13 #include "../fem/fem.hpp" 14 #include "../general/text.hpp" 18 #if defined(_MSC_VER) && (_MSC_VER < 1800) 20 #define copysign _copysign 32 input >> Order >> NumOfControlPoints;
33 knot.Load(input, NumOfControlPoints + Order + 1);
40 NumOfControlPoints = NCP;
41 knot.SetSize(NumOfControlPoints + Order + 1);
63 " Parent KnotVector order higher than child");
66 const int nOrder = Order +
t;
69 for (
int i = 0; i <= nOrder; i++)
71 (*newkv)[i] = knot(0);
73 for (
int i = nOrder + 1; i < newkv->
GetNCP(); i++)
75 (*newkv)[i] = knot(i -
t);
77 for (
int i = 0; i <= nOrder; i++)
79 (*newkv)[newkv->
GetNCP() + i] = knot(knot.Size()-1);
89 newknots.
SetSize(NumOfElements);
91 for (
int i = 0; i < knot.Size()-1; i++)
93 if (knot(i) != knot(i+1))
95 newknots(j) = 0.5*(knot(i) + knot(i+1));
104 for (
int i = Order; i < NumOfControlPoints; i++)
106 if (knot(i) != knot(i+1))
115 double apb = knot(0) + knot(knot.Size()-1);
117 int ns = (NumOfControlPoints - Order)/2;
118 for (
int i = 1; i <= ns; i++)
120 double tmp = apb - knot(Order + i);
121 knot(Order + i) = apb - knot(NumOfControlPoints - i);
122 knot(NumOfControlPoints - i) = tmp;
128 os << Order <<
' ' << NumOfControlPoints <<
' ';
129 knot.Print(os, knot.Size());
137 double x, dx = 1.0/double (samples - 1);
139 for (
int i = 0; i <GetNE() ; i++)
141 for (
int j = 0; j <samples; j++)
146 CalcShape ( shape, i, x);
147 for (
int d = 0; d < Order+1; d++) { os<<
"\t"<<shape[d]; }
149 CalcDShape ( shape, i, x);
150 for (
int d = 0; d < Order+1; d++) { os<<
"\t"<<shape[d]; }
152 CalcD2Shape ( shape, i, x);
153 for (
int d = 0; d < Order+1; d++) { os<<
"\t"<<shape[d]; }
162 MFEM_ASSERT(Order <= MaxOrder, "Order > MaxOrder!
"); 165 int ip = (i >= 0) ? (i + p) : (-1 - i + p); 166 double u = getKnotLocation((i >= 0) ? xi : 1. - xi, ip), saved, tmp; 167 double left[MaxOrder+1], right[MaxOrder+1]; 170 for (int j = 1; j <= p; ++j) 172 left[j] = u - knot(ip+1-j); 173 right[j] = knot(ip+j) - u; 175 for (int r = 0; r < j; ++r) 177 tmp = shape(r)/(right[r+1] + left[j-r]); 178 shape(r) = saved + right[r+1]*tmp; 179 saved = left[j-r]*tmp; 185 // Routine from "The NURBS book
" - 2nd ed - Piegl and Tiller 186 void KnotVector::CalcDShape(Vector &grad, int i, double xi) const 188 int p = Order, rk, pk; 189 int ip = (i >= 0) ? (i + p) : (-1 - i + p); 190 double u = getKnotLocation((i >= 0) ? xi : 1. - xi, ip), temp, saved, d; 191 double ndu[MaxOrder+1][MaxOrder+1], left[MaxOrder+1], right[MaxOrder+1]; 201 for (int j = 1; j <= p; j++) 203 left[j] = u - knot(ip-j+1); 204 right[j] = knot(ip+j) - u; 206 for (int r = 0; r < j; r++) 208 ndu[j][r] = right[r+1] + left[j-r]; 209 temp = ndu[r][j-1]/ndu[j][r]; 210 ndu[r][j] = saved + right[r+1]*temp; 211 saved = left[j-r]*temp; 216 for (int r = 0; r <= p; ++r) 223 d = ndu[rk][pk]/ndu[p][rk]; 227 d -= ndu[r][pk]/ndu[p][r]; 234 grad *= p*(knot(ip+1) - knot(ip)); 238 grad *= p*(knot(ip) - knot(ip+1)); 242 // Routine from "The NURBS book
" - 2nd ed - Piegl and Tiller 243 void KnotVector::CalcDnShape(Vector &gradn, int n, int i, double xi) const 245 int p = Order, rk, pk, j1, j2,r,j,k; 246 int ip = (i >= 0) ? (i + p) : (-1 - i + p); 247 double u = getKnotLocation((i >= 0) ? xi : 1. - xi, ip); 248 double temp, saved, d; 249 double a[2][MaxOrder+1],ndu[MaxOrder+1][MaxOrder+1], left[MaxOrder+1], 260 for (j = 1; j <= p; j++) 262 left[j] = u - knot(ip-j+1); 263 right[j] = knot(ip+j)- u; 266 for (r = 0; r < j; r++) 268 ndu[j][r] = right[r+1] + left[j-r]; 269 temp = ndu[r][j-1]/ndu[j][r]; 270 ndu[r][j] = saved + right[r+1]*temp; 271 saved = left[j-r]*temp; 276 for (r = 0; r <= p; r++) 281 for (k = 1; k <= n; k++) 288 a[s2][0] = a[s1][0]/ndu[pk+1][rk]; 289 d = a[s2][0]*ndu[rk][pk]; 310 for (j = j1; j <= j2; j++) 312 a[s2][j] = (a[s1][j] - a[s1][j-1])/ndu[pk+1][rk+j]; 313 d += a[s2][j]*ndu[rk+j][pk]; 318 a[s2][k] = - a[s1][k-1]/ndu[pk+1][r]; 319 d += a[s2][j]*ndu[rk+j][pk]; 330 u = (knot(ip+1) - knot(ip)); 334 u = (knot(ip) - knot(ip+1)); 338 for (k = 1; k <= n-1; k++) { temp *= (p-k)*u; } 340 for (j = 0; j <= p; j++) { gradn[j] *= temp; } 345 int KnotVector::findKnotSpan(double u) const 349 if (u == knot(NumOfControlPoints+Order)) 351 mid = NumOfControlPoints; 356 high = NumOfControlPoints + 1; 357 mid = (low + high)/2; 358 while ( (u < knot(mid-1)) || (u > knot(mid)) ) 368 mid = (low + high)/2; 374 void KnotVector::Difference(const KnotVector &kv, Vector &diff) const 376 if (Order != kv.GetOrder()) 379 " Can not compare knot vectors with different orders!
