfT, &normalsToCAD) - distT) /eps;
v->setXYZ(pp.x(),pp.y(),pp.z());
v->setParameter(1,vv);
gradObj[index+1] += deriv * factor;
}
}
}
}
}
}
mesh.updateGEntityPositions(xyz,uvw);
Obj +=distCAD;
// printf("computing distance : 2D part %12.5E\n",distCAD);
// printf("%22.15E\n",distCAD);
return true;
}
gmshFace::gmshFace(GModel *m, Surface *face)
: GFace(m, face->Num), s(face), isSphere(false), radius(0.)
{
resetMeshAttributes();
// edgeCounterparts = s->edgeCounterparts;
// affineTransform = s->affineTransform;
std::vector<GEdge*> eds;
std::vector<int> nums;
for(int i = 0; i < List_Nbr(s->Generatrices); i++){
Curve *c;
List_Read(s->Generatrices, i, &c);
GEdge *e = m->getEdgeByTag(abs(c->Num));
if(e){
eds.push_back(e);
nums.push_back(c->Num);
}
else
Msg::Error("Unknown curve %d", c->Num);
}
for(int i = 0; i < List_Nbr(s->GeneratricesByTag); i++){
int j;
List_Read(s->GeneratricesByTag, i, &j);
GEdge *e = m->getEdgeByTag(abs(j));
if(e){
eds.push_back(e);
nums.push_back(j);
}
else
Msg::Error("Unknown curve %d", j);
}
std::list<GEdge*> l_wire;
GVertex *first = 0;
for(unsigned int i = 0; i < eds.size(); i++){
GEdge *e = eds[i];
int num = nums[i];
GVertex *start = (num > 0) ? e->getBeginVertex() : e->getEndVertex();
GVertex *next = (num > 0) ? e->getEndVertex() : e->getBeginVertex();
if (!first) first = start;
l_wire.push_back(e);
if (next == first){
edgeLoops.push_back(GEdgeLoop(l_wire));
l_wire.clear();
first = 0;
}
l_edges.push_back(e);
e->addFace(this);
l_dirs.push_back((num > 0) ? 1 : -1);
if (List_Nbr(s->Generatrices) == 2){
e->meshAttributes.minimumMeshSegments =
std::max(e->meshAttributes.minimumMeshSegments, 2);
}
}
// always compute and store the mean plane for plane surfaces (using
// the bounding vertices)
if(s->Typ == MSH_SURF_PLAN) computeMeanPlane();
if(s->EmbeddedCurves){
for(int i = 0; i < List_Nbr(s->EmbeddedCurves); i++){
Curve *c;
List_Read(s->EmbeddedCurves, i, &c);
GEdge *e = m->getEdgeByTag(abs(c->Num));
if(e)
addEmbeddedEdge(e);
else
Msg::Error("Unknown curve %d", c->Num);
}
}
if(s->EmbeddedPoints){
for(int i = 0; i < List_Nbr(s->EmbeddedPoints); i++){
Vertex *v;
List_Read(s->EmbeddedPoints, i, &v);
GVertex *gv = m->getVertexByTag(v->Num);
if(gv)
embedded_vertices.push_back(gv);
else
Msg::Error("Unknown point %d", v->Num);
}
}
isSphere = iSRuledSurfaceASphere(s, center, radius);
}
void MyCanvas::shadeDevicePolygon(std::vector<GEdge>& Edges, GShader* shader)
{
assert(shader != nullptr);
if (Edges.size() < 2)
{
//printf("Error: ShadeDevicePolygon needs at least 2 edges to draw\n");
return;
}
// Sort the edges from top to bottom, left to right
std::sort(Edges.begin(), Edges.end());
// The first two edges will be the top most edges
GEdge LeftEdge = Edges[0];
GEdge RightEdge = Edges[1];
// Get start of pixel address for bitmap and offset to the top row
GPixel *DstPixels = (GPixel*)((char*)Bitmap.pixels() + Bitmap.fRowBytes * LeftEdge.top());
// Set the context in the shader to the CTM
float TwoRows[6];
CTM.GetTwoRows(TwoRows);
shader->setContext(TwoRows);
int EdgeCounter = 2;
for (int y = LeftEdge.top(); y < Edges.back().bottom(); ++y)
{
int startX = Utility::round(LeftEdge.currentX());
int count = (int)(RightEdge.currentX() - LeftEdge.currentX());
count = Utility::clamp(1, count, BmpRect.width() - 1);
/* Allocate a row of pixels to calculate shader pixel values
* then blend shader pixels into the dst bitmap */
GPixel *row = new GPixel[count];
shader->shadeRow(startX, y, count, row);
blendRow(DstPixels, startX, row, count);
delete[] row;
// Move currentX of the left and right edges to the next row
