#include #include #include // #include #ifdef STLGEOM #include #endif // #include #include namespace netgen { // extern shared_ptr mesh; extern NetgenGeometry * ng_geometry; VisualSceneMesh vsmesh; VisualSceneMesh :: VisualSceneMesh () : VisualScene() { filledlist = 0; linelist = 0; edgelist = 0; badellist = 0; tetlist = 0; prismlist = 0; hexlist = 0; pyramidlist = 0; identifiedlist = 0; pointnumberlist = 0; domainsurflist = 0; vstimestamp = -1; // GetTimeStamp(); selecttimestamp = -1; // GetTimeStamp(); filledtimestamp = -1; // GetTimeStamp(); linetimestamp = -1; // GetTimeStamp(); edgetimestamp = -1; // GetTimeStamp(); pointnumbertimestamp = -1; // GetTimeStamp(); tettimestamp = -1; // GetTimeStamp(); prismtimestamp = -1; // GetTimeStamp(); hextimestamp = -1; // GetTimeStamp(); pyramidtimestamp = -1; // GetTimeStamp(); badeltimestamp = -1; // GetTimeStamp(); identifiedtimestamp = -1; // GetTimeStamp(); domainsurftimestamp = -1; // GetTimeStamp(); selface = -1; selelement = -1; locpi = 1; selpoint = -1; selpoint2 = -1; seledge = -1; minh = 0.0; maxh = 0.0; user_me_handler = NULL; } VisualSceneMesh :: ~VisualSceneMesh () { ; } void VisualSceneMesh :: DrawScene () { try { shared_ptr mesh = GetMesh(); if (!mesh) { VisualScene::DrawScene(); return; } lock = NULL; static int timer = NgProfiler::CreateTimer ("VSMesh::DrawScene"); NgProfiler::RegionTimer reg (timer); BuildScene(); glEnable(GL_DEPTH_TEST); glClearColor(backcolor, backcolor, backcolor, 1.0); glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT); glEnable (GL_COLOR_MATERIAL); glColor3f (1.0f, 1.0f, 1.0f); glLineWidth (1.0f); SetLight(); glPushMatrix(); glMultMatrixd (transformationmat); GLdouble projmat[16]; // brauchen wir das ? glGetDoublev (GL_PROJECTION_MATRIX, projmat); #ifdef PARALLEL glEnable (GL_BLEND); glBlendFunc (GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA); #endif glInitNames (); glPushName (0); // glEnable (GL_LINE_SMOOTH); // glEnable (GL_BLEND); // glEnable (GL_POLYGON_SMOOTH); // glDisable (GL_DEPTH_TEST); // glBlendFunc (GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA); // glHint (GL_LINE_SMOOTH_HINT, GL_DONT_CARE); glDisable (GL_COLOR_MATERIAL); GLfloat matcol0[] = { 0, 0, 0, 1 }; GLfloat matcol1[] = { 1, 1, 1, 1 }; GLfloat matcolf[] = { 0, 1, 0, 1 }; GLfloat matcolb[] = { 0.5, 0, 0, 1 }; // GLfloat matcolblue[] = { 0, 0, 1, 1 }; glMatrixMode (GL_MODELVIEW); glMaterialfv(GL_FRONT, GL_EMISSION, matcol0); glMaterialfv(GL_BACK, GL_EMISSION, matcol0); glMaterialfv(GL_FRONT_AND_BACK, GL_SPECULAR, matcol1); glMaterialfv(GL_FRONT, GL_AMBIENT_AND_DIFFUSE, matcolf); glMaterialfv(GL_BACK, GL_AMBIENT_AND_DIFFUSE, matcolb); glPolygonMode (GL_FRONT_AND_BACK, GL_FILL); // glPolygonOffset (1,10); glPolygonOffset (2,2); glEnable (GL_POLYGON_OFFSET_FILL); SetClippingPlane (); if (vispar.drawfilledtrigs) { if (filledtimestamp < mesh->GetTimeStamp () || filledtimestamp < selecttimestamp) { BuildFilledList (false); } #ifdef PARALLELGL if (ntasks > 1 && vispar.drawtetsdomain > 0 && vispar.drawtetsdomain < ntasks) glCallList (par_filledlists[vispar.drawtetsdomain]); else #endif glCallList (filledlist); } if (vispar.drawbadels) glCallList (badellist); if (vispar.drawprisms) { BuildPrismList (); glCallList (prismlist); } if (vispar.drawpyramids) { BuildPyramidList (); glCallList (pyramidlist); } if (vispar.drawhexes) { BuildHexList (); glCallList (hexlist); } if (vispar.drawtets) { BuildTetList (); glCallList (tetlist); } if (vispar.drawdomainsurf) { BuildDomainSurfList(); glCallList (domainsurflist); } glDisable (GL_POLYGON_OFFSET_FILL); // draw lines glMatrixMode (GL_MODELVIEW); glMaterialfv(GL_FRONT_AND_BACK, GL_AMBIENT_AND_DIFFUSE, matcol0); glMaterialfv(GL_FRONT_AND_BACK, GL_EMISSION, matcol0); glMaterialfv(GL_FRONT_AND_BACK, GL_SPECULAR, matcol0); glPolygonMode (GL_FRONT_AND_BACK, GL_LINE); glLineWidth (1.0f); glColor3f (0.0f, 0.0f, 0.0f); glDisable (GL_LINE_SMOOTH); if (vispar.drawoutline) { glPolygonOffset (1, 1); glEnable (GL_POLYGON_OFFSET_LINE); if (linetimestamp < mesh->GetTimeStamp ()) BuildLineList (); #ifdef PARALLELGL if (ntasks > 1 && vispar.drawtetsdomain > 0 && vispar.drawtetsdomain < ntasks) glCallList (par_linelists[vispar.drawtetsdomain]); else #endif glCallList (linelist); glDisable (GL_POLYGON_OFFSET_LINE); } if (vispar.drawidentified) { glPolygonOffset (1, -1); glEnable (GL_POLYGON_OFFSET_LINE); glCallList (identifiedlist); glDisable (GL_POLYGON_OFFSET_LINE); } if (vispar.drawpointnumbers || vispar.drawedgenumbers || vispar.drawfacenumbers || vispar.drawelementnumbers) glCallList (pointnumberlist); glPopName(); if (vispar.drawedges) { BuildEdgeList(); glCallList (edgelist); } if (selpoint > 0 && selpoint <= mesh->GetNP()) { /* glPointSize (3.0); glColor3d (0, 0, 1); glMaterialfv (GL_FRONT_AND_BACK, GL_AMBIENT_AND_DIFFUSE, matcolblue); glBegin (GL_POINTS); const Point3d p = mesh->Point(selpoint); glVertex3f (p.X(), p.Y(), p.Z()); glEnd(); */ glColor3d (0, 0, 1); static GLubyte cross[] = { 0xc6, 0xee, 0x7c, 0x38, 0x7c, 0xee, 0xc6 }; glPixelStorei(GL_UNPACK_ALIGNMENT, 1); glDisable (GL_COLOR_MATERIAL); glDisable (GL_LIGHTING); glDisable (GL_CLIP_PLANE0); const Point3d p = mesh->Point(selpoint); glRasterPos3d (p.X(), p.Y(), p.Z()); glBitmap (7, 7, 3, 3, 0, 0, &cross[0]); } glDisable(GL_CLIP_PLANE0); glPopMatrix(); if (vispar.colormeshsize) DrawColorBar (minh, maxh, 1); DrawCoordinateCross (); DrawNetgenLogo (); if (lock) { lock -> UnLock(); delete lock; lock = NULL; } glFinish(); } catch (bad_weak_ptr e) { cout << "don't have a mesh to visualize" << endl; VisualScene::DrawScene(); } } void VisualSceneMesh :: BuildScene (int zoomall) { try { shared_ptr mesh = GetMesh(); if (!mesh) { VisualScene::BuildScene (zoomall); return; } if (!lock) { lock = new NgLock (mesh->Mutex()); lock -> Lock(); } static int timer = NgProfiler::CreateTimer ("VSMesh::BuildScene"); NgProfiler::RegionTimer reg (timer); Point3d pmin, pmax; static double oldrad = 0; Array faces; int meshtimestamp = mesh->GetTimeStamp(); if (meshtimestamp > vstimestamp || zoomall) { if (mesh->GetDimension() == 2) { // works in NGSolve, mesh view mesh->GetBox (pmin, pmax); } else { // otherwise strange zooms douring mesh generation mesh->GetBox (pmin, pmax, SURFACEPOINT); } if (vispar.use_center_coords && zoomall == 2) { center.X() = vispar.centerx; center.Y() = vispar.centery; center.Z() = vispar.centerz; } else if (selpoint >= 1 && zoomall == 2) center = mesh->Point (selpoint); else if (vispar.centerpoint >= 1 && zoomall == 2) center = mesh->Point (vispar.centerpoint); else center = Center (pmin, pmax); rad = 0.5 * Dist (pmin, pmax); if(rad == 0) rad = 1e-6; if (rad > 1.2 * oldrad || mesh->GetMajorTimeStamp() > vstimestamp || zoomall) { CalcTransformationMatrices(); oldrad = rad; } } glEnable (GL_NORMALIZE); if (pointnumberlist) { glDeleteLists (pointnumberlist, 1); pointnumberlist = 0; } if (badellist) { glDeleteLists (badellist, 1); badellist = 0; } /* if (prismlist) { glDeleteLists (prismlist, 1); prismlist = 0; } if (pyramidlist) { glDeleteLists (pyramidlist, 1); pyramidlist = 0; } if (hexlist) { glDeleteLists (hexlist, 1); hexlist = 0; } */ if (identifiedlist) { glDeleteLists (identifiedlist, 1); identifiedlist = 0; } pointnumberlist = glGenLists (1); glNewList (pointnumberlist, GL_COMPILE); if (vispar.drawpointnumbers || vispar.drawedgenumbers || vispar.drawfacenumbers || vispar.drawelementnumbers) { // glEnable (GL_COLOR_MATERIAL); GLfloat textcol[3] = { float(1-backcolor), float(1-backcolor), float(1-backcolor) }; glColor3fv (textcol); glNormal3d (0, 0, 1); glPushAttrib (GL_LIST_BIT); // glListBase (fontbase); char buf[30]; if (vispar.drawpointnumbers) for (PointIndex pi : mesh->Points().Range()) { const Point3d & p = mesh->Point(pi); glRasterPos3d (p.X(), p.Y(), p.Z()); sprintf (buf, "%d", int(pi)); // glCallLists (strlen (buf), GL_UNSIGNED_BYTE, buf); MyOpenGLText (buf); } if (vispar.drawedgenumbers) { /* for (SegmentIndex i = 0; i < mesh->GetNSeg(); i++) { const Segment & seg = (*mesh)[i]; const Point3d & p1 = mesh->Point(seg[0]); const Point3d & p2 = mesh->Point(seg[1]); const Point3d p = Center (p1, p2); glRasterPos3d (p.X(), p.Y(), p.Z()); sprintf (buf, "%d", seg.edgenr); glCallLists (strlen (buf), GL_UNSIGNED_BYTE, buf); } */ const MeshTopology & top = mesh->GetTopology(); for (int i = 1; i <= top.GetNEdges(); i++) { int v1, v2; top.GetEdgeVertices (i, v1, v2); const Point3d & p1 = mesh->Point(v1); const Point3d & p2 = mesh->Point(v2); const Point3d p = Center (p1, p2); glRasterPos3d (p.X(), p.Y(), p.Z()); sprintf (buf, "%d", i); // glCallLists (strlen (buf), GL_UNSIGNED_BYTE, buf); MyOpenGLText (buf); } } if (vispar.drawfacenumbers) { const MeshTopology & top = mesh->GetTopology(); Array v; for (int i = 1; i <= top.GetNFaces(); i++) { top.GetFaceVertices (i, v); const Point3d & p1 = mesh->Point(v.Elem(1)); const Point3d & p2 = mesh->Point(v.Elem(2)); const Point3d & p3 = mesh->Point(v.Elem(3)); Point3d p; if (v.Elem(4) == 0) { p = Center (p1, p2, p3); } else { const Point3d & p4 = mesh->Point(v.Elem(4)); Point3d hp1 = Center (p1, p2); Point3d hp2 = Center (p3, p4); p = Center (hp1, hp2); } glRasterPos3d (p.X(), p.Y(), p.Z()); sprintf (buf, "%d", i); // glCallLists (strlen (buf), GL_UNSIGNED_BYTE, buf); MyOpenGLText (buf); } } if (vispar.drawelementnumbers) { Array v; for (int i = 1; i <= mesh->GetNE(); i++) { // const ELEMENTTYPE & eltype = mesh->ElementType(i); Array pnums; Point3d p; const Element & el = mesh->VolumeElement (i); if ( ! el.PNum(5)) // eltype == TET ) { pnums.SetSize(4); for( int j = 0; j < pnums.Size(); j++) pnums[j] = mesh->VolumeElement(i).PNum(j+1); const Point3d & p1 = mesh->Point(pnums[0]); const Point3d & p2 = mesh->Point(pnums[1]); const Point3d & p3 = mesh->Point(pnums[2]); const Point3d & p4 = mesh->Point(pnums[3]); p = Center (p1, p2, p3, p4); } else if ( ! el.PNum(6)) // eltype == PYRAMID { pnums.SetSize(5); for( int j = 0; j < pnums.Size(); j++) pnums[j] = mesh->VolumeElement(i).PNum(j+1); const Point3d & p1 = mesh->Point(pnums[0]); const Point3d & p2 = mesh->Point(pnums[1]); const Point3d & p3 = mesh->Point(pnums[2]); const Point3d & p4 = mesh->Point(pnums[3]); const Point3d & p5 = mesh->Point(pnums[4]); p.X() = 0.3 * p5.X() + 0.7 * Center ( Center(p1, p3) , Center(p2, p4) ) . X(); p.Y() = 0.3 * p5.Y() + 0.7 * Center ( Center(p1, p3) , Center(p2, p4) ) . Y(); p.Z() = 0.3 * p5.Z() + 0.7 * Center ( Center(p1, p3) , Center(p2, p4) ) . Z(); } else if ( ! el.PNum(7) ) // eltype == PRISM { pnums.SetSize(6); for( int j = 0; j < pnums.Size(); j++) pnums[j] = mesh->VolumeElement(i).PNum(j+1); const Point3d & p1 = mesh->Point(pnums[0]); const Point3d & p2 = mesh->Point(pnums[1]); const Point3d & p3 = mesh->Point(pnums[2]); const Point3d & p11 = mesh->Point(pnums[3]); const Point3d & p12 = mesh->Point(pnums[4]); const Point3d & p13 = mesh->Point(pnums[5]); p = Center ( Center (p1, p2, p3) , Center(p11, p12, p13) ) ; } else if (! el.PNum(9) ) // eltype == HEX { pnums.SetSize(8); for( int j = 0; j < pnums.Size(); j++) pnums[j] = mesh->VolumeElement(i).PNum(j+1); const Point3d & p1 = mesh->Point(pnums[0]); const Point3d & p2 = mesh->Point(pnums[1]); const Point3d & p3 = mesh->Point(pnums[2]); const Point3d & p4 = mesh->Point(pnums[3]); const Point3d & p5 = mesh->Point(pnums[4]); const Point3d & p6 = mesh->Point(pnums[5]); const Point3d & p7 = mesh->Point(pnums[6]); const Point3d & p8 = mesh->Point(pnums[7]); p = Center ( Center ( Center(p1, p3), Center(p2, p4) ) , Center( Center(p5, p7) , Center(p6, p8 ) ) ); } glRasterPos3d (p.X(), p.Y(), p.Z()); sprintf (buf, "%d", i); // glCallLists (strlen (buf), GL_UNSIGNED_BYTE, buf); MyOpenGLText (buf); } } glPopAttrib (); // glDisable (GL_COLOR_MATERIAL); } glEndList (); badellist = glGenLists (1); glNewList (badellist, GL_COMPILE); if (vispar.drawbadels) { // SetClippingPlane (); static float badelcol[] = { 1.0f, 0.0f, 1.0f, 1.0f }; glLineWidth (1.0f); for (int i = 1; i <= mesh->GetNE(); i++) { if (mesh->VolumeElement(i).flags.badel || mesh->VolumeElement(i).flags.illegal || (i == vispar.drawelement)) { // copy to be thread-safe Element el = mesh->VolumeElement (i); el.GetSurfaceTriangles (faces); glMaterialfv(GL_FRONT, GL_AMBIENT_AND_DIFFUSE, badelcol); // if ( (el.GetNP() == 4) || (el.GetNP() == 10)) if (el.PNum(1)) { glBegin (GL_TRIANGLES); for (int j = 1; j <= faces.Size(); j++) { Element2d & face = faces.Elem(j); const Point3d & lp1 = mesh->Point (el.PNum(face.PNum(1))); const Point3d & lp2 = mesh->Point (el.PNum(face.PNum(2))); const Point3d & lp3 = mesh->Point (el.PNum(face.PNum(3))); Vec3d n = Cross (Vec3d (lp1, lp2), Vec3d (lp1, lp3)); n /= (n.Length()+1e-12); glNormal3d (n.X(), n.Y(), n.Z()); glVertex3d (lp1.X(), lp1.Y(), lp1.Z()); glVertex3d (lp2.X(), lp2.Y(), lp2.Z()); glVertex3d (lp3.X(), lp3.Y(), lp3.Z()); } glEnd(); } } } for (ElementIndex ei : mesh->VolumeElements().Range()) { if (mesh->VolumeElement(ei).flags.badel) { // copy to be thread-safe Element el = mesh->VolumeElement (ei); if ( (el.GetNP() == 4) || (el.GetNP() == 10)) { glBegin (GL_LINES); glVertex3d (0,0,0); const Point3d & p = mesh->Point(el.PNum(1)); glVertex3d (p.X(), p.Y(), p.Z()); glEnd(); } } } for (int i = 1; i <= mesh->GetNE(); i++) { Element el = mesh->VolumeElement (i); int hascp = 0; for (int j = 1; j <= el.GetNP(); j++) if (el.PNum(j) == vispar.centerpoint) hascp = 1; if (hascp) { (*testout) << "draw el " << i << " : "; for (int j = 1; j <= el.GetNP(); j++) (*testout) << el.PNum(j) << " "; (*testout) << endl; if (el.GetNP() == 4) { int et[6][2] = { { 1, 2 }, { 1, 3 }, { 1, 4 }, { 2, 3 }, { 2, 4 }, { 3, 4 } } ; for (int j = 0; j < 6; j++) { glBegin (GL_LINES); const Point3d & p1 = mesh->Point (el.PNum(et[j][0])); const Point3d & p2 = mesh->Point (el.PNum(et[j][1])); glVertex3d (p1.X(), p1.Y(), p1.Z()); glVertex3d (p2.X(), p2.Y(), p2.Z()); glEnd (); } } if (el.GetNP() == 10) { int et[12][2] = { { 1, 5 }, { 2, 5 }, { 1, 6 }, { 3, 6 }, { 1, 7 }, { 4, 7 }, { 2, 8 }, { 3, 8 }, { 2, 9 }, { 4, 9 }, { 3, 10 }, { 4, 10 } }; for (int j = 0; j < 12; j++) { glBegin (GL_LINES); const Point3d & p1 = mesh->Point (el.PNum(et[j][0])); const Point3d & p2 = mesh->Point (el.PNum(et[j][1])); glVertex3d (p1.X(), p1.Y(), p1.Z()); glVertex3d (p2.X(), p2.Y(), p2.Z()); glEnd (); } } } } for (SurfaceElementIndex sei : mesh->SurfaceElements().Range()) { Element2d el = mesh->SurfaceElement(sei); // copy to be thread-safe if (!el.BadElement()) continue; bool drawel = true; for (int j = 1; j <= el.GetNP(); j++) if (!el.PNum(j).IsValid()) drawel = false; if (!drawel) continue; // cout << int (el.GetType()) << " " << flush; switch (el.GetType()) { case TRIG: { glBegin (GL_TRIANGLES); Point3d lp1 = mesh->Point (el.PNum(1)); Point3d lp2 = mesh->Point (el.PNum(2)); Point3d lp3 = mesh->Point (el.PNum(3)); Vec3d n = Cross (Vec3d (lp1, lp2), Vec3d (lp1, lp3)); n /= (n.Length() + 1e-12); glNormal3dv (&n.X()); glVertex3dv (&lp1.X()); glVertex3dv (&lp2.X()); glVertex3dv (&lp3.X()); glEnd(); break; } case QUAD: { glBegin (GL_QUADS); const Point3d & lp1 = mesh->Point (el.PNum(1)); const Point3d & lp2 = mesh->Point (el.PNum(2)); const Point3d & lp3 = mesh->Point (el.PNum(4)); const Point3d & lp4 = mesh->Point (el.PNum(3)); Vec3d n = Cross (Vec3d (lp1, lp2), Vec3d (lp1, Center (lp3, lp4))); n /= (n.Length() + 1e-12); glNormal3d (n.X(), n.Y(), n.Z()); glVertex3d (lp1.X(), lp1.Y(), lp1.Z()); glVertex3d (lp2.X(), lp2.Y(), lp2.Z()); glVertex3d (lp4.X(), lp4.Y(), lp4.Z()); glVertex3d (lp3.X(), lp3.Y(), lp3.Z()); glEnd(); break; } case TRIG6: { int lines[6][2] = { { 1, 6 }, { 2, 6 }, { 1, 5 }, { 3, 5 }, { 2, 4 }, { 3, 4 } }; glBegin (GL_LINES); for (int j = 0; j < 6; j++) { glVertex3dv ( mesh->Point (el.PNum(lines[j][0])) ); glVertex3dv ( mesh->Point (el.PNum(lines[j][0])) ); } glEnd(); break; } case QUAD6: { int lines[6][2] = { { 1, 5 }, { 2, 5 }, { 3, 6 }, { 4, 6 }, { 1, 4 }, { 2, 3 } }; glBegin (GL_LINES); for (int j = 0; j < 6; j++) { const Point3d & lp1 = mesh->Point (el.PNum(lines[j][0])); const Point3d & lp2 = mesh->Point (el.PNum(lines[j][1])); glVertex3d (lp1.X(), lp1.Y(), lp1.Z()); glVertex3d (lp2.X(), lp2.Y(), lp2.Z()); } glEnd (); break; } default: PrintSysError ("Cannot draw surface element of type ", int(el.GetType())); } } glLoadName (0); } glEndList (); if (1) { identifiedlist = glGenLists (1); glNewList (identifiedlist, GL_COMPILE); GLfloat identifiedcol[] = { 1, 0, 1, 1 }; glLineWidth (3); // for (i = 1; i <= mesh->GetNSeg(); i++) if (mesh -> HasIdentifications() ) { if (mesh->GetIdentifications().HasIdentifiedPoints()) { INDEX_2_HASHTABLE & idpts = mesh->GetIdentifications().GetIdentifiedPoints(); for (int i = 1; i <= idpts.GetNBags(); i++) for (int j = 1; j <= idpts.GetBagSize(i); j++) { INDEX_2 pts; int val; idpts.GetData (i, j, pts, val); const Point3d & p1 = mesh->Point(pts.I1()); const Point3d & p2 = mesh->Point(pts.I2()); glMaterialfv (GL_FRONT_AND_BACK, GL_AMBIENT_AND_DIFFUSE, identifiedcol); glBegin (GL_LINES); glVertex3f (p1.X(), p1.Y(), p1.Z()); glVertex3f (p2.X(), p2.Y(), p2.Z()); glEnd(); } } } glEndList (); } if (lock) { lock -> UnLock(); delete lock; lock = NULL; } vstimestamp = meshtimestamp; } catch (bad_weak_ptr e) { cout << "vsmesh::buildscene: don't have a mesh to visualize" << endl; VisualScene::BuildScene (zoomall); } } void VisualSceneMesh :: BuildFilledList (bool names) { shared_ptr mesh = GetMesh(); static int timer = NgProfiler::CreateTimer ("Mesh::BuildFilledList"); NgProfiler::RegionTimer reg (timer); #ifdef PARALLELGL if (id == 0 && ntasks > 1) { InitParallelGL(); par_filledlists.SetSize (ntasks); MyMPI_SendCmd ("redraw"); MyMPI_SendCmd ("filledlist"); for ( int dest = 1; dest < ntasks; dest++ ) MyMPI_Recv (par_filledlists[dest], dest, MPI_TAG_VIS); if (filledlist) glDeleteLists (filledlist, 1); filledlist = glGenLists (1); glNewList (filledlist, GL_COMPILE); for ( int dest = 1; dest < ntasks; dest++ ) glCallList (par_filledlists[dest]); glEndList(); filledtimestamp = NextTimeStamp(); return; } #endif if (!lock) { lock = new NgLock (mesh->Mutex()); lock -> Lock(); } filledtimestamp = NextTimeStamp(); if (filledlist) glDeleteLists (filledlist, 1); filledlist = glGenLists (1); glNewList (filledlist, GL_COMPILE); #ifdef STLGEOM STLGeometry * stlgeometry = dynamic_cast (ng_geometry); bool checkvicinity = (stlgeometry != NULL) && stldoctor.showvicinity; #endif glEnable (GL_NORMALIZE); glLineWidth (1.0f); Vector locms; if (vispar.colormeshsize) { glEnable (GL_COLOR_MATERIAL); glShadeModel (GL_SMOOTH); locms.SetSize (mesh->GetNP()); maxh = -1; minh = 1e99; for (int i = 1; i <= locms.Size(); i++) { Point3d p = mesh->Point(i); locms(i-1) = mesh->GetH (p); if (locms(i-1) > maxh) maxh = locms(i-1); if (locms(i-1) < minh) minh = locms(i-1); } if (!locms.Size()) { minh = 1; maxh = 10; } } else glDisable (GL_COLOR_MATERIAL); GLfloat matcol[] = { 0, 1, 0, 1 }; GLfloat matcolsel[] = { 1, 0, 0, 1 }; GLint rendermode; glGetIntegerv (GL_RENDER_MODE, &rendermode); CurvedElements & curv = mesh->GetCurvedElements(); int hoplotn = 1 << vispar.subdivisions; Array seia; for (int faceindex = 1; faceindex <= mesh->GetNFD(); faceindex++) { mesh->GetSurfaceElementsOfFace (faceindex, seia); // Philippose - 06/07/2009 // Modified the colour system to integrate the face colours into // the mesh data structure, rather than limit it to the OCC geometry // structure... allows other geometry types to use face colours too matcol[0] = mesh->GetFaceDescriptor(faceindex).SurfColour().X(); matcol[1] = mesh->GetFaceDescriptor(faceindex).SurfColour().Y(); matcol[2] = mesh->GetFaceDescriptor(faceindex).SurfColour().Z(); matcol[3] = 1.0; if (faceindex == selface) glMaterialfv(GL_FRONT_AND_BACK, GL_AMBIENT_AND_DIFFUSE, matcolsel); else glMaterialfv(GL_FRONT_AND_BACK, GL_AMBIENT_AND_DIFFUSE, matcol); for (int hi = 0; hi < seia.Size(); hi++) { SurfaceElementIndex sei = seia[hi]; const Element2d & el = (*mesh)[sei]; bool drawel = (!el.IsDeleted() & el.IsVisible()); #ifdef STLGEOM if (checkvicinity) for (int j = 0; j < el.GetNP(); j++) if (!stlgeometry->Vicinity(el.GeomInfoPi(j+1).trignum)) drawel = 0; #endif if (!drawel) continue; if (names) glLoadName (sei+1); switch (el.GetType()) { case TRIG: { if (curv.IsHighOrder()) // && curv.IsSurfaceElementCurved(sei)) { if (hoplotn > 128) hoplotn = 128; Point<3> xa[129]; Vec<3> na[129]; for (int i = 0; i < hoplotn; i++) { glBegin (GL_TRIANGLE_STRIP); for (int j = 0; j <= hoplotn-i; j++) for (int k = 0; k < 2; k++) { if (j == hoplotn-i && k == 1) continue; if (i > 0 && k == 0) { glNormal3dv (na[j]); glVertex3dv (xa[j]); continue; } Point<2> xref (double(j) / hoplotn, double(i+k) / hoplotn); Point<3> xglob; Mat<3,2> dxdxi; Vec<3> dx, dy, n; curv.CalcSurfaceTransformation (xref, sei, xglob, dxdxi); for (int i = 0; i < 3; i++) { dx(i) = dxdxi(i,0); dy(i) = dxdxi(i,1); } n = Cross (dx, dy); glNormal3dv (n); glVertex3dv (xglob); if (k == 1) { na[j] = n; xa[j] = xglob; } } glEnd(); } } else // not high order { glBegin (GL_TRIANGLES); const Point<3> & lp0 = (*mesh) [el[0]]; const Point<3> & lp1 = (*mesh) [el[1]]; const Point<3> & lp2 = (*mesh) [el[2]]; Vec<3> n = Cross (lp1-lp0, lp2-lp0).Normalize(); glNormal3dv (n); for (int j = 0; j < 3; j++) { if (vispar.colormeshsize) SetOpenGlColor (locms(el[0]-1), minh, maxh, 0); glVertex3dv ( (*mesh)[el[j]] ); } glEnd(); } break; } case QUAD: { if (curv.IsHighOrder()) // && curv.IsSurfaceElementCurved(sei)) { Point<2> xr[4]; Point<3> xg; Vec<3> dx, dy, n; glBegin (GL_QUADS); for (int i = 0; i < hoplotn; i++) for (int j = 0; j < hoplotn; j++) { xr[0](0) = (double) i/hoplotn; xr[0](1) = (double) j/hoplotn; xr[1](0) = (double)(i+1)/hoplotn; xr[1](1) = (double) j/hoplotn; xr[2](0) = (double)(i+1)/hoplotn; xr[2](1) = (double)(j+1)/hoplotn; xr[3](0) = (double) i/hoplotn; xr[3](1) = (double)(j+1)/hoplotn; for (int l=0; l<4; l++) { Mat<3,2> dxdxi; curv.CalcSurfaceTransformation (xr[l], sei, xg, dxdxi); for (int i = 0; i < 3; i++) { dx(i) = dxdxi(i,0); dy(i) = dxdxi(i,1); } n = Cross (dx, dy); n.Normalize(); glNormal3d (n(0), n(1), n(2)); glVertex3d (xg(0), xg(1), xg(2)); } } glEnd(); } else // not high order { glBegin (GL_QUADS); const Point<3> & lp1 = mesh->Point (el.PNum(1)); const Point<3> & lp2 = mesh->Point (el.PNum(2)); const Point<3> & lp3 = mesh->Point (el.PNum(4)); const Point<3> & lp4 = mesh->Point (el.PNum(3)); Vec<3> n = Cross (lp2-lp1, Center (lp3, lp4)-lp1); n.Normalize(); glNormal3dv (n); glVertex3dv (lp1); glVertex3dv (lp2); glVertex3dv (lp4); glVertex3dv (lp3); glEnd (); } break; } case TRIG6: { glBegin (GL_TRIANGLES); static int trigs[4][3] = { { 1, 6, 5 }, { 2, 4, 6 }, { 3, 5, 4 }, { 4, 5, 6 } }; for (int j = 0; j < 4; j++) { const Point<3> & lp1 = mesh->Point (el.PNum(trigs[j][0])); const Point<3> & lp2 = mesh->Point (el.PNum(trigs[j][1])); const Point<3> & lp3 = mesh->Point (el.PNum(trigs[j][2])); // Vec3d n = Cross (Vec3d (lp1, lp2), Vec3d (lp1, lp3)); Vec<3> n = Cross (lp2-lp1, lp3-lp1); glNormal3dv (n); glVertex3dv (lp1); glVertex3dv (lp2); glVertex3dv (lp3); } glEnd(); break; } case QUAD6: { glBegin (GL_QUADS); static int quads[2][4] = { { 1, 5, 6, 4 }, { 5, 2, 3, 6 } }; for (int j = 0; j < 2; j++) { Point3d lp1 = mesh->Point (el.PNum(quads[j][0])); Point3d lp2 = mesh->Point (el.PNum(quads[j][1])); Point3d lp3 = mesh->Point (el.PNum(quads[j][2])); Point3d lp4 = mesh->Point (el.PNum(quads[j][3])); Vec3d n = Cross (Vec3d (lp1, lp2), Vec3d (lp1, lp3)); n /= (n.Length() + 1e-12); glNormal3dv (&n.X()); glVertex3dv (&lp1.X()); glVertex3dv (&lp2.X()); glVertex3dv (&lp3.X()); glVertex3dv (&lp4.X()); } glEnd(); break; } case QUAD8: { glBegin (GL_TRIANGLES); static int boundary[] = { 1, 5, 2, 8, 3, 6, 4, 7, 1 }; Point3d c(0,0,0); for (int j = 0; j < 4; j++) { const Point3d & hp = mesh->Point (el[j]); c.X() -= 0.25 * hp.X(); c.Y() -= 0.25 * hp.Y(); c.Z() -= 0.25 * hp.Z(); } for (int j = 4; j < 8; j++) { const Point3d & hp = mesh->Point (el[j]); c.X() += 0.5 * hp.X(); c.Y() += 0.5 * hp.Y(); c.Z() += 0.5 * hp.Z(); } for (int j = 0; j < 8; j++) { Point3d lp1 = mesh->Point (el.PNum(boundary[j])); Point3d lp2 = mesh->Point (el.PNum(boundary[j+1])); Vec3d n = Cross (Vec3d (c, lp1), Vec3d (c, lp2)); n /= (n.Length() + 1e-12); glNormal3dv (&n.X()); glVertex3dv (&lp1.X()); glVertex3dv (&lp2.X()); glVertex3dv (&c.X()); } glEnd(); break; } default: PrintSysError ("Cannot draw (2) surface element of type ", int(el.GetType())); } } } glLoadName (0); glEndList (); #ifdef PARALLELGL glFinish(); if (id > 0) MyMPI_Send (filledlist, 0, MPI_TAG_VIS); #endif } void VisualSceneMesh :: BuildLineList() { shared_ptr mesh = GetMesh(); static int timer = NgProfiler::CreateTimer ("Mesh::BuildLineList"); NgProfiler::RegionTimer reg (timer); #ifdef PARALLELGL if (id == 0 && ntasks > 1) { InitParallelGL(); par_linelists.SetSize (ntasks); MyMPI_SendCmd ("redraw"); MyMPI_SendCmd ("linelist"); for ( int dest = 1; dest < ntasks; dest++ ) MyMPI_Recv (par_linelists[dest], dest, MPI_TAG_VIS); if (linelist) glDeleteLists (linelist, 1); linelist = glGenLists (1); glNewList (linelist, GL_COMPILE); for ( int dest = 1; dest < ntasks; dest++ ) glCallList (par_linelists[dest]); glEndList(); linetimestamp = NextTimeStamp(); return; } #endif if (!lock) { lock = new NgLock (mesh->Mutex()); lock -> Lock(); } linetimestamp = NextTimeStamp(); #ifdef STLGEOM STLGeometry * stlgeometry = dynamic_cast (ng_geometry); bool checkvicinity = (stlgeometry != NULL) && stldoctor.showvicinity; #endif if (linelist) glDeleteLists (linelist, 1); linelist = glGenLists (1); glNewList (linelist, GL_COMPILE); // cout << "linelist = " << linelist << endl; glLineWidth (1.0f); int hoplotn = 1 << vispar.subdivisions; // PrintMessage (3, "nse = ", mesh->GetNSE()); for (SurfaceElementIndex sei = 0; sei < mesh->GetNSE(); sei++) { const Element2d & el = (*mesh)[sei]; bool drawel = (!el.IsDeleted() & el.IsVisible()); #ifdef STLGEOM if (checkvicinity) for (int j = 0; j < el.GetNP(); j++) if (!stlgeometry->Vicinity(el.GeomInfoPi(j+1).trignum)) drawel = 0; #endif if (!drawel) continue; switch (el.GetType()) { case TRIG: { CurvedElements & curv = mesh->GetCurvedElements(); if (curv.IsHighOrder()) // && curv.IsSurfaceElementCurved(sei)) { Point<3> xg; glBegin (GL_LINE_LOOP); for (int i = 0; i < hoplotn; i++) { Point<2> xr (double(i) / hoplotn, 0); curv.CalcSurfaceTransformation (xr, sei, xg); glVertex3dv (xg); } for (int i = 0; i < hoplotn; i++) { Point<2> xr (double(hoplotn-i) / hoplotn, double(i)/hoplotn); curv.CalcSurfaceTransformation (xr, sei, xg); glVertex3dv (xg); } for (int i = 0; i < hoplotn; i++) { Point<2> xr (0, double(hoplotn-i) / hoplotn); curv.CalcSurfaceTransformation (xr, sei, xg); glVertex3dv (xg); } glEnd(); } else { glBegin (GL_TRIANGLES); for (int j = 0; j < 3; j++) glVertex3dv ( (*mesh) [el[j]] ); /* const Point<3> & lp0 = (*mesh) [el[0]]; const Point<3> & lp1 = (*mesh) [el[1]]; const Point<3> & lp2 = (*mesh) [el[2]]; glVertex3dv (lp0); glVertex3dv (lp1); glVertex3dv (lp2); */ glEnd(); } break; } case QUAD: { CurvedElements & curv = mesh->GetCurvedElements(); if (curv.IsHighOrder()) // && curv.IsSurfaceElementCurved(sei)) { Point<2> xr; Point<3> xg; glBegin (GL_LINE_STRIP); for (int side = 0; side < 4; side++) { for (int i = 0; i <= hoplotn; i++) { switch (side) { case 0: xr(0) = (double) i/hoplotn; xr(1) = 0.; break; case 1: xr(0) = 1.; xr(1) = (double) i/hoplotn; break; case 2: xr(0) = (double) (hoplotn-i)/hoplotn; xr(1) = 1.; break; case 3: xr(0) = 0.; xr(1) = (double) (hoplotn-i)/hoplotn; break; } curv.CalcSurfaceTransformation (xr, sei, xg); glVertex3d (xg(0), xg(1), xg(2)); } } glEnd(); } else { glBegin (GL_QUADS); const Point3d & lp1 = mesh->Point (el.PNum(1)); const Point3d & lp2 = mesh->Point (el.PNum(2)); const Point3d & lp3 = mesh->Point (el.PNum(4)); const Point3d & lp4 = mesh->Point (el.PNum(3)); Vec3d n = Cross (Vec3d (lp1, lp2), Vec3d (lp1, Center (lp3, lp4))); glNormal3d (n.X(), n.Y(), n.Z()); glVertex3d (lp1.X(), lp1.Y(), lp1.Z()); glVertex3d (lp2.X(), lp2.Y(), lp2.Z()); glVertex3d (lp4.X(), lp4.Y(), lp4.Z()); glVertex3d (lp3.X(), lp3.Y(), lp3.Z()); glEnd(); } break; } case TRIG6: { int lines[6][2] = { { 1, 6 }, { 2, 6 }, { 1, 5 }, { 3, 5 }, { 2, 4 }, { 3, 4 } }; glBegin (GL_LINES); for (int j = 0; j < 6; j++) { const Point3d & lp1 = mesh->Point (el.PNum(lines[j][0])); const Point3d & lp2 = mesh->Point (el.PNum(lines[j][1])); glVertex3d (lp1.X(), lp1.Y(), lp1.Z()); glVertex3d (lp2.X(), lp2.Y(), lp2.Z()); } glEnd(); break; } case QUAD6: { int lines[6][2] = { { 1, 5 }, { 2, 5 }, { 3, 6 }, { 4, 6 }, { 1, 4 }, { 2, 3 } }; glBegin (GL_LINES); for (int j = 0; j < 6; j++) { const Point3d & lp1 = mesh->Point (el.PNum(lines[j][0])); const Point3d & lp2 = mesh->Point (el.PNum(lines[j][1])); glVertex3d (lp1.X(), lp1.Y(), lp1.Z()); glVertex3d (lp2.X(), lp2.Y(), lp2.Z()); } glEnd (); break; } case QUAD8: { int lines[8][2] = { { 1, 5 }, { 2, 5 }, { 3, 6 }, { 4, 6 }, { 1, 7 }, { 4, 7 }, { 2, 8 }, { 3, 8 } }; glBegin (GL_LINES); for (int j = 0; j < 8; j++) { const Point3d & lp1 = mesh->Point (el.PNum(lines[j][0])); const Point3d & lp2 = mesh->Point (el.PNum(lines[j][1])); glVertex3d (lp1.X(), lp1.Y(), lp1.Z()); glVertex3d (lp2.X(), lp2.Y(), lp2.Z()); } glEnd (); break; } default: PrintSysError ("Cannot draw (4) surface element of type ", int(el.GetType())); } } glEndList (); #ifdef PARALLELGL glFinish(); if (id > 0) MyMPI_Send (linelist, 0, MPI_TAG_VIS); #endif } void VisualSceneMesh :: BuildEdgeList() { shared_ptr mesh = GetMesh(); if (!lock) { lock = new NgLock (mesh->Mutex()); lock -> Lock(); } if (edgetimestamp > mesh->GetTimeStamp () && vispar.drawtetsdomain == 0 && vispar.shrink == 1) return; edgetimestamp = NextTimeStamp(); if (edgelist) glDeleteLists (edgelist, 1); edgelist = glGenLists (1); glNewList (edgelist, GL_COMPILE); GLfloat matcoledge[] = { 0, 0, 1, 1 }; GLfloat matcolsingedge[] = { 1, 0, 1, 1 }; glEnable (GL_POLYGON_OFFSET_LINE); glPolygonOffset (1, -1); glEnable (GL_COLOR_MATERIAL); glDisable (GL_LIGHTING); for (int i = 1; i <= mesh->GetNSeg(); i++) { const Segment & seg = mesh->LineSegment(i); #ifdef PARALLEL if (ntasks > 1 && vispar.drawtetsdomain && (vispar.drawtetsdomain != seg.GetPartition())) continue; #endif const Point3d & p1 = (*mesh)[seg[0]]; const Point3d & p2 = (*mesh)[seg[1]]; if (seg.singedge_left || seg.singedge_right) glMaterialfv (GL_FRONT_AND_BACK, GL_AMBIENT_AND_DIFFUSE, matcolsingedge); else glMaterialfv (GL_FRONT_AND_BACK, GL_AMBIENT_AND_DIFFUSE, matcoledge); if (seg.singedge_left || seg.singedge_right) glColor3fv (matcolsingedge); else glColor3fv (matcoledge); if (seg.edgenr == seledge) glLineWidth(5); else glLineWidth(2); if (mesh->GetCurvedElements().IsHighOrder()) { int hoplotn = 1 << vispar.subdivisions; // mesh->GetCurvedElements().GetNVisualSubsecs(); Point<3> x; glBegin (GL_LINE_STRIP); for (int j = 0; j <= hoplotn; j++) { mesh->GetCurvedElements().CalcSegmentTransformation ((double) j/hoplotn, i-1, x); glVertex3d (x(0), x(1), x(2)); /* cout << "x = " << x(0) << ", " << x(1) << ", " << x(2) << ", norm = 1+" << sqrt(x(0)*x(0)+x(1)*x(1))-1 << ", phi = " << atan2(x(1), x(0))/M_PI << endl; */ } glEnd(); } else { glBegin (GL_LINES); Point<3> hp1 = p1; Point<3> hp2 = p2; Point<3> c = Center(p1, p2); if (vispar.shrink < 1) { hp1 = c + vispar.shrink * (hp1 - c); hp2 = c + vispar.shrink * (hp2 - c); } glVertex3dv (hp1); glVertex3dv (hp2); // p2.X(), p2.Y(), p2.Z()); glEnd(); } } glLineWidth (2); glDisable (GL_POLYGON_OFFSET_LINE); glDisable (GL_COLOR_MATERIAL); glEnable (GL_LIGHTING); glEndList(); } void VisualSceneMesh :: BuildPointNumberList() { ; } // Bernstein Pol B_{n,i}(x) = n! / i! / (n-i)! (1-x)^{n-i} x^i static inline double Bernstein (int n, int i, double x) { double val = 1; for (int j = 1; j <= i; j++) val *= x; for (int j = 1; j <= n-i; j++) val *= (1-x) * (j+i) / j; return val; } void ToBernstein (int order, Point<3> * pts, int stride) { static DenseMatrix mat, inv; static Vector vec1, vec2; if (mat.Height () != order+1) { mat.SetSize (order+1); inv.SetSize (order+1); vec1.SetSize (order+1); vec2.SetSize (order+1); for (int i = 0; i <= order; i++) { double x = double(i) / order; for (int j = 0; j <= order; j++) mat(i,j) = Bernstein (order, j, x); } CalcInverse (mat, inv); } for (int i = 0; i < 3; i++) { for (int j = 0; j <= order; j++) vec1(j) = pts[j*stride](i); inv.Mult (vec1, vec2); for (int j = 0; j <= order; j++) pts[j*stride](i) = vec2(j); } } void VisualSceneMesh :: BuildTetList() { shared_ptr mesh = GetMesh(); if (tettimestamp > mesh->GetTimeStamp () && tettimestamp > vispar.clipping.timestamp ) return; if (!lock) { lock = new NgLock (mesh->Mutex()); lock -> Lock(); } tettimestamp = NextTimeStamp(); if (tetlist) glDeleteLists (tetlist, 1); tetlist = glGenLists (1); glNewList (tetlist, GL_COMPILE); Vector locms; // Philippose - 16/02/2010 // Add Mesh size based coloring of // meshes also for the volume elements if (vispar.colormeshsize) { glEnable (GL_COLOR_MATERIAL); locms.SetSize (mesh->GetNP()); maxh = -1; minh = 1e99; for (int i = 1; i <= locms.Size(); i++) { Point3d p = mesh->Point(i); locms(i-1) = mesh->GetH (p); if (locms(i-1) > maxh) maxh = locms(i-1); if (locms(i-1) < minh) minh = locms(i-1); } if (!locms.Size()) { minh = 1; maxh = 10; } } else glDisable (GL_COLOR_MATERIAL); Array faces; BitArray shownode(mesh->GetNP()); if (vispar.clipping.enable) { shownode.Clear(); for (int i = 1; i <= shownode.Size(); i++) { Point<3> p = mesh->Point(i); double val = p[0] * clipplane[0] + p[1] * clipplane[1] + p[2] * clipplane[2] + clipplane[3]; if (val > 0) shownode.Set (i); } } else shownode.Set(); static float tetcols[][4] = { { 1.0f, 1.0f, 0.0f, 1.0f }, { 1.0f, 0.0f, 0.0f, 1.0f }, { 0.0f, 1.0f, 0.0f, 1.0f }, { 0.0f, 0.0f, 1.0f, 1.0f } /* { 1.0f, 1.0f, 0.0f, 0.3f }, { 1.0f, 0.0f, 0.0f, 0.3f }, { 0.0f, 1.0f, 0.0f, 0.3f }, { 0.0f, 0.0f, 1.0f, 0.3f } */ }; CurvedElements & curv = mesh->GetCurvedElements(); if (!curv.IsHighOrder()) glShadeModel (GL_FLAT); else glShadeModel (GL_SMOOTH); int hoplotn = max (2, 1 << vispar.subdivisions); for (ElementIndex ei = 0; ei < mesh->GetNE(); ei++) { if (vispar.drawtetsdomain > 0) { int tetid = vispar.drawmetispartition ? (*mesh)[ei].GetPartition() : (*mesh)[ei].GetIndex(); if (vispar.drawtetsdomain != tetid) continue; } const Element & el = (*mesh)[ei]; if ((el.GetType() == TET || el.GetType() == TET10) && !el.IsDeleted()) { bool drawtet = 1; for (int j = 0; j < 4; j++) if (!shownode.Test(el[j])) drawtet = 0; if (!drawtet) continue; int ind = el.GetIndex() % 4; if (vispar.drawmetispartition && el.GetPartition()!