"); 382 int s = kv.Size() - Size(); 385 kv.Difference(*this, diff); 393 for (int j = 0; j < kv.Size(); j++) 395 if (knot(i) == kv[j]) 407 void NURBSPatch::init(int dim_) 414 ni = kv[0]->GetNCP(); 415 nj = kv[1]->GetNCP(); 418 data = new double[ni*nj*Dim]; 421 for (int i = 0; i < ni*nj*Dim; i++) 427 else if (kv.Size() == 3) 429 ni = kv[0]->GetNCP(); 430 nj = kv[1]->GetNCP(); 431 nk = kv[2]->GetNCP(); 433 data = new double[ni*nj*nk*Dim]; 436 for (int i = 0; i < ni*nj*nk*Dim; i++) 448 NURBSPatch::NURBSPatch(const NURBSPatch &orig) 449 : ni(orig.ni), nj(orig.nj), nk(orig.nk), Dim(orig.Dim), 450 data(NULL), kv(orig.kv.Size()), sd(orig.sd), nd(orig.nd) 452 // Allocate and copy data: 453 const int data_size = Dim*ni*nj*((kv.Size() == 2) ? 1 : nk); 454 data = new double[data_size]; 455 std::memcpy(data, orig.data, data_size*sizeof(double)); 457 // Copy the knot vectors: 458 for (int i = 0; i < kv.Size(); i++) 460 kv[i] = new KnotVector(*orig.kv[i]); 464 NURBSPatch::NURBSPatch(std::istream &input) 466 int pdim, dim, size = 1; 469 input >> ws >> ident >> pdim; // knotvectors 471 for (int i = 0; i < pdim; i++) 473 kv[i] = new KnotVector(input); 474 size *= kv[i]->GetNCP(); 477 input >> ws >> ident >> dim; // dimension 480 input >> ws >> ident; // controlpoints (homogeneous coordinates) 481 if (ident == "controlpoints
" || ident == "controlpoints_homogeneous
") 483 for (int j = 0, i = 0; i < size; i++) 484 for (int d = 0; d <= dim; d++, j++) 489 else // "controlpoints_cartesian
" (Cartesian coordinates with weight) 491 for (int j = 0, i = 0; i < size; i++) 493 for (int d = 0; d <= dim; d++) 497 for (int d = 0; d < dim; d++) 499 data[j+d] *= data[j+dim]; 506 NURBSPatch::NURBSPatch(const KnotVector *kv0, const KnotVector *kv1, int dim_) 509 kv[0] = new KnotVector(*kv0); 510 kv[1] = new KnotVector(*kv1); 514 NURBSPatch::NURBSPatch(const KnotVector *kv0, const KnotVector *kv1, 515 const KnotVector *kv2, int dim_) 518 kv[0] = new KnotVector(*kv0); 519 kv[1] = new KnotVector(*kv1); 520 kv[2] = new KnotVector(*kv2); 524 NURBSPatch::NURBSPatch(Array<const KnotVector *> &kv_, int dim_) 526 kv.SetSize(kv_.Size()); 527 for (int i = 0; i < kv.Size(); i++) 529 kv[i] = new KnotVector(*kv_[i]); 534 NURBSPatch::NURBSPatch(NURBSPatch *parent, int dir, int Order, int NCP) 536 kv.SetSize(parent->kv.Size()); 537 for (int i = 0; i < kv.Size(); i++) 540 kv[i] = new KnotVector(*parent->kv[i]); 544 kv[i] = new KnotVector(Order, NCP); 549 void NURBSPatch::swap(NURBSPatch *np) 556 for (int i = 0; i < kv.Size(); i++) 558 if (kv[i]) { delete kv[i]; } 575 NURBSPatch::~NURBSPatch() 582 for (int i = 0; i < kv.Size(); i++) 584 if (kv[i]) { delete kv[i]; } 588 void NURBSPatch::Print(std::ostream &os) const 592 os << "knotvectors\n
" << kv.Size() << '\n'; 593 for (int i = 0; i < kv.Size(); i++) 596 size *= kv[i]->GetNCP(); 599 os << "\ndimension\n
" << Dim - 1 600 << "\n\ncontrolpoints\n
"; 601 for (int j = 0, i = 0; i < size; i++) 604 for (int d = 1; d < Dim; d++) 606 os << ' ' << data[j++]; 612 int NURBSPatch::SetLoopDirection(int dir) 633 " Direction error in 2D patch, dir =
" << dir << '\n'; 663 " Direction error in 3D patch, dir =
" << dir << '\n'; 671 void NURBSPatch::UniformRefinement() 674 for (int dir = 0; dir < kv.Size(); dir++) 676 kv[dir]->UniformRefinement(newknots); 677 KnotInsert(dir, newknots); 681 void NURBSPatch::KnotInsert(Array<KnotVector *> &newkv) 683 for (int dir = 0; dir < kv.Size(); dir++) 685 KnotInsert(dir, *newkv[dir]); 689 void NURBSPatch::KnotInsert(int dir, const KnotVector &newkv) 691 if (dir >= kv.Size() || dir < 0) 696 int t = newkv.GetOrder() - kv[dir]->GetOrder(); 700 DegreeElevate(dir, t); 708 GetKV(dir)->Difference(newkv, diff); 711 KnotInsert(dir, diff); 715 void NURBSPatch::KnotInsert(Array<Vector *> &newkv) 717 for (int dir = 0; dir < kv.Size(); dir++) 719 KnotInsert(dir, *newkv[dir]); 723 // Routine from "The NURBS book