LeftEdge.moveCurrentX(1.0f);
RightEdge.moveCurrentX(1.0f);
// Check left and right edge for y has passed bottom, if we have edges left then set the next edge
if (y >= LeftEdge.bottom() && EdgeCounter < Edges.size())
{
LeftEdge = Edges[EdgeCounter];
++EdgeCounter;
}
if (y >= RightEdge.bottom() && EdgeCounter < Edges.size())
{
RightEdge = Edges[EdgeCounter];
++EdgeCounter;
}
DstPixels = (GPixel*)((char*)DstPixels + Bitmap.fRowBytes);
}
}
int GModel::importGEOInternals()
{
if(Tree_Nbr(_geo_internals->Points)) {
List_T *points = Tree2List(_geo_internals->Points);
for(int i = 0; i < List_Nbr(points); i++){
Vertex *p;
List_Read(points, i, &p);
GVertex *v = getVertexByTag(p->Num);
if(!v){
v = new gmshVertex(this, p);
add(v);
}
if(!p->Visible) v->setVisibility(0);
}
List_Delete(points);
}
if(Tree_Nbr(_geo_internals->Curves)) {
List_T *curves = Tree2List(_geo_internals->Curves);
for(int i = 0; i < List_Nbr(curves); i++){
Curve *c;
List_Read(curves, i, &c);
if(c->Num >= 0){
GEdge *e = getEdgeByTag(c->Num);
if(!e && c->Typ == MSH_SEGM_COMPOUND){
std::vector<GEdge*> comp;
for(unsigned int j = 0; j < c->compound.size(); j++){
GEdge *ge = getEdgeByTag(c->compound[j]);
if(ge) comp.push_back(ge);
}
e = new GEdgeCompound(this, c->Num, comp);
e->meshAttributes.method = c->Method;
e->meshAttributes.nbPointsTransfinite = c->nbPointsTransfinite;
e->meshAttributes.typeTransfinite = c->typeTransfinite;
e->meshAttributes.coeffTransfinite = c->coeffTransfinite;
e->meshAttributes.extrude = c->Extrude;
e->meshAttributes.reverseMesh = c->ReverseMesh;
add(e);
}
else if(!e && c->beg && c->end){
e = new gmshEdge(this, c,
getVertexByTag(c->beg->Num),
getVertexByTag(c->end->Num));
add(e);
}
else if(!e){
e = new gmshEdge(this, c, 0, 0);
add(e);
}
if(!c->Visible) e->setVisibility(0);
if(c->Color.type) e->setColor(c->Color.mesh);
if(c->degenerated) {
e->setTooSmall(true);
}
}
}
List_Delete(curves);
}
if(Tree_Nbr(_geo_internals->Surfaces)) {
List_T *surfaces = Tree2List(_geo_internals->Surfaces);
for(int i = 0; i < List_Nbr(surfaces); i++){
Surface *s;
List_Read(surfaces, i, &s);
GFace *f = getFaceByTag(s->Num);
if(!f && s->Typ == MSH_SURF_COMPOUND){
std::list<GFace*> comp;
for(unsigned int j = 0; j < s->compound.size(); j++){
GFace *gf = getFaceByTag(s->compound[j]);
if(gf)
comp.push_back(gf);
}
std::list<GEdge*> b[4];
for(int j = 0; j < 4; j++){
for(unsigned int k = 0; k < s->compoundBoundary[j].size(); k++){
GEdge *ge = getEdgeByTag(s->compoundBoundary[j][k]);
if(ge) b[j].push_back(ge);
}
}
int param = CTX::instance()->mesh.remeshParam;
GFaceCompound::typeOfCompound typ = GFaceCompound::HARMONIC_CIRCLE;
if (param == 1) typ = GFaceCompound::CONFORMAL_SPECTRAL;
if (param == 2) typ = GFaceCompound::RADIAL_BASIS;
if (param == 3) typ = GFaceCompound::HARMONIC_PLANE;
if (param == 4) typ = GFaceCompound::CONVEX_CIRCLE;
if (param == 5) typ = GFaceCompound::CONVEX_PLANE;
if (param == 6) typ = GFaceCompound::HARMONIC_SQUARE;
if (param == 7) typ = GFaceCompound::CONFORMAL_FE;
int algo = CTX::instance()->mesh.remeshAlgo;
f = new GFaceCompound(this, s->Num, comp, b[0], b[1], b[2], b[3], typ, algo);
f->meshAttributes.recombine = s->Recombine;
f->meshAttributes.recombineAngle = s->RecombineAngle;
f->meshAttributes.method = s->Method;
f->meshAttributes.extrude = s->Extrude;
// transfinite import Added by Trevor Strickler. This helps when experimenting
// to create compounds from transfinite surfs. Not having it does not break
// anything Gmsh *officially* does right now, but maybe it was left out by mistake??? and could
// cause problems later?