=-1) ind = el.GetPartition() % 4; glMaterialfv(GL_FRONT, GL_AMBIENT_AND_DIFFUSE, tetcols[ind]); if (curv.IsHighOrder()) // && curv.IsElementCurved(ei)) { const ELEMENT_FACE * faces = MeshTopology :: GetFaces1 (TET); const Point3d * vertices = MeshTopology :: GetVertices (TET); /* Point<3> grid[11][11]; Point<3> fpts[3]; int order = vispar.subdivisions+1; for (int trig = 0; trig < 4; trig++) { for (int j = 0; j < 3; j++) fpts[j] = vertices[faces[trig][j]-1]; static Point<3> c(0.25, 0.25, 0.25); if (vispar.shrink < 1) for (int j = 0; j < 3; j++) fpts[j] += (1-vispar.shrink) * (c-fpts[j]); for (int ix = 0; ix <= order; ix++) for (int iy = 0; iy <= order; iy++) { double lami[3] = { (1-double(ix)/order) * (1-double(iy)/order), ( double(ix)/order) * (1-double(iy)/order), double(iy)/order }; Point<3> xl; for (int l = 0; l < 3; l++) xl(l) = lami[0] * fpts[0](l) + lami[1] * fpts[1](l) + lami[2] * fpts[2](l); curv.CalcElementTransformation (xl, i-1, grid[ix][iy]); } for (int j = 0; j <= order; j++) ToBernstein (order, &grid[j][0], &grid[0][1]-&grid[0][0]); for (int j = 0; j <= order; j++) ToBernstein (order, &grid[0][j], &grid[1][0]-&grid[0][0]); glMap2d(GL_MAP2_VERTEX_3, 0.0, 1.0, &grid[0][1](0)-&grid[0][0](0), order+1, 0.0, 1.0, &grid[1][0](0)-&grid[0][0](0), order+1, &grid[0][0](0)); glEnable(GL_MAP2_VERTEX_3); glEnable(GL_AUTO_NORMAL); glMapGrid2f(8, 0.0, 0.999, 8, 0.0, 1.0); glEvalMesh2(GL_FILL, 0, 8, 0, 8); glDisable (GL_AUTO_NORMAL); glDisable (GL_MAP2_VERTEX_3); } */ int order = curv.GetOrder(); Array > ploc ( (order+1)*(order+1) ); Array > pglob ( (order+1)*(order+1) ); Point<3> fpts[3]; for (int trig = 0; trig < 4; trig++) { for (int j = 0; j < 3; j++) fpts[j] = vertices[faces[trig][j]-1]; static Point<3> c(0.25, 0.25, 0.25); if (vispar.shrink < 1) for (int j = 0; j < 3; j++) fpts[j] += (1-vispar.shrink) * (c-fpts[j]); for (int ix = 0, ii = 0; ix <= order; ix++) for (int iy = 0; iy <= order; iy++, ii++) { double lami[3] = { (1-double(ix)/order) * (1-double(iy)/order), ( double(ix)/order) * (1-double(iy)/order), double(iy)/order }; Point<3> xl; for (int l = 0; l < 3; l++) xl(l) = lami[0] * fpts[0](l) + lami[1] * fpts[1](l) + lami[2] * fpts[2](l); ploc[ii] = xl; } curv.CalcMultiPointElementTransformation (&ploc, ei, &pglob, 0); Point<3> grid[11][11]; for (int ix = 0, ii = 0; ix <= order; ix++) for (int iy = 0; iy <= order; iy++, ii++) grid[ix][iy] = pglob[ii]; for (int j = 0; j <= order; j++) ToBernstein (order, &grid[j][0], &grid[0][1]-&grid[0][0]); for (int j = 0; j <= order; j++) ToBernstein (order, &grid[0][j], &grid[1][0]-&grid[0][0]); glMap2d(GL_MAP2_VERTEX_3, 0.0, 1.0, &grid[0][1](0)-&grid[0][0](0), order+1, 0.0, 1.0, &grid[1][0](0)-&grid[0][0](0), order+1, &grid[0][0](0)); glEnable(GL_MAP2_VERTEX_3); glEnable(GL_AUTO_NORMAL); glMapGrid2f(hoplotn, 0.0, 0.9999f, hoplotn, 0.0, 1.0); glEvalMesh2(GL_FILL, 0, hoplotn, 0, hoplotn); glDisable (GL_AUTO_NORMAL); glDisable (GL_MAP2_VERTEX_3); } } else // Not High Order { Point<3> pts[4]; for (int j = 0; j < 4; j++) pts[j] = (*mesh)[el[j]]; if (vispar.shrink < 1) { Point<3> c = Center (pts[0], pts[1], pts[2], pts[3]); for (int j = 0; j < 4; j++) pts[j] = c + vispar.shrink * (pts[j]-c); } Vec<3> n; // Philippose - 16/02/2010 // Add Mesh size based coloring of // meshes also for the volume elements if(vispar.colormeshsize) { glBegin (GL_TRIANGLE_STRIP); n = Cross (pts[1]-pts[0], pts[2]-pts[0]); glNormal3dv (n); SetOpenGlColor (locms(el[0]-1), minh, maxh, 0); glVertex3dv (pts[0]); SetOpenGlColor (locms(el[1]-1), minh, maxh, 0); glVertex3dv (pts[1]); SetOpenGlColor (locms(el[2]-1), minh, maxh, 0); glVertex3dv (pts[2]); n = Cross (pts[3]-pts[1], pts[2]-pts[1]); glNormal3dv (n); SetOpenGlColor (locms(el[3]-1), minh, maxh, 0); glVertex3dv (pts[3]); n = Cross (pts[3]-pts[2], pts[0]-pts[2]); glNormal3dv (n); SetOpenGlColor (locms(el[0]-1), minh, maxh, 0); glVertex3dv (pts[0]); n = Cross (pts[1]-pts[3], pts[0]-pts[3]); glNormal3dv (n); SetOpenGlColor (locms(el[1]-1), minh, maxh, 0); glVertex3dv (pts[1]); glEnd(); } else // Do not color mesh based on mesh size { GLubyte ind[4][3] = { { 0,1,2 }, { 3,1,0 }, { 1,3,2 }, { 2,3,0 } }; glEnableClientState(GL_VERTEX_ARRAY); glVertexPointer(3, GL_DOUBLE, 0, &pts[0](0)); for (int j = 0; j < 4; j++) { glNormal3dv (Cross (pts[ind[j][1]]-pts[ind[j][0]], pts[ind[j][2]]-pts[ind[j][0]])); glDrawElements(GL_TRIANGLES, 3, GL_UNSIGNED_BYTE, &ind[j][0]); } glDisableClientState(GL_VERTEX_ARRAY); /* glBegin (GL_TRIANGLE_STRIP); glNormal3dv (Cross (pts[1]-pts[0], pts[2]-pts[0])); glVertex3dv (pts[0]); glVertex3dv (pts[1]); glVertex3dv (pts[2]); glNormal3dv (Cross (pts[3]-pts[1], pts[2]-pts[1])); glVertex3dv (pts[3]); glNormal3dv (Cross (pts[3]-pts[2], pts[0]-pts[2])); glVertex3dv (pts[0]); glNormal3dv (Cross (pts[1]-pts[3], pts[0]-pts[3])); glVertex3dv (pts[1]); glEnd(); */ } } } } glEndList (); } void VisualSceneMesh :: BuildPrismList() { shared_ptr mesh = GetMesh(); if (prismtimestamp > mesh->GetTimeStamp () && prismtimestamp > vispar.clipping.timestamp ) return; if (!lock) { lock = new NgLock (mesh->Mutex()); lock -> Lock(); } prismtimestamp = NextTimeStamp(); if (prismlist) glDeleteLists (prismlist, 1); prismlist = glGenLists (1); glNewList (prismlist, GL_COMPILE); static float prismcol[] = { 0.0f, 1.0f, 1.0f, 1.0f }; glLineWidth (1.0f); Array faces; glMaterialfv(GL_FRONT, GL_AMBIENT_AND_DIFFUSE, prismcol); for (ElementIndex ei = 0; ei < mesh->GetNE(); ei++) { const Element & el = (*mesh)[ei]; if (el.GetType() == PRISM && !el.IsDeleted()) { int j; int i = ei + 1; CurvedElements & curv = mesh->GetCurvedElements(); if (curv.IsHighOrder()) // && curv.IsElementCurved(ei)) { const ELEMENT_FACE * faces = MeshTopology :: GetFaces1 (PRISM); const Point3d * vertices = MeshTopology :: GetVertices (PRISM); Point<3> grid[11][11]; Point<3> fpts[4]; int order = vispar.subdivisions+1; for (int trig = 0; trig < 2; trig++) { for (int j = 0; j < 3; j++) fpts[j] = vertices[faces[trig][j]-1]; static Point<3> c(1.0/3.0, 1.0/3.0, 0.5); if (vispar.shrink < 1) for (int j = 0; j < 3; j++) fpts[j] += (1-vispar.shrink) * (c-fpts[j]); for (int ix = 0; ix <= order; ix++) for (int iy = 0; iy <= order; iy++) { double lami[3] = { (1-double(ix)/order) * (1-double(iy)/order), ( double(ix)/order) * (1-double(iy)/order), double(iy)/order }; Point<3> xl; for (int l = 0; l < 3; l++) xl(l) = lami[0] * fpts[0](l) + lami[1] * fpts[1](l) + lami[2] * fpts[2](l); curv.CalcElementTransformation (xl, i-1, grid[ix][iy]); } for (int j = 0; j <= order; j++) ToBernstein (order, &grid[j][0], &grid[0][1]-&grid[0][0]); for (int j = 0; j <= order; j++) ToBernstein (order, &grid[0][j], &grid[1][0]-&grid[0][0]); glMap2d(GL_MAP2_VERTEX_3, 0.0, 1.0, &grid[0][1](0)-&grid[0][0](0), order+1, 0.0, 1.0, &grid[1][0](0)-&grid[0][0](0), order+1, &grid[0][0](0)); glEnable(GL_MAP2_VERTEX_3); glEnable(GL_AUTO_NORMAL); glMapGrid2f(8, 0.0, 0.999f, 8, 0.0, 1.0); glEvalMesh2(GL_FILL, 0, 8, 0, 8); glDisable (GL_AUTO_NORMAL); glDisable (GL_MAP2_VERTEX_3); } for (int quad = 2; quad < 5; quad++) { for (int j = 0; j < 4; j++) fpts[j] = vertices[faces[quad][j]-1]; static Point<3> c(1.0/3.0, 1.0/3.0, 0.5); if (vispar.shrink < 1) for (int j = 0; j < 4; j++) fpts[j] += (1-vispar.shrink) * (c-fpts[j]); for (int ix = 0; ix <= order; ix++) for (int iy = 0; iy <= order; iy++) { double lami[4] = { (1-double(ix)/order) * (1-double(iy)/order), ( double(ix)/order) * (1-double(iy)/order), ( double(ix)/order) * ( double(iy)/order), (1-double(ix)/order) * ( double(iy)/order) }; Point<3> xl; for (int l = 0; l < 3; l++) xl(l) = lami[0] * fpts[0](l) + lami[1] * fpts[1](l) + lami[2] * fpts[2](l) + lami[3] * fpts[3](l); curv.CalcElementTransformation (xl, ei, grid[ix][iy]); } for (int j = 0; j <= order; j++) ToBernstein (order, &grid[j][0], &grid[0][1]-&grid[0][0]); for (int j = 0; j <= order; j++) ToBernstein (order, &grid[0][j], &grid[1][0]-&grid[0][0]); glMap2d(GL_MAP2_VERTEX_3, 0.0, 1.0, &grid[0][1](0)-&grid[0][0](0), order+1, 0.0, 1.0, &grid[1][0](0)-&grid[0][0](0), order+1, &grid[0][0](0)); glEnable(GL_MAP2_VERTEX_3); glEnable(GL_AUTO_NORMAL); glMapGrid2f(8, 0.0, 1.0, 8, 0.0, 1.0); glEvalMesh2(GL_FILL, 0, 8, 0, 8); glDisable (GL_AUTO_NORMAL); glDisable (GL_MAP2_VERTEX_3); } /* int hoplotn = 1 << vispar.subdivisions; // int hoplotn = curv.GetNVisualSubsecs(); const Point3d * facepoint = MeshTopology :: GetVertices (TRIG); const ELEMENT_FACE * elface = MeshTopology :: GetFaces(TRIG); glBegin (GL_TRIANGLES); for (int trig = 0; trig<2; trig++) { Vec<3> x0,x1,d0,d1; x0 = facepoint[1] - facepoint[2]; x1 = facepoint[0] - facepoint[2]; x0.Normalize(); x1.Normalize(); if (trig == 1) swap (x0,x1); Point<3> xr[3]; Point<3> xg; Vec<3> dx, dy, dz, n; for (int i1 = 0; i1 < hoplotn; i1++) for (int j1 = 0; j1 < hoplotn-i1; j1++) for (int k = 0; k < 2; k++) { if (k == 0) { xr[0](0) = (double) i1/hoplotn; xr[0](1) = (double) j1/hoplotn; xr[1](0) = (double)(i1+1)/hoplotn; xr[1](1) = (double) j1/hoplotn; xr[2](0) = (double) i1/hoplotn; xr[2](1) = (double)(j1+1)/hoplotn; } else { if (j1 == hoplotn-i1-1) continue; xr[0](0) = (double)(i1+1)/hoplotn; xr[0](1) = (double) j1/hoplotn; xr[1](0) = (double)(i1+1)/hoplotn; xr[1](1) = (double)(j1+1)/hoplotn; xr[2](0) = (double) i1/hoplotn; xr[2](1) = (double)(j1+1)/hoplotn; }; for (int l=0; l<3; l++) { Mat<3,3> dxdxi; xr[l](2) = (double) trig; curv.CalcElementTransformation (xr[l], i-1, xg, dxdxi); for (int i = 0; i < 3; i++) { dx(i) = dxdxi(i,0); dy(i) = dxdxi(i,1); dz(i) = dxdxi(i,2); } Vec<3> d0 = x0(0)*dx + x0(1)*dy + x0(2)*dz; Vec<3> d1 = x1(0)*dx + x1(1)*dy + x1(2)*dz; n = Cross (d1, d0); glNormal3d (n(0), n(1), n(2)); glVertex3d (xg(0), xg(1), xg(2)); } } } glEnd (); glBegin (GL_QUADS); for (int quad = 0; quad<3; quad++) { const Point3d * facepoint = MeshTopology :: GetVertices (PRISM); Vec<3> x0,x1; int xyz; switch (quad) { case 0: x0 = facepoint[5] - facepoint[2]; x1 = facepoint[0] - facepoint[2]; xyz = 0; break; case 1: x0 = facepoint[4] - facepoint[0]; x1 = facepoint[1] - facepoint[0]; xyz = 0; break; case 2: x0 = facepoint[1] - facepoint[2]; x1 = facepoint[5] - facepoint[2]; xyz = 1; break; } x0.Normalize(); x1.Normalize(); swap (x0,x1); Point<3> xr[4]; Point<3> xg; Vec<3> dx, dy, dz, n; for (int i1 = 0; i1 < hoplotn; i1++) for (int j1 = 0; j1 < hoplotn; j1++) { xr[0](xyz) = (double) i1/hoplotn; xr[0](2) = (double) j1/hoplotn; xr[1](xyz) = (double)(i1+1)/hoplotn; xr[1](2) = (double) j1/hoplotn; xr[2](xyz) = (double)(i1+1)/hoplotn; xr[2](2) = (double)(j1+1)/hoplotn; xr[3](xyz) = (double) i1/hoplotn; xr[3](2) = (double)(j1+1)/hoplotn; for (int l=0; l<4; l++) { switch (quad) { case 0: xr[l](1) = 0; break; case 1: xr[l](1) = 1-xr[l](0); break; case 2: xr[l](0) = 0; break; } Mat<3,3> dxdxi; curv.CalcElementTransformation (xr[l], i-1, xg, dxdxi); for (int i = 0; i < 3; i++) { dx(i) = dxdxi(i,0); dy(i) = dxdxi(i,1); dz(i) = dxdxi(i,2); } Vec<3> d0 = x0(0)*dx + x0(1)*dy + x0(2)*dz; Vec<3> d1 = x1(0)*dx + x1(1)*dy + x1(2)*dz; n = Cross (d1, d0); glNormal3d (n(0), n(1), n(2)); glVertex3d (xg(0), xg(1), xg(2)); } } } glEnd (); */ } else { Point3d c(0,0,0); if (vispar.shrink < 1) { for (j = 1; j <= 6; j++) { Point3d p = mesh->Point(el.PNum(j)); c.X() += p.X() / 6; c.Y() += p.Y() / 6; c.Z() += p.Z() / 6; } } el.GetSurfaceTriangles (faces); glBegin (GL_TRIANGLES); for (j = 1; j <= faces.Size(); j++) { Element2d & face = faces.Elem(j); Point3d lp1 = mesh->Point (el.PNum(face.PNum(1))); Point3d lp2 = mesh->Point (el.PNum(face.PNum(2))); Point3d lp3 = mesh->Point (el.PNum(face.PNum(3))); Vec3d n = Cross (Vec3d (lp1, lp3), Vec3d (lp1, lp2)); n /= (n.Length()+1e-12); glNormal3d (n.X(), n.Y(), n.Z()); if (vispar.shrink < 1) { lp1 = c + vispar.shrink * (lp1 - c); lp2 = c + vispar.shrink * (lp2 - c); lp3 = c + vispar.shrink * (lp3 - c); } glVertex3d (lp1.X(), lp1.Y(), lp1.Z()); glVertex3d (lp2.X(), lp2.Y(), lp2.Z()); glVertex3d (lp3.X(), lp3.Y(), lp3.Z()); } glEnd(); } } } glEndList (); } void VisualSceneMesh :: BuildHexList() { shared_ptr mesh = GetMesh(); if (hextimestamp > mesh->GetTimeStamp () && hextimestamp > vispar.clipping.timestamp ) return; if (!lock) { lock = new NgLock (mesh->Mutex()); lock -> Lock(); } hextimestamp = NextTimeStamp(); if (hexlist) glDeleteLists (hexlist, 1); hexlist = glGenLists (1); glNewList (hexlist, GL_COMPILE); static float hexcol[] = { 1.0f, 1.0f, 0.0f, 1.0f }; glLineWidth (1.0f); glMaterialfv(GL_FRONT, GL_AMBIENT_AND_DIFFUSE, hexcol); Array faces; // int hoplotn = 1 << vispar.subdivisions; for (ElementIndex ei = 0; ei < mesh->GetNE(); ei++) { const Element & el = (*mesh)[ei]; if (el.GetType() == HEX && !el.IsDeleted()) { CurvedElements & curv = mesh->GetCurvedElements(); if (curv.IsHighOrder()) // && curv.IsElementCurved(ei)) { /* // classical glBegin (GL_QUADS); const ELEMENT_FACE * faces = MeshTopology :: GetFaces (HEX); const Point3d * vertices = MeshTopology :: GetVertices (HEX); Point<3> grid[33][33]; Vec<3> gridn[33][33]; Point<3> fpts[4]; for (int quad = 0; quad<6; quad++) { for (int j = 0; j < 4; j++) fpts[j] = vertices[faces[quad][j]-1]; static Point<3> c(0.5, 0.5, 0.5); if (vispar.shrink < 1) for (int j = 0; j < 4; j++) fpts[j] += (1-vispar.shrink) * (c-fpts[j]); Vec<3> taux = fpts[1]-fpts[0]; Vec<3> tauy = fpts[3]-fpts[0]; for (int ix = 0; ix <= hoplotn; ix++) for (int iy = 0; iy <= hoplotn; iy++) { Point<3> xl; Mat<3,3> dxdxi; double lami[4] = { (1-double(ix)/hoplotn) * (1-double(iy)/hoplotn), ( double(ix)/hoplotn) * (1-double(iy)/hoplotn), ( double(ix)/hoplotn) * ( double(iy)/hoplotn), (1-double(ix)/hoplotn) * ( double(iy)/hoplotn) }; for (int l = 0; l < 3; l++) xl(l) = lami[0] * fpts[0](l) + lami[1] * fpts[1](l) + lami[2] * fpts[2](l) + lami[3] * fpts[3](l); curv.CalcElementTransformation (xl, ei, grid[ix][iy], dxdxi); Vec<3> gtaux = dxdxi * taux; Vec<3> gtauy = dxdxi * tauy; gridn[ix][iy] = Cross (gtauy, gtaux).Normalize(); } for (int ix = 0; ix < hoplotn; ix++) for (int iy = 0; iy < hoplotn; iy++) { glNormal3dv (gridn[ix][iy]); glVertex3dv (grid[ix][iy]); glNormal3dv (gridn[ix+1][iy]); glVertex3dv (grid[ix+1][iy]); glNormal3dv (gridn[ix+1][iy+1]); glVertex3dv (grid[ix+1][iy+1]); glNormal3dv (gridn[ix][iy+1]); glVertex3dv (grid[ix][iy+1]); } } glEnd (); */ const ELEMENT_FACE * faces = MeshTopology :: GetFaces1 (HEX); const Point3d * vertices = MeshTopology :: GetVertices (HEX); Point<3> grid[11][11]; Point<3> fpts[4]; int order = vispar.subdivisions+1; for (int quad = 0; quad<6; quad++) { for (int j = 0; j < 4; j++) fpts[j] = vertices[faces[quad][j]-1]; static Point<3> c(0.5, 0.5, 0.5); if (vispar.shrink < 1) for (int j = 0; j < 4; j++) fpts[j] += (1-vispar.shrink) * (c-fpts[j]); for (int ix = 0; ix <= order; ix++) for (int iy = 0; iy <= order; iy++) { double lami[4] = { (1-double(ix)/order) * (1-double(iy)/order), ( double(ix)/order) * (1-double(iy)/order), ( double(ix)/order) * ( double(iy)/order), (1-double(ix)/order) * ( double(iy)/order) }; Point<3> xl; for (int l = 0; l < 3; l++) xl(l) = lami[0] * fpts[0](l) + lami[1] * fpts[1](l) + lami[2] * fpts[2](l) + lami[3] * fpts[3](l); curv.CalcElementTransformation (xl, ei, grid[ix][iy]); } for (int j = 0; j <= order; j++) ToBernstein (order, &grid[j][0], &grid[0][1]-&grid[0][0]); for (int j = 0; j <= order; j++) ToBernstein (order, &grid[0][j], &grid[1][0]-&grid[0][0]); glMap2d(GL_MAP2_VERTEX_3, 0.0, 1.0, &grid[0][1](0)-&grid[0][0](0), order+1, 0.0, 1.0, &grid[1][0](0)-&grid[0][0](0), order+1, &grid[0][0](0)); glEnable(GL_MAP2_VERTEX_3); glEnable(GL_AUTO_NORMAL); glMapGrid2f(8, 0.0, 1.0, 8, 0.0, 1.0); glEvalMesh2(GL_FILL, 0, 8, 0, 8); glDisable (GL_AUTO_NORMAL); glDisable (GL_MAP2_VERTEX_3); } } else { Point3d c(0,0,0); if (vispar.shrink < 1) { for (int j = 1; j <= 8; j++) { Point3d p = mesh->Point(el.PNum(j)); c.X() += p.X(); c.Y() += p.Y(); c.Z() += p.Z(); } c.X() /= 8; c.Y() /= 8; c.Z() /= 8; } glBegin (GL_TRIANGLES); el.GetSurfaceTriangles (faces); for (int j = 1; j <= faces.Size(); j++) { Element2d & face = faces.Elem(j); Point<3> lp1 = mesh->Point (el.PNum(face.PNum(1))); Point<3> lp2 = mesh->Point (el.PNum(face.PNum(2))); Point<3> lp3 = mesh->Point (el.PNum(face.PNum(3))); Vec<3> n = Cross (lp3-lp1, lp2-lp1); n.Normalize(); glNormal3dv (n); if (vispar.shrink < 1) { lp1 = c + vispar.shrink * (lp1 - c); lp2 = c + vispar.shrink * (lp2 - c); lp3 = c + vispar.shrink * (lp3 - c); } glVertex3dv (lp1); glVertex3dv (lp2); glVertex3dv (lp3); } glEnd(); } } } glEndList (); } void VisualSceneMesh :: BuildPyramidList() { shared_ptr mesh = GetMesh(); if (pyramidtimestamp > mesh->GetTimeStamp () && pyramidtimestamp > vispar.clipping.timestamp ) return; if (!lock) { lock = new NgLock (mesh->Mutex()); lock -> Lock(); } pyramidtimestamp = NextTimeStamp(); if (pyramidlist) glDeleteLists (pyramidlist, 1); pyramidlist = glGenLists (1); glNewList (pyramidlist, GL_COMPILE); static float pyramidcol[] = { 1.0f, 0.0f, 1.0f, 1.0f }; glMaterialfv(GL_FRONT, GL_AMBIENT_AND_DIFFUSE, pyramidcol); glLineWidth (1.0f); Array faces; for (ElementIndex ei = 0; ei < mesh->GetNE(); ei++) { const Element & el = (*mesh)[ei]; if (el.GetType() == PYRAMID && !el.IsDeleted()) { int i = ei + 1; CurvedElements & curv = mesh->GetCurvedElements(); if (curv.IsHighOrder()) // && curv.IsElementCurved(ei)) { const ELEMENT_FACE * faces = MeshTopology :: GetFaces1 (PYRAMID); const Point3d * vertices = MeshTopology :: GetVertices (PYRAMID); Point<3> grid[11][11]; Point<3> fpts[4]; int order = vispar.subdivisions+1; for (int trig = 0; trig < 4; trig++) { for (int j = 0; j < 3; j++) fpts[j] = vertices[faces[trig][j]-1]; static Point<3> c(0.375, 0.375, 0.25); if (vispar.shrink < 1) for (int j = 0; j < 3; j++) fpts[j] += (1-vispar.shrink) * (c-fpts[j]); for (int ix = 0; ix <= order; ix++) for (int iy = 0; iy <= order; iy++) { double lami[3] = { (1-double(ix)/order) * (1-double(iy)/order), ( double(ix)/order) * (1-double(iy)/order), double(iy)/order }; Point<3> xl; for (int l = 0; l < 3; l++) xl(l) = lami[0] * fpts[0](l) + lami[1] * fpts[1](l) + lami[2] * fpts[2](l); curv.CalcElementTransformation (xl, i-1, grid[ix][iy]); } for (int j = 0; j <= order; j++) ToBernstein (order, &grid[j][0], &grid[0][1]-&grid[0][0]); for (int j = 0; j <= order; j++) ToBernstein (order, &grid[0][j], &grid[1][0]-&grid[0][0]); glMap2d(GL_MAP2_VERTEX_3, 0.0, 1.0, &grid[0][1](0)-&grid[0][0](0), order+1, 0.0, 1.0, &grid[1][0](0)-&grid[0][0](0), order+1, &grid[0][0](0)); glEnable(GL_MAP2_VERTEX_3); glEnable(GL_AUTO_NORMAL); glMapGrid2f(8, 0.0, 0.999f, 8, 0.0, 1.0); glEvalMesh2(GL_FILL, 0, 8, 0, 8); glDisable (GL_AUTO_NORMAL); glDisable (GL_MAP2_VERTEX_3); } for (int quad = 4; quad < 5; quad++) { for (int j = 0; j < 4; j++) fpts[j] = vertices[faces[quad][j]-1]; static Point<3> c(0.375, 0.375, 0.25); if (vispar.shrink < 1) for (int j = 0; j < 4; j++) fpts[j] += (1-vispar.shrink) * (c-fpts[j]); for (int ix = 0; ix <= order; ix++) for (int iy = 0; iy <= order; iy++) { double lami[4] = { (1-double(ix)/order) * (1-double(iy)/order), ( double(ix)/order) * (1-double(iy)/order), ( double(ix)/order) * ( double(iy)/order), (1-double(ix)/order) * ( double(iy)/order) }; Point<3> xl; for (int l = 0; l < 3; l++) xl(l) = lami[0] * fpts[0](l) + lami[1] * fpts[1](l) + lami[2] * fpts[2](l) + lami[3] * fpts[3](l); curv.CalcElementTransformation (xl, ei, grid[ix][iy]); } for (int j = 0; j <= order; j++) ToBernstein (order, &grid[j][0], &grid[0][1]-&grid[0][0]); for (int j = 0; j <= order; j++) ToBernstein (order, &grid[0][j], &grid[1][0]-&grid[0][0]); glMap2d(GL_MAP2_VERTEX_3, 0.0, 1.0, &grid[0][1](0)-&grid[0][0](0), order+1, 0.0, 1.0, &grid[1][0](0)-&grid[0][0](0), order+1, &grid[0][0](0)); glEnable(GL_MAP2_VERTEX_3); glEnable(GL_AUTO_NORMAL); glMapGrid2f(8, 0.0, 1.0, 8, 0.0, 1.0); glEvalMesh2(GL_FILL, 0, 8, 0, 8); glDisable (GL_AUTO_NORMAL); glDisable (GL_MAP2_VERTEX_3); } /* int hoplotn = 1 << vispar.subdivisions; const ELEMENT_FACE * faces = MeshTopology :: GetFaces (PYRAMID); const Point3d * vertices = MeshTopology :: GetVertices (PYRAMID); Point<3> grid[33][33]; Vec<3> gridn[33][33]; glBegin (GL_TRIANGLES); for (int trig = 0; trig < 4; trig++) { Point<3> p0 = vertices[faces[trig][0]-1]; Point<3> p1 = vertices[faces[trig][1]-1]; Point<3> p2 = vertices[faces[trig][2]-1]; if (vispar.shrink < 1) { static Point<3> c(0.375, 0.375, 0.25); p0 = c + vispar.shrink * (p0 - c); p1 = c + vispar.shrink * (p1 - c); p2 = c + vispar.shrink * (p2 - c); } Vec<3> taux = p0-p2; Vec<3> tauy = p1-p2; Vec<3> gtaux, gtauy; Point<3> xl; Mat<3,3> dxdxi; for (int ix = 0; ix <= hoplotn; ix++) for (int iy = 0; iy <= hoplotn-ix; iy++) { for (int l = 0; l < 3; l++) xl(l) = (1-double(ix+iy)/hoplotn) * p2(l) + (double(ix)/hoplotn) * p0(l) + (double(iy)/hoplotn) * p1(l); curv.CalcElementTransformation (xl, i-1, grid[ix][iy], dxdxi); gtaux = dxdxi * taux; gtauy = dxdxi * tauy; gridn[ix][iy] = Cross (gtauy, gtaux).Normalize(); } for (int ix = 0; ix < hoplotn; ix++) for (int iy = 0; iy < hoplotn-ix; iy++) { glNormal3dv (gridn[ix][iy]); glVertex3dv (grid[ix][iy]); glNormal3dv (gridn[ix+1][iy]); glVertex3dv (grid[ix+1][iy]); glNormal3dv (gridn[ix][iy+1]); glVertex3dv (grid[ix][iy+1]); if (iy < hoplotn-ix-1) { glNormal3dv (gridn[ix][iy+1]); glVertex3dv (grid[ix][iy+1]); glNormal3dv (gridn[ix+1][iy]); glVertex3dv (grid[ix+1][iy]); glNormal3dv (gridn[ix+1][iy+1]); glVertex3dv (grid[ix+1][iy+1]); } } } glEnd (); glBegin (GL_QUADS); for (int quad = 4; quad < 5; quad++) { Point<3> p0 = vertices[faces[quad][0]-1]; Point<3> p1 = vertices[faces[quad][1]-1]; Point<3> p2 = vertices[faces[quad][2]-1]; Point<3> p3 = vertices[faces[quad][3]-1]; if (vispar.shrink < 1) { static Point<3> c(0.375, 0.375, 0.25); p0 = c + vispar.shrink * (p0 - c); p1 = c + vispar.shrink * (p1 - c); p2 = c + vispar.shrink * (p2 - c); p3 = c + vispar.shrink * (p3 - c); } Vec<3> taux = p1-p0; Vec<3> tauy = p3-p0; Vec<3> gtaux, gtauy; Point<3> xl, xg; Mat<3,3> dxdxi; for (int ix = 0; ix <= hoplotn; ix++) for (int iy = 0; iy <= hoplotn; iy++) { Point<3> xl; for (int l = 0; l < 3; l++) xl(l) = (1-double(ix)/hoplotn)*(1-double(iy)/hoplotn) * p0(l) + ( double(ix)/hoplotn)*(1-double(iy)/hoplotn) * p1(l) + ( double(ix)/hoplotn)*( double(iy)/hoplotn) * p2(l) + (1-double(ix)/hoplotn)*( double(iy)/hoplotn) * p3(l); curv.CalcElementTransformation (xl, i-1, grid[ix][iy], dxdxi); gtaux = dxdxi * taux; gtauy = dxdxi * tauy; gridn[ix][iy] = Cross (gtauy, gtaux).Normalize(); } for (int ix = 0; ix < hoplotn; ix++) for (int iy = 0; iy < hoplotn; iy++) { glNormal3dv (gridn[ix][iy]); glVertex3dv (grid[ix][iy]); glNormal3dv (gridn[ix+1][iy]); glVertex3dv (grid[ix+1][iy]); glNormal3dv (gridn[ix+1][iy+1]); glVertex3dv (grid[ix+1][iy+1]); glNormal3dv (gridn[ix][iy+1]); glVertex3dv (grid[ix][iy+1]); } } glEnd (); */ } else { Point3d c(0,0,0); if (vispar.shrink < 1) { for (int j = 1; j <= 5; j++) { Point3d p = mesh->Point(el.PNum(j)); c.X() += p.X() / 5; c.Y() += p.Y() / 5; c.Z() += p.Z() / 5; } } el.GetSurfaceTriangles (faces); if (el.PNum(1)) { glBegin (GL_TRIANGLES); for (int j = 1; j <= faces.Size(); j++) { Element2d & face = faces.Elem(j); Point3d lp1 = mesh->Point (el.PNum(face.PNum(1))); Point3d lp2 = mesh->Point (el.PNum(face.PNum(2))); Point3d lp3 = mesh->Point (el.PNum(face.PNum(3))); Vec3d n = Cross (Vec3d (lp1, lp2), Vec3d (lp1, lp3)); n /= (n.Length()+1e-12); n *= -1; glNormal3d (n.X(), n.Y(), n.Z()); if (vispar.shrink < 1) { lp1 = c + vispar.shrink * (lp1 - c); lp2 = c + vispar.shrink * (lp2 - c); lp3 = c + vispar.shrink * (lp3 - c); } glVertex3d (lp1.X(), lp1.Y(), lp1.Z()); glVertex3d (lp2.X(), lp2.Y(), lp2.Z()); glVertex3d (lp3.X(), lp3.Y(), lp3.Z()); } glEnd(); } } } } glEndList (); } void VisualSceneMesh :: BuildBadelList() { ; } void VisualSceneMesh :: BuildIdentifiedList() { ; } void VisualSceneMesh :: BuildDomainSurfList() { shared_ptr mesh = GetMesh(); if (domainsurflist) glDeleteLists (domainsurflist, 1); domainsurflist = glGenLists (1); glNewList (domainsurflist, GL_COMPILE); int i, j; glLineWidth (1.0f); glDisable (GL_COLOR_MATERIAL); for (i = 1; i <= mesh->GetNSE(); i++) { Element2d el = mesh->SurfaceElement (i); int drawel = 1; for (j = 1; j <= el.GetNP(); j++) { if (!el.PNum(j)) drawel = 0; } if (!drawel) continue; if (el.GetIndex() < 1 || el.GetIndex() > mesh->GetNFD()) continue; int domin = mesh->GetFaceDescriptor(el.GetIndex()).DomainIn(); int domout = mesh->GetFaceDescriptor(el.GetIndex()).DomainOut(); int fac; if (domin == vispar.drawdomainsurf) fac = 1; else if (domout == vispar.drawdomainsurf) fac = -1; else continue; GLfloat matcol[] = { 1, 0, 0, 1 }; glMaterialfv(GL_FRONT, GL_AMBIENT_AND_DIFFUSE, matcol); if (el.GetNP() == 3) { glBegin (GL_TRIANGLES); const Point3d & lp1 = mesh->Point (el.PNum(1)); const Point3d & lp2 = mesh->Point (el.PNum(2)); const Point3d & lp3 = mesh->Point (el.PNum(3)); Vec3d n = Cross (Vec3d (lp1, lp2), Vec3d (lp1, lp3)); n /= ( fac * (n.Length()+1e-12)); glNormal3d (n.X(), n.Y(), n.Z()); if (!vispar.colormeshsize) { glVertex3d (lp1.X(), lp1.Y(), lp1.Z()); glVertex3d (lp2.X(), lp2.Y(), lp2.Z()); glVertex3d (lp3.X(), lp3.Y(), lp3.Z()); } glEnd(); } else if (el.GetNP() == 4) { glBegin (GL_QUADS); const Point3d & lp1 = mesh->Point (el.PNum(1)); const Point3d & lp2 = mesh->Point (el.PNum(2)); const Point3d & lp3 = mesh->Point (el.PNum(4)); const Point3d & lp4 = mesh->Point (el.PNum(3)); Vec3d n = Cross (Vec3d (lp1, lp2), Vec3d (lp1, Center (lp3, lp4))); n /= (fac * (n.Length()+1e-12)); glNormal3d (n.X(), n.Y(), n.Z()); glVertex3d (lp1.X(), lp1.Y(), lp1.Z()); glVertex3d (lp2.X(), lp2.Y(), lp2.Z()); glVertex3d (lp4.X(), lp4.Y(), lp4.Z()); glVertex3d (lp3.X(), lp3.Y(), lp3.Z()); glEnd(); } else if (el.GetNP() == 6) { glBegin (GL_TRIANGLES); static int trigs[4][3] = { { 1, 6, 5 }, { 2, 4, 6 }, { 3, 5, 4 }, { 4, 5, 6 } }; for (j = 0; j < 4; j++) { const Point3d & lp1 = mesh->Point (el.PNum(trigs[j][0])); const Point3d & lp2 = mesh->Point (el.PNum(trigs[j][1])); const Point3d & lp3 = mesh->Point (el.PNum(trigs[j][2])); Vec3d n = Cross (Vec3d (lp1, lp2), Vec3d (lp1, lp3)); n /= (fac * (n.Length() + 1e-12)); glNormal3d (n.X(), n.Y(), n.Z()); glVertex3d (lp1.X(), lp1.Y(), lp1.Z()); glVertex3d (lp2.X(), lp2.Y(), lp2.Z()); glVertex3d (lp3.X(), lp3.Y(), lp3.Z()); } glEnd(); } } glEndList (); } void VisualSceneMesh :: MouseDblClick (int px, int py) { shared_ptr mesh = GetMesh(); BuildFilledList (true); MouseDblClickSelect(px,py,clipplane,backcolor,transformationmat,center,rad, filledlist,selelement,selface,seledge,selpoint,selpoint2,locpi); GLdouble /* modelview[16], */ projection[16]; GLint viewport[4]; GLdouble result[3]; glGetDoublev(GL_PROJECTION_MATRIX, &projection[0]); glGetIntegerv(GL_VIEWPORT, &viewport[0]); int hy = viewport[3]-py; GLfloat pz; // cout << "x, y = " << px << ", " << hy << endl; glReadPixels (px, hy, 1, 1, GL_DEPTH_COMPONENT, GL_FLOAT, &pz); cout << "pz = " << pz << endl; gluUnProject(px, hy, pz, transformationmat, projection, viewport, &result[0], &result[1], &result[2]); if (pz < 1.0) cout << "point : " << result[0] << ", " << result[1] << ", " << result[2] << endl; if (user_me_handler && pz < 1.0) { if (selelement != -1) user_me_handler -> DblClick (selelement-1, result[0], result[1], result[2]); } selecttimestamp = NextTimeStamp(); if(lock) { lock->UnLock(); delete lock; lock = NULL; } /* int i, hits; // select surface triangle by mouse click GLuint selbuf[10000]; glSelectBuffer (10000, selbuf); glRenderMode (GL_SELECT); GLint viewport[4]; glGetIntegerv (GL_VIEWPORT, viewport); glMatrixMode (GL_PROJECTION); glPushMatrix(); GLdouble projmat[16]; glGetDoublev (GL_PROJECTION_MATRIX, projmat); glLoadIdentity(); gluPickMatrix (px, viewport[3] - py, 1, 1, viewport); glMultMatrixd (projmat); glClearColor(backcolor, backcolor, backcolor, 1.0); glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT); glMatrixMode (GL_MODELVIEW); glPushMatrix(); glMultMatrixf (transformationmat); // SetClippingPlane(); glInitNames(); glPushName (1); glPolygonOffset (1, 1); glEnable (GL_POLYGON_OFFSET_FILL); glDisable(GL_CLIP_PLANE0); if (vispar.clipenable) { Vec<3> n(clipplane[0], clipplane[1], clipplane[2]); double len = Abs(n); double mu = -clipplane[3] / (len*len); Point<3> p (mu * n); n /= len; Vec<3> t1 = n.GetNormal (); Vec<3> t2 = Cross (n, t1); double xi1mid = (center - p) * t1; double xi2mid = (center - p) * t2; glLoadName (0); glBegin (GL_QUADS); glVertex3dv (p + (xi1mid-rad) * t1 + (xi2mid-rad) * t2); glVertex3dv (p + (xi1mid+rad) * t1 + (xi2mid-rad) * t2); glVertex3dv (p + (xi1mid+rad) * t1 + (xi2mid+rad) * t2); glVertex3dv (p + (xi1mid-rad) * t1 + (xi2mid+rad) * t2); glEnd (); } // SetClippingPlane(); glCallList (filledlist); glDisable (GL_POLYGON_OFFSET_FILL); glPopName(); glMatrixMode (GL_PROJECTION); glPopMatrix(); glMatrixMode (GL_MODELVIEW); glPopMatrix(); glFlush(); hits = glRenderMode (GL_RENDER); // cout << "hits = " << hits << endl; int minname = 0; GLuint mindepth = 0; // find clippingplane GLuint clipdepth = 0; // GLuint(-1); for (i = 0; i < hits; i++) { int curname = selbuf[4*i+3]; if (!curname) clipdepth = selbuf[4*i+1]; } for (i = 0; i < hits; i++) { int curname = selbuf[4*i+3]; GLuint curdepth = selbuf[4*i+1]; if (curname && (curdepth > clipdepth) && (curdepth < mindepth || !minname)) { mindepth = curdepth; minname = curname; } } seledge = -1; if (minname) { const Element2d & sel = mesh->SurfaceElement(minname); cout << "select element " << minname << " on face " << sel.GetIndex() << endl; cout << "Nodes: "; for (i = 1; i <= sel.GetNP(); i++) cout << sel.PNum(i) << " "; cout << endl; selelement = minname; selface = mesh->SurfaceElement(minname).GetIndex(); locpi = (locpi % sel.GetNP()) + 1; selpoint2 = selpoint; selpoint = sel.PNum(locpi); cout << "selected point " << selpoint << ", pos = " << mesh->Point (selpoint) << endl; for (i = 1; i <= mesh->GetNSeg(); i++) { const Segment & seg = mesh->LineSegment(i); if (seg[0] == selpoint && seg[1] == selpoint2 || seg[1] == selpoint && seg[0] == selpoint2) { seledge = seg.edgenr; cout << "seledge = " << seledge << endl; } } } else { selface = -1; selelement = -1; selpoint = -1; selpoint2 = -1; } glDisable(GL_CLIP_PLANE0); selecttimestamp = NextTimeStamp(); */ } void MouseDblClickSelect (const int px, const int py, const GLdouble * clipplane, const GLdouble backcolor, const double * transformationmat, const Point3d & center, const double rad, const int displaylist, int & selelement, int & selface, int & seledge, PointIndex & selpoint, PointIndex & selpoint2, int & locpi) { auto mesh = vsmesh.GetMesh(); int i, hits; // select surface triangle by mouse click GLuint selbuf[10000]; glSelectBuffer (10000, selbuf); glRenderMode (GL_SELECT); GLint viewport[4]; glGetIntegerv (GL_VIEWPORT, viewport); glMatrixMode (GL_PROJECTION); glPushMatrix(); GLdouble projmat[16]; glGetDoublev (GL_PROJECTION_MATRIX, projmat); glLoadIdentity(); gluPickMatrix (px, viewport[3] - py, 1, 1, viewport); glMultMatrixd (projmat); glClearColor(backcolor, backcolor, backcolor, 1.0); glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT); glMatrixMode (GL_MODELVIEW); glPushMatrix(); glMultMatrixd (transformationmat); // SetClippingPlane(); glInitNames(); glPushName (1); glPolygonOffset (1, 1); glEnable (GL_POLYGON_OFFSET_FILL); glDisable(GL_CLIP_PLANE0); if (vispar.clipping.enable) { Vec<3> n(clipplane[0], clipplane[1], clipplane[2]); double len = Abs(n); double mu = -clipplane[3] / (len*len); Point<3> p (mu * n); n /= len; Vec<3> t1 = n.GetNormal (); Vec<3> t2 = Cross (n, t1); double xi1mid = (center - p) * t1; double xi2mid = (center - p) * t2; glLoadName (0); glBegin (GL_QUADS); glVertex3dv (p + (xi1mid-rad) * t1 + (xi2mid-rad) * t2); glVertex3dv (p + (xi1mid+rad) * t1 + (xi2mid-rad) * t2); glVertex3dv (p + (xi1mid+rad) * t1 + (xi2mid+rad) * t2); glVertex3dv (p + (xi1mid-rad) * t1 + (xi2mid+rad) * t2); glEnd (); } // SetClippingPlane(); glCallList (displaylist); glDisable (GL_POLYGON_OFFSET_FILL); glPopName(); glMatrixMode (GL_PROJECTION); glPopMatrix(); glMatrixMode (GL_MODELVIEW); glPopMatrix(); glFlush(); hits = glRenderMode (GL_RENDER); //cout << "hits = " << hits << endl; int minname = 0; GLuint mindepth = 0; // find clippingplane GLuint clipdepth = 0; // GLuint(-1); for (i = 0; i < hits; i++) { int curname = selbuf[4*i+3]; if (!curname) clipdepth = selbuf[4*i+1]; } for (i = 0; i < hits; i++) { int curname = selbuf[4*i+3]; GLuint curdepth = selbuf[4*i+1]; /* cout << selbuf[4*i] << " " << selbuf[4*i+1] << " " << selbuf[4*i+2] << " " << selbuf[4*i+3] << endl; */ if (curname && (curdepth > clipdepth) && (curdepth < mindepth || !minname)) { mindepth = curdepth; minname = curname; } } seledge = -1; if (minname) { const Element2d & sel = mesh->SurfaceElement(minname); cout << "select element " << minname << " on face " << sel.GetIndex() << endl; cout << "Nodes: "; for (i = 1; i <= sel.GetNP(); i++) cout << sel.PNum(i) << " "; cout << endl; selelement = minname; selface = mesh->SurfaceElement(minname).GetIndex(); locpi = (locpi % sel.GetNP()) + 1; selpoint2 = selpoint; selpoint = sel.PNum(locpi); cout << "selected point " << selpoint << ", pos = " << mesh->Point (selpoint) << endl; for (i = 1; i <= mesh->GetNSeg(); i++) { const Segment & seg = mesh->LineSegment(i); if ( (seg[0] == selpoint && seg[1] == selpoint2) || (seg[1] == selpoint && seg[0] == selpoint2) ) { seledge = seg.edgenr; cout << "seledge = " << seledge << endl; } } } else { selface = -1; selelement = -1; selpoint = -1; selpoint2 = -1; } glDisable(GL_CLIP_PLANE0); #ifdef PARALLELGL vsmesh.Broadcast (); #endif } void VisualSceneMesh :: SetSelectedFace (int asf) { selface = asf; selecttimestamp = NextTimeStamp(); } } #ifdef NG_PYTHON #include <../general/ngpython.hpp> DLL_HEADER void ExportMeshVis(py::module &m) { using namespace netgen; vispar.drawcolorbar = true; vispar.drawnetgenlogo = true; vispar.drawcoordinatecross = true; vispar.drawfilledtrigs = true; vispar.drawdomainsurf = true; vispar.drawhexes = true; vispar.drawtets = true; vispar.drawprisms = true; vispar.drawoutline = true; py::class_> (m, "VisualSceneMesh") .def("Draw", &VisualSceneMesh::DrawScene) ; m.def("VS", FunctionPointer ([](shared_ptr mesh) { auto vs = make_shared(); // vs->SetMesh(mesh); SetGlobalMesh (mesh); return vs; })); m.def("MouseMove", FunctionPointer ([](VisualSceneMesh &vsmesh, int oldx, int oldy, int newx, int newy, char mode) { vsmesh.MouseMove(oldx, oldy, newx, newy, mode); })); m.def("SelectFace", FunctionPointer ([] (int facenr) { vsmesh.SetSelectedFace(facenr); })); m.def("GetGlobalMesh", FunctionPointer ([] () { return vsmesh.GetMesh(); })); } // BOOST_PYTHON_MODULE(libvisual) // { // ExportMeshVis(); // } #endif