" - 2nd ed - Piegl and Tiller 724 void NURBSPatch::KnotInsert(int dir, const Vector &knot) 726 if (knot.Size() == 0 ) { return; } 728 if (dir >= kv.Size() || dir < 0) 733 NURBSPatch &oldp = *this; 734 KnotVector &oldkv = *kv[dir]; 736 NURBSPatch *newpatch = new NURBSPatch(this, dir, oldkv.GetOrder(), 737 oldkv.GetNCP() + knot.Size()); 738 NURBSPatch &newp = *newpatch; 739 KnotVector &newkv = *newp.GetKV(dir); 741 int size = oldp.SetLoopDirection(dir); 742 if (size != newp.SetLoopDirection(dir)) 747 int rr = knot.Size() - 1; 748 int a = oldkv.findKnotSpan(knot(0)) - 1; 749 int b = oldkv.findKnotSpan(knot(rr)) - 1; 750 int pl = oldkv.GetOrder(); 751 int ml = oldkv.GetNCP(); 753 for (int j = 0; j <= a; j++) 757 for (int j = b+pl; j <= ml+pl; j++) 759 newkv[j+rr+1] = oldkv[j]; 761 for (int k = 0; k <= (a-pl); k++) 763 for (int ll = 0; ll < size; ll++) 765 newp(k,ll) = oldp(k,ll); 768 for (int k = (b-1); k < ml; k++) 770 for (int ll = 0; ll < size; ll++) 772 newp(k+rr+1,ll) = oldp(k,ll); 779 for (int j = rr; j >= 0; j--) 781 while ( (knot(j) <= oldkv[i]) && (i > a) ) 784 for (int ll = 0; ll < size; ll++) 786 newp(k-pl-1,ll) = oldp(i-pl-1,ll); 793 for (int ll = 0; ll < size; ll++) 795 newp(k-pl-1,ll) = newp(k-pl,ll); 798 for (int l = 1; l <= pl; l++) 801 double alfa = newkv[k+l] - knot(j); 802 if (fabs(alfa) == 0.0) 804 for (int ll = 0; ll < size; ll++) 806 newp(ind-1,ll) = newp(ind,ll); 811 alfa = alfa/(newkv[k+l] - oldkv[i-pl+l]); 812 for (int ll = 0; ll < size; ll++) 814 newp(ind-1,ll) = alfa*newp(ind-1,ll) + (1.0-alfa)*newp(ind,ll); 828 void NURBSPatch::DegreeElevate(int t) 830 for (int dir = 0; dir < kv.Size(); dir++) 832 DegreeElevate(dir, t); 836 // Routine from "The NURBS book
" - 2nd ed - Piegl and Tiller 837 void NURBSPatch::DegreeElevate(int dir, int t) 839 if (dir >= kv.Size() || dir < 0) 844 int i, j, k, kj, mpi, mul, mh, kind, cind, first, last; 845 int r, a, b, oldr, save, s, tr, lbz, rbz, l; 846 double inv, ua, ub, numer, alf, den, bet, gam; 848 NURBSPatch &oldp = *this; 849 KnotVector &oldkv = *kv[dir]; 851 NURBSPatch *newpatch = new NURBSPatch(this, dir, oldkv.GetOrder() + t, 852 oldkv.GetNCP() + oldkv.GetNE()*t); 853 NURBSPatch &newp = *newpatch; 854 KnotVector &newkv = *newp.GetKV(dir); 856 int size = oldp.SetLoopDirection(dir); 857 if (size != newp.SetLoopDirection(dir)) 862 int p = oldkv.GetOrder(); 863 int n = oldkv.GetNCP()-1; 865 DenseMatrix bezalfs (p+t+1, p+1); 866 DenseMatrix bpts (p+1, size); 867 DenseMatrix ebpts (p+t+1, size); 868 DenseMatrix nextbpts(p-1, size); 876 Array2D<int> binom(ph+1, ph+1); 877 for (i = 0; i <= ph; i++) 879 binom(i,0) = binom(i,i) = 1; 880 for (j = 1; j < i; j++) 882 binom(i,j) = binom(i-1,j) + binom(i-1,j-1); 889 for (i = 1; i <= ph2; i++) 891 inv = 1.0/binom(ph,i); 893 for (j = max(0,i-t); j <= mpi; j++) 895 bezalfs(i,j) = inv*binom(p,j)*binom(t,i-j); 900 for (i = ph2+1; i < ph; i++) 903 for (j = max(0,i-t); j <= mpi; j++) 905 bezalfs(i,j) = bezalfs(ph-i,p-j); 916 for (l = 0; l < size; l++) 918 newp(0,l) = oldp(0,l); 920 for (i = 0; i <= ph; i++) 925 for (i = 0; i <= p; i++) 927 for (l = 0; l < size; l++) 929 bpts(i,l) = oldp(i,l); 936 while (b < m && oldkv[b] == oldkv[b+1]) { b++; } 944 if (oldr > 0) { lbz = (oldr+2)/2; } 947 if (r > 0) { rbz = ph-(r+1)/2; } 953 for (k = p ; k > mul; k--) 955 alphas[k-mul-1] = numer/(oldkv[a+k]-ua); 958 for (j = 1; j <= r; j++) 962 for (k = p; k >= s; k--) 964 for (l = 0; l < size; l++) 965 bpts(k,l) = (alphas[k-s]*bpts(k,l) + 966 (1.0-alphas[k-s])*bpts(k-1,l)); 968 for (l = 0; l < size; l++) 970 nextbpts(save,l) = bpts(p,l); 975 for (i = lbz; i <= ph; i++) 977 for (l = 0; l < size; l++) 982 for (j = max(0,i-t); j <= mpi; j++) 984 for (l = 0; l < size; l++) 986 ebpts(i,l) += bezalfs(i,j)*bpts(j,l); 996 bet = (ub-newkv[kind-1])/den; 998 for (tr = 1; tr < oldr; tr++) 1007 alf = (ub-newkv[i])/(ua-newkv[i]); 1008 for (l = 0; l < size; l++) 1010 newp(i,l) = alf*newp(i,l)-(1.0-alf)*newp(i-1,l); 1015 if ((j-tr) <= (kind-ph+oldr)) 1017 gam = (ub-newkv[j-tr])/den; 1018 for (l = 0; l < size; l++) 1020 ebpts(kj,l) = gam*ebpts(kj,l) + (1.0-gam)*ebpts(kj+1,l); 1025 for (l = 0; l < size; l++) 1027 ebpts(kj,l) = bet*ebpts(kj,l) + (1.0-bet)*ebpts(kj+1,l); 1042 for (i = 0; i < (ph-oldr); i++) 1048 for (j = lbz; j <= rbz; j++) 1050 for (l = 0; l < size; l++) 1052 newp(cind,l) = ebpts(j,l); 1059 for (j = 0; j <r; j++) 1060 for (l = 0; l < size; l++) 1062 bpts(j,l) = nextbpts(j,l); 1065 for (j = r; j <= p; j++) 1066 for (l = 0; l < size; l++) 1068 bpts(j,l) = oldp(b-p+j,l); 1077 for (i = 0; i <= ph; i++) 1083 newkv.GetElements(); 1088 void NURBSPatch::FlipDirection(int dir) 1090 int size = SetLoopDirection(dir); 1092 for (int id = 0; id < nd/2; id++) 1093 for (int i = 0; i < size; i++) 1095 Swap<double>((*this)(id,i), (*this)(nd-1-id,i)); 1100 void NURBSPatch::SwapDirections(int dir1, int dir2) 1102 if (abs(dir1-dir2) == 2) 1105 " directions 0 and 2 are not supported!