f->meshAttributes.transfiniteArrangement = s->Recombine_Dir;
f->meshAttributes.corners.clear();
for(int i = 0; i < List_Nbr(s->TrsfPoints); i++){
Vertex *corn;
List_Read(s->TrsfPoints, i, &corn);
GVertex *gv = f->model()->getVertexByTag(corn->Num);
if(gv)
f->meshAttributes.corners.push_back(gv);
else
Msg::Error("Unknown vertex %d in transfinite attributes", corn->Num);
}
add(f);
if(s->EmbeddedCurves){
for(int i = 0; i < List_Nbr(s->EmbeddedCurves); i++){
Curve *c;
List_Read(s->EmbeddedCurves, i, &c);
GEdge *e = getEdgeByTag(abs(c->Num));
if(e)
f->addEmbeddedEdge(e);
else
Msg::Error("Unknown curve %d", c->Num);
}
}
if(s->EmbeddedPoints){
for(int i = 0; i < List_Nbr(s->EmbeddedPoints); i++){
Vertex *v;
List_Read(s->EmbeddedPoints, i, &v);
GVertex *gv = getVertexByTag(v->Num);
if(gv)
f->addEmbeddedVertex(gv);
else
Msg::Error("Unknown point %d", v->Num);
}
}
}
else if(!f){
f = new gmshFace(this, s);
add(f);
}
else
f->resetMeshAttributes();
if(!s->Visible) f->setVisibility(0);
if(s->Color.type) f->setColor(s->Color.mesh);
}
List_Delete(surfaces);
}
if(Tree_Nbr(_geo_internals->Volumes)) {
List_T *volumes = Tree2List(_geo_internals->Volumes);
for(int i = 0; i < List_Nbr(volumes); i++){
Volume *v;
List_Read(volumes, i, &v);
GRegion *r = getRegionByTag(v->Num);
if(!r && v->Typ == MSH_VOLUME_COMPOUND){
std::vector<GRegion*> comp;
for(unsigned int j = 0; j < v->compound.size(); j++){
GRegion *gr = getRegionByTag(v->compound[j]);
if(gr) comp.push_back(gr);
}
r = new GRegionCompound(this, v->Num, comp);
if(v->EmbeddedSurfaces){
for(int i = 0; i < List_Nbr(v->EmbeddedSurfaces); i++){
Surface *s;
List_Read(v->EmbeddedSurfaces, i, &s);
GFace *gf = getFaceByTag(abs(s->Num));
if(gf)
r->addEmbeddedFace(gf);
else
Msg::Error("Unknown surface %d", s->Num);
}
}
add(r);
}
else if(!r){
r = new gmshRegion(this, v);
add(r);
}
else
r->resetMeshAttributes();
if(!v->Visible) r->setVisibility(0);
if(v->Color.type) r->setColor(v->Color.mesh);
}
List_Delete(volumes);
}
for(int i = 0; i < List_Nbr(_geo_internals->PhysicalGroups); i++){
PhysicalGroup *p;
List_Read(_geo_internals->PhysicalGroups, i, &p);
for(int j = 0; j < List_Nbr(p->Entities); j++){
int num;
List_Read(p->Entities, j, &num);
GEntity *ge = 0;
int tag = CTX::instance()->geom.orientedPhysicals ? abs(num) : num;