"); 1108 Array<const KnotVector *> nkv(kv); 1110 Swap<const KnotVector *>(nkv[dir1], nkv[dir2]); 1111 NURBSPatch *newpatch = new NURBSPatch(nkv, Dim); 1113 int size = SetLoopDirection(dir1); 1114 newpatch->SetLoopDirection(dir2); 1116 for (int id = 0; id < nd; id++) 1117 for (int i = 0; i < size; i++) 1119 (*newpatch)(id,i) = (*this)(id,i); 1125 void NURBSPatch::Get3DRotationMatrix(double n[], double angle, double r, 1129 double l2 = n[0]*n[0] + n[1]*n[1] + n[2]*n[2]; 1130 double l = sqrt(l2); 1132 if (fabs(angle) == M_PI_2) 1134 s = r*copysign(1., angle); 1138 else if (fabs(angle) == M_PI) 1153 T(0,0) = (n[0]*n[0] + (n[1]*n[1] + n[2]*n[2])*c)/l2; 1154 T(0,1) = -(n[0]*n[1]*c1)/l2 - (n[2]*s)/l; 1155 T(0,2) = -(n[0]*n[2]*c1)/l2 + (n[1]*s)/l; 1156 T(1,0) = -(n[0]*n[1]*c1)/l2 + (n[2]*s)/l; 1157 T(1,1) = (n[1]*n[1] + (n[0]*n[0] + n[2]*n[2])*c)/l2; 1158 T(1,2) = -(n[1]*n[2]*c1)/l2 - (n[0]*s)/l; 1159 T(2,0) = -(n[0]*n[2]*c1)/l2 - (n[1]*s)/l; 1160 T(2,1) = -(n[1]*n[2]*c1)/l2 + (n[0]*s)/l; 1161 T(2,2) = (n[2]*n[2] + (n[0]*n[0] + n[1]*n[1])*c)/l2; 1164 void NURBSPatch::Rotate3D(double n[], double angle) 1172 Vector x(3), y(NULL, 3); 1174 Get3DRotationMatrix(n, angle, 1., T); 1177 for (int i = 0; i < kv.Size(); i++) 1179 size *= kv[i]->GetNCP(); 1182 for (int i = 0; i < size; i++) 1184 y.SetData(data + i*Dim); 1190 int NURBSPatch::MakeUniformDegree(int degree) 1196 for (int dir = 0; dir < kv.Size(); dir++) 1198 maxd = std::max(maxd, kv[dir]->GetOrder()); 1202 for (int dir = 0; dir < kv.Size(); dir++) 1204 if (maxd > kv[dir]->GetOrder()) 1206 DegreeElevate(dir, maxd - kv[dir]->GetOrder()); 1213 NURBSPatch *Interpolate(NURBSPatch &p1, NURBSPatch &p2) 1215 if (p1.kv.Size() != p2.kv.Size() || p1.Dim != p2.Dim) 1220 int size = 1, dim = p1.Dim; 1221 Array<const KnotVector *> kv(p1.kv.Size() + 1); 1223 for (int i = 0; i < p1.kv.Size(); i++) 1225 if (p1.kv[i]->GetOrder() < p2.kv[i]->GetOrder()) 1227 p1.KnotInsert(i, *p2.kv[i]); 1228 p2.KnotInsert(i, *p1.kv[i]); 1232 p2.KnotInsert(i, *p1.kv[i]); 1233 p1.KnotInsert(i, *p2.kv[i]); 1236 size *= kv[i]->GetNCP(); 1239 KnotVector &nkv = *(new KnotVector(1, 2)); 1240 nkv[0] = nkv[1] = 0.0; 1241 nkv[2] = nkv[3] = 1.0; 1245 NURBSPatch *patch = new NURBSPatch(kv, dim); 1248 for (int i = 0; i < size; i++) 1250 for (int d = 0; d < dim; d++) 1252 patch->data[i*dim+d] = p1.data[i*dim+d]; 1253 patch->data[(i+size)*dim+d] = p2.data[i*dim+d]; 1260 NURBSPatch *Revolve3D(NURBSPatch &patch, double n[], double ang, int times) 1268 Array<const KnotVector *> nkv(patch.kv.Size() + 1); 1270 for (int i = 0; i < patch.kv.Size(); i++) 1272 nkv[i] = patch.kv[i]; 1273 size *= nkv[i]->GetNCP(); 1276 KnotVector &lkv = *(new KnotVector(2, ns)); 1278 lkv[0] = lkv[1] = lkv[2] = 0.0; 1279 for (int i = 1; i < times; i++) 1281 lkv[2*i+1] = lkv[2*i+2] = i; 1283 lkv[ns] = lkv[ns+1] = lkv[ns+2] = times; 1285 NURBSPatch *newpatch = new NURBSPatch(nkv, 4); 1288 DenseMatrix T(3), T2(3); 1289 Vector u(NULL, 3), v(NULL, 3); 1291 NURBSPatch::Get3DRotationMatrix(n, ang, 1., T); 1292 double c = cos(ang/2); 1293 NURBSPatch::Get3DRotationMatrix(n, ang/2, 1./c, T2); 1296 double *op = patch.data, *np; 1297 for (int i = 0; i < size; i++) 1299 np = newpatch->data + 4*i; 1300 for (int j = 0; j < 4; j++) 1304 for (int j = 0; j < times; j++) 1307 v.SetData(np += 4*size); 1310 v.SetData(np += 4*size); 1321 NURBSExtension::NURBSExtension(const NURBSExtension &orig) 1322 : mOrder(orig.mOrder), mOrders(orig.mOrders), 1323 NumOfKnotVectors(orig.NumOfKnotVectors), 1324 NumOfVertices(orig.NumOfVertices), 1325 NumOfElements(orig.NumOfElements), 