switch(p->Typ){
case MSH_PHYSICAL_POINT: ge = getVertexByTag(tag); break;
case MSH_PHYSICAL_LINE: ge = getEdgeByTag(tag); break;
case MSH_PHYSICAL_SURFACE: ge = getFaceByTag(tag); break;
case MSH_PHYSICAL_VOLUME: ge = getRegionByTag(tag); break;
}
int pnum = CTX::instance()->geom.orientedPhysicals ? (sign(num) * p->Num) : p->Num;
if(ge && std::find(ge->physicals.begin(), ge->physicals.end(), pnum) ==
ge->physicals.end())
ge->physicals.push_back(pnum);
}
}
// create periodic mesh relationships
for (std::map<int,int>::iterator it = _geo_internals->periodicEdges.begin();
it != _geo_internals->periodicEdges.end(); ++it){
GEdge *ge = getEdgeByTag(abs(it->first));
if (ge){
int MASTER = it->second * (it->first > 0 ? 1 : -1);
ge->setMeshMaster(MASTER);
}
}
for (std::map<int,int>::iterator it = _geo_internals->periodicFaces.begin();
it != _geo_internals->periodicFaces.end(); ++it){
GFace *gf = getFaceByTag(abs(it->first));
if (gf)gf->setMeshMaster(it->second * (it->first > 0 ? 1 : -1));
}
for (eiter it = firstEdge() ; it != lastEdge() ; ++it){
int meshMaster = (*it)->meshMaster();
if (meshMaster != (*it)->tag()){
GEdge *ge_master = getEdgeByTag(abs(meshMaster));
if(ge_master)(*it)->getBeginVertex()->setMeshMaster ( (meshMaster > 0) ? ge_master->getBeginVertex()->tag() : ge_master->getEndVertex()->tag());
if(ge_master)(*it)->getEndVertex()->setMeshMaster ( (meshMaster < 0) ? ge_master->getBeginVertex()->tag() : ge_master->getEndVertex()->tag());
}
}
Msg::Debug("Gmsh model (GModel) imported:");
Msg::Debug("%d Vertices", vertices.size());
Msg::Debug("%d Edges", edges.size());
Msg::Debug("%d Faces", faces.size());
Msg::Debug("%d Regions", regions.size());
return 1;
}
GEdge *GNode< Point >::Del( Long n, Long i ) {
GEdge *p = Neighbours();
GEdge *q;
if (!p) return NULL;
if ((p->Node()==n)&&(p->Item()==i)) {
q=p->Next();
etrash.push_back(p);
// delete(p); // Problem when using Neighbours() list: cannot delete
adjacents=q;
} else {
for (q=p->Next();q != NULL; p=q,q=q->Next())
if (q && (q->Node() ==n) && (q->Item() == i)) {
p->Next(q->Next());
etrash.push_back(q);
break;
// delete(q); // Problem when using Neighbours() list: cannot delete
}
}
return adjacents;
}
/*
* Merges 2 nodes in 1 ->n1
* Updates the adjacent list of all node (n2 ->n1).
* and delete n2.