1326 NumOfBdrElements(orig.NumOfBdrElements), 1327 NumOfDofs(orig.NumOfDofs), 1328 NumOfActiveVertices(orig.NumOfActiveVertices), 1329 NumOfActiveElems(orig.NumOfActiveElems), 1330 NumOfActiveBdrElems(orig.NumOfActiveBdrElems), 1331 NumOfActiveDofs(orig.NumOfActiveDofs), 1332 activeVert(orig.activeVert), 1333 activeElem(orig.activeElem), 1334 activeBdrElem(orig.activeBdrElem), 1335 activeDof(orig.activeDof), 1336 patchTopo(new Mesh(*orig.patchTopo)), 1338 edge_to_knot(orig.edge_to_knot), 1339 knotVectors(orig.knotVectors.Size()), // knotVectors are copied in the body 1340 weights(orig.weights), 1341 d_to_d(orig.d_to_d), 1342 master(orig.master), 1344 v_meshOffsets(orig.v_meshOffsets), 1345 e_meshOffsets(orig.e_meshOffsets), 1346 f_meshOffsets(orig.f_meshOffsets), 1347 p_meshOffsets(orig.p_meshOffsets), 1348 v_spaceOffsets(orig.v_spaceOffsets), 1349 e_spaceOffsets(orig.e_spaceOffsets), 1350 f_spaceOffsets(orig.f_spaceOffsets), 1351 p_spaceOffsets(orig.p_spaceOffsets), 1352 el_dof(orig.el_dof ? new Table(*orig.el_dof) : NULL), 1353 bel_dof(orig.bel_dof ? new Table(*orig.bel_dof) : NULL), 1354 el_to_patch(orig.el_to_patch), 1355 bel_to_patch(orig.bel_to_patch), 1356 el_to_IJK(orig.el_to_IJK), 1357 bel_to_IJK(orig.bel_to_IJK), 1358 patches(orig.patches.Size()) // patches are copied in the body 1360 // Copy the knot vectors: 1361 for (int i = 0; i < knotVectors.Size(); i++) 1363 knotVectors[i] = new KnotVector(*orig.knotVectors[i]); 1366 // Copy the patches: 1367 for (int p = 0; p < patches.Size(); p++) 1369 patches[p] = new NURBSPatch(*orig.patches[p]); 1373 NURBSExtension::NURBSExtension(std::istream &input) 1376 patchTopo = new Mesh; 1377 patchTopo->LoadPatchTopo(input, edge_to_knot); 1381 // CheckBdrPatches(); 1383 skip_comment_lines(input, '#'); 1385 // Read knotvectors or patches 1387 input >> ws >> ident; // 'knotvectors' or 'patches' 1388 if (ident == "knotvectors
") 1390 input >> NumOfKnotVectors; 1391 knotVectors.SetSize(NumOfKnotVectors); 1392 for (int i = 0; i < NumOfKnotVectors; i++) 1394 knotVectors[i] = new KnotVector(input); 1397 else if (ident == "patches
") 1399 patches.SetSize(GetNP()); 1400 for (int p = 0; p < patches.Size(); p++) 1402 skip_comment_lines(input, '#'); 1403 patches[p] = new NURBSPatch(input); 1406 NumOfKnotVectors = 0; 1407 for (int i = 0; i < patchTopo->GetNEdges(); i++) 1408 if (NumOfKnotVectors < KnotInd(i)) 1410 NumOfKnotVectors = KnotInd(i); 1413 knotVectors.SetSize(NumOfKnotVectors); 1416 Array<int> edges, oedge; 1417 for (int p = 0; p < patches.Size(); p++) 1419 patchTopo->GetElementEdges(p, edges, oedge); 1420 if (Dimension() == 2) 1422 if (knotVectors[KnotInd(edges[0])] == NULL) 1424 knotVectors[KnotInd(edges[0])] = 1425 new KnotVector(*patches[p]->GetKV(0)); 1427 if (knotVectors[KnotInd(edges[1])] == NULL) 1429 knotVectors[KnotInd(edges[1])] = 1430 new KnotVector(*patches[p]->GetKV(1)); 1435 if (knotVectors[KnotInd(edges[0])] == NULL) 1437 knotVectors[KnotInd(edges[0])] = 1438 new KnotVector(*patches[p]->GetKV(0)); 1440 if (knotVectors[KnotInd(edges[3])] == NULL) 1442 knotVectors[KnotInd(edges[3])] = 1443 new KnotVector(*patches[p]->GetKV(1)); 1445 if (knotVectors[KnotInd(edges[8])] == NULL) 1447 knotVectors[KnotInd(edges[8])] = 1448 new KnotVector(*patches[p]->GetKV(2)); 1455 MFEM_ABORT("invalid section:
" << ident); 1458 SetOrdersFromKnotVectors(); 1463 // NumOfVertices, NumOfElements, NumOfBdrElements, NumOfDofs 1465 skip_comment_lines(input, '#'); 1467 // Check for a list of mesh elements 1468 if (patches.Size() == 0) 1470 input >> ws >> ident; 1472 if (patches.Size() == 0 && ident == "mesh_elements