*/
Errc Graph3d::Merge( Long n1, Long n2 ) {
GEdge *ptr;
if (_directed) {
if ((n1==n2) || (!tnode[n1]) || (!tnode[n2])) return FAILURE;
// Remove links
Unlink(n1,n2);
Unlink(n2,n1);
while((ptr=tnode[n2]->Neighbours())){
if ( n2 != ptr->Node() )
Link(n1,ptr->Node(),ptr->Item(),ptr->weight,true);
else
Link(n1,n1,ptr->Item(),ptr->weight,true);
Unlink(n2,ptr->Node(),ptr->Item());
}
// Cross the graph in order to replace n2 by n1
for ( int i = 0; i < this->Size(); ++i ) {
const GNode<Point3d> * noeud = (*this)[i];
if ( noeud != NULL ) {
for ( ptr = noeud->Neighbours() ; ptr != NULL; ptr = ptr->Next() )
if ( ptr->Node() == n2 ) {
Link(i,n1,ptr->Item(),ptr->weight,true);
Unlink(i,n2,ptr->Item());
}
}
}
Del(n2);
} else {
if ((n1==n2) || (!tnode[n1]) || (!tnode[n2])) return FAILURE;
Unlink(n1,n2);
while((ptr=tnode[n2]->Neighbours())){
if ( n2 != ptr->Node() )
Link(n1,ptr->Node(),ptr->Item(),ptr->weight,true);
else
Link(n1,n1,ptr->Item(),ptr->weight,true);
Unlink(n2,ptr->Node(),ptr->Item());
}
Del(n2);
}
return SUCCESS;
}
void GEdgeCompound::orderEdges()
{
std::vector<GEdge*> _c ;
std::list<GEdge*> edges ;
for (unsigned int i = 0; i < _compound.size(); i++){
edges.push_back(_compound[i]);
}
// find a lonely edge
std::map<GVertex*, GEdge*> tempv;
for (std::list<GEdge*>::iterator it = edges.begin() ; it != edges.end() ; ++it){
GVertex *v1 = (*it)->getBeginVertex();
GVertex *v2 = (*it)->getEndVertex();
if(!v1 || !v2){
Msg::Error("Compounds don't support curves without two bounding vertices");
return;
}
std::map<GVertex*, GEdge*>::iterator it1 = tempv.find(v1);
if (it1 == tempv.end()) {
tempv.insert(std::make_pair(v1, *it));
}
else tempv.erase(it1);
std::map<GVertex*, GEdge*>::iterator it2 = tempv.find(v2);
if (it2 == tempv.end()){
tempv.insert(std::make_pair(v2, *it));
}
else tempv.erase(it2);
}
// find the first GEdge and erase it from the list edges
GEdge *firstEdge;
if (tempv.size() == 2){ // non periodic
firstEdge = (tempv.begin())->second;
for (std::list<GEdge*>::iterator it = edges.begin() ; it != edges.end() ; ++it){
if (*it == firstEdge){
edges.erase(it);
break;
}
}
}
else if (tempv.size() == 0){ // periodic
firstEdge = *(edges.begin());
edges.erase(edges.begin());
}
else{
Msg::Error("EdgeCompound %d is wrong (it has %d end points)", tag(), tempv.size());
return;
}
// loop over all segments to order segments and store it in the list _c
_c.push_back(firstEdge);
_orientation.push_back(1);
GVertex *first = _c[0]->getBeginVertex();
GVertex *last = _c[0]->getEndVertex();
while (first != last){
if (edges.empty())break;
bool found = false;
for (std::list<GEdge*>::iterator it = edges.begin() ; it != edges.end() ; ++it){
GEdge *e = *it;
std::list<GEdge*>::iterator itp;
if (e->getBeginVertex() == last){
_c.push_back(e);
itp = it;
it++;
edges.erase(itp);
_orientation.push_back(1);
last = e->getEndVertex();
found = true;
break;
}
else if (e->getEndVertex() == last){
_c.push_back(e);
itp = it;
it++;
edges.erase(itp);
_orientation.push_back(0);
last = e->getBeginVertex();
found = true;
break;
}
}
if (!found){
if (_c.size() == 1 && _orientation[0]){
GVertex *temp = first;
first = last;
last = temp;
_orientation[0] = 0;
}
else {
Msg::Error("Compound Edge %d is wrong", tag());
return;
}
}
}
//edges is now a list of ordered GEdges
_compound = _c;
// special case reverse orientation
if (_compound.size() < 2) return;
if (_orientation[0] && _compound[0]->getEndVertex() != _compound[1]->getEndVertex()
&& _compound[0]->getEndVertex() != _compound[1]->getBeginVertex()){
for (unsigned int i = 0; i < _compound.size(); i++){
_orientation[i] = !_orientation[i] ;
}
}
}
void WalkEdges(const GEdge e1, const GEdge e2, const GPaint &paint) {
const GBitmap &bm = GetInternalBitmap();
int h = bm.fHeight;
int w = bm.fWidth;
GASSERT(e1.p1.y() == e2.p1.y());
int startY = Clamp(static_cast<int>(e1.p1.y() + 0.5f), 0, h-1);
GASSERT(e1.p2.y() == e2.p2.y());
int endY = Clamp(static_cast<int>(e1.p2.y() + 0.5f), 0, h-1);
if(endY == startY) {
return;
}
GASSERT(endY > startY);
// Initialize to NAN
float m1 = 0.0f/0.0f, b1;
float m2 = 0.0f/0.0f, b2;
bool vert1 = e1.ComputeLine(m1, b1);
bool vert2 = e2.ComputeLine(m2, b2);
if(m1 == 0 || m2 == 0) {
return;
}
// Collinear?
if(vert2 && vert1 && e1.p1.x() == e2.p1.x()) {
return;
} else if(m1 == m2 && b1 == b2) {
return;
}
float stepX1 = vert1? 0 : 1/m1;
float stepX2 = vert2? 0 : 1/m2;
GPoint p1, p2;
float sY = static_cast<float>(startY) + 0.5f;
if(vert1) {
p1.set(e1.p1.x(), sY);
} else {
p1.set((sY - b1) / m1, sY);
}
if(vert2) {
p2.set(e2.p1.x(), sY);
} else {
p2.set((sY - b2) / m2, sY);
}
// Make sure that p1 is always less than p2 to avoid
// doing a min/max in the inner loop
if(p1.x() > p2.x()) {
std::swap(p1, p2);
std::swap(stepX1, stepX2);
}
GPixel color = ColorToPixel(paint.getColor());
BlendFunc blend = GetBlendFunc(eBlendOp_SrcOver);
uint32_t nSteps = endY - startY;
for(uint32_t i = 0; i < nSteps; i++) {
// Since we haven't implemented clipping yet, take care
// not to go beyond our bounds...
const int x1 = Clamp<int>(p1.fX + 0.5f, 0, w-1);
const int x2 = Clamp<int>(p2.fX + 0.5f, 0, w-1);
GPixel *row = GetRow(bm, startY + i);
for(int x = x1; x < x2; x++) {
row[x] = blend(row[x], color);
}
p1.fX += stepX1;
p2.fX += stepX2;
}
}
void
EdgeItem::keyPressEvent(QKeyEvent *event)
{
int key = event->key();
GNode *n = NULL;
GEdge *e = NULL;
VEdge vedge( edge());
NavSector sector = edge()->graph()->nodeNavigationSector();
GNode *curr_node = edge()->graph()->nodeInFocus();
NodeNav node_nav( curr_node, sector);
switch( key)
{
case Qt::Key_Up:
if ( isNotNullP( curr_node)
&& ( sector == LEFT_SECTOR || sector == RIGHT_SECTOR))
{
e = node_nav.edgeInDir( edge(), NAV_DIR_UP);
} else
{
n = vedge.nodeUp();
}
break;
case Qt::Key_Down:
if ( isNotNullP( curr_node)
&& ( sector == LEFT_SECTOR || sector == RIGHT_SECTOR) )
{
e = node_nav.edgeInDir( edge(), NAV_DIR_DOWN);
} else
{
n = vedge.nodeDown();
}
break;
case Qt::Key_Left:
if ( isNotNullP( curr_node)
&& ( sector == TOP_SECTOR || sector == BOTTOM_SECTOR) )
{
e = node_nav.edgeInDir( edge(), NAV_DIR_LEFT);
} else
{
n = vedge.nodeLeft();
}
break;
case Qt::Key_Right:
if ( isNotNullP( curr_node)
&& ( sector == TOP_SECTOR || sector == BOTTOM_SECTOR) )
{
e = node_nav.edgeInDir( edge(), NAV_DIR_RIGHT);
} else
{
n = vedge.nodeRight();
}
break;
default:
break;
}
if ( isNotNullP( n))
{
if ( edge()->graph()->view()->isContext())
{
edge()->graph()->emptySelection();
edge()->graph()->selectNode( n);
edge()->graph()->view()->findContext();
}
edge()->graph()->view()->focusOnNode( n, true);
scene()->clearFocus();
scene()->clearSelection();
n->item()->setFocus();
n->item()->setSelected( true);
} else if ( isNotNullP( e))
{
// Get focus on edge
scene()->clearFocus();
scene()->clearSelection();
e->item()->setFocus();
e->item()->setSelected( true);
}
//QGraphicsItem::keyPressEvent( event);
}
GEdge *GNode< Point >::Search( Long n ) const {
GEdge *p;
for (p=adjacents; p && (p->Node()!=n); p=p->Next()) ;
return p;
}