") 1474 input >> NumOfActiveElems; 1475 activeElem.SetSize(GetGNE()); 1478 for (int i = 0; i < NumOfActiveElems; i++) 1481 activeElem[glob_elem] = true; 1484 skip_comment_lines(input, '#'); 1485 input >> ws >> ident; 1489 NumOfActiveElems = NumOfElements; 1490 activeElem.SetSize(NumOfElements); 1494 GenerateActiveVertices(); 1496 GenerateElementDofTable(); 1497 GenerateActiveBdrElems(); 1498 GenerateBdrElementDofTable(); 1501 if (ident == "periodic
") 1506 skip_comment_lines(input, '#'); 1507 input >> ws >> ident; 1510 if (patches.Size() == 0) 1513 if (ident == "weights
") 1515 weights.Load(input, GetNDof()); 1517 else // e.g. ident = "unitweights
" or "autoweights
" 1519 weights.SetSize(GetNDof()); 1525 ConnectBoundaries(); 1528 NURBSExtension::NURBSExtension(NURBSExtension *parent, int newOrder) 1530 patchTopo = parent->patchTopo; 1533 parent->edge_to_knot.Copy(edge_to_knot); 1535 NumOfKnotVectors = parent->GetNKV(); 1536 knotVectors.SetSize(NumOfKnotVectors); 1537 const Array<int> &pOrders = parent->GetOrders(); 1538 for (int i = 0; i < NumOfKnotVectors; i++) 1540 if (newOrder > pOrders[i]) 1543 parent->GetKnotVector(i)->DegreeElevate(newOrder - pOrders[i]); 1547 knotVectors[i] = new KnotVector(*parent->GetKnotVector(i)); 1551 // copy some data from parent 1552 NumOfElements = parent->NumOfElements; 1553 NumOfBdrElements = parent->NumOfBdrElements; 1555 SetOrdersFromKnotVectors(); 1557 GenerateOffsets(); // dof offsets will be different from parent 1559 NumOfActiveVertices = parent->NumOfActiveVertices; 1560 NumOfActiveElems = parent->NumOfActiveElems; 1561 NumOfActiveBdrElems = parent->NumOfActiveBdrElems; 1562 parent->activeVert.Copy(activeVert); 1564 parent->activeElem.Copy(activeElem); 1565 parent->activeBdrElem.Copy(activeBdrElem); 1567 GenerateElementDofTable(); 1568 GenerateBdrElementDofTable(); 1570 weights.SetSize(GetNDof()); 1574 parent->master.Copy(master); 1575 parent->slave.Copy(slave); 1576 ConnectBoundaries(); 1579 NURBSExtension::NURBSExtension(NURBSExtension *parent, 1580 const Array<int> &newOrders) 1582 newOrders.Copy(mOrders); 1583 SetOrderFromOrders(); 1585 patchTopo = parent->patchTopo; 1588 parent->edge_to_knot.Copy(edge_to_knot); 1590 NumOfKnotVectors = parent->GetNKV(); 1591 MFEM_VERIFY(mOrders.Size() == NumOfKnotVectors, "invalid newOrders array
"); 1592 knotVectors.SetSize(NumOfKnotVectors); 1593 const Array<int> &pOrders = parent->GetOrders(); 1595 for (int i = 0; i < NumOfKnotVectors; i++) 1597 if (mOrders[i] > pOrders[i]) 1600 parent->GetKnotVector(i)->DegreeElevate(mOrders[i] - pOrders[i]); 1604 knotVectors[i] = new KnotVector(*parent->GetKnotVector(i)); 1608 // copy some data from parent 1609 NumOfElements = parent->NumOfElements; 1610 NumOfBdrElements = parent->NumOfBdrElements; 1612 GenerateOffsets(); // dof offsets will be different from parent 1614 NumOfActiveVertices = parent->NumOfActiveVertices; 1615 NumOfActiveElems = parent->NumOfActiveElems; 1616 NumOfActiveBdrElems = parent->NumOfActiveBdrElems; 1617 parent->activeVert.Copy(activeVert); 1619 parent->activeElem.Copy(activeElem); 1620 parent->activeBdrElem.Copy(activeBdrElem); 1622 GenerateElementDofTable(); 1623 GenerateBdrElementDofTable(); 1625 weights.SetSize(GetNDof()); 1628 parent->master.Copy(master); 1629 parent->slave.Copy(slave); 1630 ConnectBoundaries(); 1633 NURBSExtension::NURBSExtension(Mesh *mesh_array[], int num_pieces) 1635 NURBSExtension *parent = mesh_array[0]->NURBSext; 1637 if (!parent->own_topo) 1640 " parent does not own the patch topology!
"); 1642 patchTopo = parent->patchTopo; 1644 parent->own_topo = 0; 1646 parent->edge_to_knot.Copy(edge_to_knot); 1648 parent->GetOrders().Copy(mOrders); 1649 mOrder = parent->GetOrder(); 1651 NumOfKnotVectors = parent->GetNKV(); 1652 knotVectors.SetSize(NumOfKnotVectors); 1653 for (int i = 0; i < NumOfKnotVectors; i++) 1655 knotVectors[i] = new KnotVector(*parent->GetKnotVector(i)); 1662 // assuming the meshes define a partitioning of all the elements 1663 NumOfActiveElems = NumOfElements; 1664 activeElem.SetSize(NumOfElements); 1667 GenerateActiveVertices(); 1669 GenerateElementDofTable(); 1670 GenerateActiveBdrElems(); 1671 GenerateBdrElementDofTable(); 1673 weights.SetSize(GetNDof()); 1674 MergeWeights(mesh_array, num_pieces); 1677 NURBSExtension::~NURBSExtension() 1679 if (patches.Size() == 0) 1685 for (int i = 0; i < knotVectors.Size(); i++) 1687 delete knotVectors[i]; 1690 for (int i = 0; i < patches.Size(); i++) 1701 void NURBSExtension::Print(std::ostream &os) const 1703 patchTopo->PrintTopo(os, edge_to_knot); 1704 if (patches.Size() == 0) 1706 os << "\nknotvectors\n
" << NumOfKnotVectors << '\n'; 1707 for (int i = 0; i < NumOfKnotVectors; i++) 1709 knotVectors[i]->Print(os); 1712 if (NumOfActiveElems < NumOfElements) 1714 os << "\nmesh_elements\n
" << NumOfActiveElems << '\n'; 1715 for (int i = 0; i < NumOfElements; i++) 1722 os << "\nweights\n
"; 1723 weights.Print(os, 1); 1727 os << "\npatches\n
"; 1728 for (int p = 0; p < patches.Size(); p++) 1730 os << "\n# patch
" << p << "\n\n
"; 1731 patches[p]->Print(os); 1736 void NURBSExtension::PrintCharacteristics(std::ostream &os) const 1739 "NURBS
Mesh entity sizes:\n
" 1740 "Dimension =
" << Dimension() << "\n
" 1742 Array<int> unique_orders(mOrders); 1743 unique_orders.Sort(); 1744 unique_orders.Unique(); 1745 unique_orders.Print(os, unique_orders.Size()); 1747 "NumOfKnotVectors =
" << GetNKV() << "\n
" 1748 "NumOfPatches =
" << GetNP() << "\n
" 1749 "NumOfBdrPatches =
" << GetNBP() << "\n
" 1750 "NumOfVertices =
" << GetGNV() << "\n
" 1751 "NumOfElements =
" << GetGNE() << "\n
" 1752 "NumOfBdrElements =
" << GetGNBE() << "\n
" 1753 "NumOfDofs =
" << GetNTotalDof() << "\n
" 1754 "NumOfActiveVertices =
" << GetNV() << "\n
" 1755 "NumOfActiveElems =
" << GetNE() << "\n
" 1756 "NumOfActiveBdrElems =
" << GetNBE() << "\n
" 1757 "NumOfActiveDofs =
" << GetNDof() << '\n'; 1758 for (int i = 0; i < NumOfKnotVectors; i++) 1760 os << ' ' << i + 1 << ")
"; 1761 knotVectors[i]->Print(os); 1766 void NURBSExtension::PrintFunctions(const char *basename, int samples) const 1769 for (int i = 0; i < NumOfKnotVectors; i++) 1771 std::ostringstream filename; 1772 filename << basename<<"_
"<<i<<".dat
"; 1773 os.open(filename.str().c_str()); 1774 knotVectors[i]->PrintFunctions(os,samples); 1779 void NURBSExtension::InitDofMap() 1786 void NURBSExtension::ConnectBoundaries(Array<int> &bnds0, Array<int> &bnds1) 1790 ConnectBoundaries(); 1793 void NURBSExtension::ConnectBoundaries() 1795 if (master.Size() != slave.Size()) 1799 if (master.Size() == 0 ) {
return; }
1802 d_to_d.SetSize(NumOfDofs);
1803 for (
int i = 0; i < NumOfDofs; i++) { d_to_d[i] = i; }
1805 for (
int i = 0; i < master.Size(); i++)
1807 if (Dimension() == 2)
1809 ConnectBoundaries2D(master[i], slave[i]);
1813 ConnectBoundaries3D(master[i], slave[i]);
1818 if (el_dof) {
delete el_dof; }
1819 if (bel_dof) {
delete bel_dof; }
1820 GenerateElementDofTable();
1821 GenerateBdrElementDofTable();
1826 int idx0 = -1, idx1 = -1;
1827 for (
int b = 0;
b < GetNBP();
b++)
1829 if (bnd0 == patchTopo->GetBdrAttribute(
b)) { idx0 =
b; }
1830 if (bnd1 == patchTopo->GetBdrAttribute(
b)) { idx1 =
b; }
1832 MFEM_VERIFY(idx0 != -1,
"Bdr 0 not found");
1833 MFEM_VERIFY(idx1 != -1,
"Bdr 1 not found");
1838 int okv0[1],okv1[1];
1845 int nks0 = kv0[0]->
GetNKS();
1848 bool compatible =
true;
1849 if (p2g0.
nx() != p2g1.
nx()) { compatible =
false; }
1850 if (kv0[0]->GetNKS() != kv1[0]->
GetNKS()) { compatible =
false; }
1851 if (kv0[0]->GetOrder() != kv1[0]->
GetOrder()) { compatible =
false; }
1858 mfem_error(
"NURBS boundaries not compatible");
1862 for (
int i = 0; i < nks0; i++)
1864 if (kv0[0]->isElement(i))
1866 if (!kv1[0]->isElement(i)) {
mfem_error(
"isElement does not match"); }
1867 for (
int ii = 0; ii <= kv0[0]->
GetOrder(); ii++)
1869 int ii0 = (okv0[0] >= 0) ? (i+ii) : (nx-i-ii);
1870 int ii1 = (okv1[0] >= 0) ? (i+ii) : (nx-i-ii);
1872 d_to_d[p2g0(ii0)] = d_to_d[p2g1(ii1)];
1882 for (
int i = 0; i < d_to_d.Size(); i++)
1888 for (
int i = 0; i < tmp.
Size(); i++)
1890 if (tmp[i] == 1) { tmp[i] = cnt++; }
1894 for (
int i = 0; i < d_to_d.Size(); i++)
1896 d_to_d[i] = tmp[d_to_d[i]];
1902 int idx0 = -1, idx1 = -1;
1903 for (
int b = 0;
b < GetNBP();
b++)
1905 if (bnd0 == patchTopo->GetBdrAttribute(
b)) { idx0 =
b; }
1906 if (bnd1 == patchTopo->GetBdrAttribute(
b)) { idx1 =
b; }
1908 MFEM_VERIFY(idx0 != -1,
"Bdr 0 not found");
1909 MFEM_VERIFY(idx1 != -1,
"Bdr 1 not found");
1914 int okv0[2],okv1[2];
1923 int nks0 = kv0[0]->
GetNKS();
1924 int nks1 = kv0[1]->
GetNKS();
1927 bool compatible =
true;
1928 if (p2g0.
nx() != p2g1.
nx()) { compatible =
false; }
1929 if (p2g0.
ny() != p2g1.
ny()) { compatible =
false; }
1931 if (kv0[0]->GetNKS() != kv1[0]->
GetNKS()) { compatible =
false; }
1932 if (kv0[1]->GetNKS() != kv1[0]->
GetNKS()) { compatible =
false; }
1934 if (kv0[0]->GetOrder() != kv1[0]->
GetOrder()) { compatible =
false; }
1935 if (kv0[1]->GetOrder() != kv1[1]->
GetOrder()) { compatible =
false; }
1947 mfem_error(
"NURBS boundaries not compatible");
1951 for (
int j = 0; j < nks1; j++)
1953 if (kv0[1]->isElement(j))
1955 if (!kv1[1]->isElement(j)) {
mfem_error(
"isElement does not match #1"); }
1956 for (
int i = 0; i < nks0; i++)
1958 if (kv0[0]->isElement(i))
1960 if (!kv1[0]->isElement(i)) {
mfem_error(
"isElement does not match #0"); }
1961 for (
int jj = 0; jj <= kv0[1]->
GetOrder(); jj++)
1963 int jj0 = (okv0[1] >= 0) ? (j+jj) : (ny-j-jj);
1964 int jj1 = (okv1[1] >= 0) ? (j+jj) : (ny-j-jj);
1966 for (
int ii = 0; ii <= kv0[0]->
GetOrder(); ii++)
1968 int ii0 = (okv0[0] >= 0) ? (i+ii) : (nx-i-ii);
1969 int ii1 = (okv1[0] >= 0) ? (i+ii) : (nx-i-ii);
1971 d_to_d[p2g0(ii0,jj0)] = d_to_d[p2g1(ii1,jj1)];
1983 for (
int i = 0; i < d_to_d.Size(); i++)
1989 for (
int i = 0; i < tmp.
Size(); i++)
1991 if (tmp[i] == 1) { tmp[i] = cnt++; }
1995 for (
int i = 0; i < d_to_d.Size(); i++)
1997 d_to_d[i] = tmp[d_to_d[i]];
2003 int vert[8], nv, g_el, nx, ny, nz,
dim = Dimension();
2009 activeVert.SetSize(GetGNV());
2011 for (
int p = 0;
p < GetNP();
p++)
2017 nz = (
dim == 3) ? p2g.
nz() : 1;
2019 for (
int k = 0; k < nz; k++)
2021 for (
int j = 0; j < ny; j++)
2023 for (
int i = 0; i < nx; i++)
2025 if (activeElem[g_el])
2029 vert[0] = p2g(i, j );
2030 vert[1] = p2g(i+1,j );
2031 vert[2] = p2g(i+1,j+1);
2032 vert[3] = p2g(i, j+1);
2037 vert[0] = p2g(i, j, k);
2038 vert[1] = p2g(i+1,j, k);
2039 vert[2] = p2g(i+1,j+1,k);
2040 vert[3] = p2g(i, j+1,k);
2042 vert[4] = p2g(i, j, k+1);
2043 vert[5] = p2g(i+1,j, k+1);
2044 vert[6] = p2g(i+1,j+1,k+1);
2045 vert[7] = p2g(i, j+1,k+1);
2049 for (
int v = 0; v < nv; v++)
2051 activeVert[vert[v]] = 1;
2060 NumOfActiveVertices = 0;
2061 for (
int i = 0; i < GetGNV(); i++)
2062 if (activeVert[i] == 1)
2064 activeVert[i] = NumOfActiveVertices++;
2070 int dim = Dimension();
2073 activeBdrElem.SetSize(GetGNBE());
2074 if (GetGNE() == GetNE())
2076 activeBdrElem =
true;
2077 NumOfActiveBdrElems = GetGNBE();
2080 activeBdrElem =
false;
2081 NumOfActiveBdrElems = 0;
2094 for (
int i = 0; i < num_pieces; i++)
2100 for (
int lel = 0; lel < lext->
GetNE(); lel++)
2102 int gel = lelem_elem[lel];
2104 int nd = el_dof->RowSize(gel);
2105 int *gdofs = el_dof->GetRow(gel);
2107 for (
int j = 0; j < nd; j++)
2109 weights(gdofs[j]) = lext->
weights(ldofs[j]);
2122 for (
int i = 0; i < num_pieces; i++)
2129 for (
int lel = 0; lel < lext->
GetNE(); lel++)
2145 for (
int p = 0;
p < GetNP();
p++)
2147 patchTopo->GetElementEdges(
p, edges, oedge);
2149 for (
int i = 0; i < edges.
Size(); i++)
2151 edges[i] = edge_to_knot[edges[i]];
2154 edges[i] = -1 - edges[i];
2158 if ((Dimension() == 2 &&
2159 (edges[0] != -1 - edges[2] || edges[1] != -1 - edges[3])) ||
2161 (Dimension() == 3 &&
2162 (edges[0] != edges[2] || edges[0] != edges[4] ||
2163 edges[0] != edges[6] || edges[1] != edges[3] ||
2164 edges[1] != edges[5] || edges[1] != edges[7] ||
2165 edges[8] != edges[9] || edges[8] != edges[10] ||
2166 edges[8] != edges[11])))
2168 mfem::err <<
"NURBSExtension::CheckPatch (patch = " <<
p 2169 <<
")\n Inconsistent edge-to-knot mapping!\n";
2173 if ((Dimension() == 2 &&
2174 (edges[0] < 0 || edges[1] < 0)) ||
2176 (Dimension() == 3 &&
2177 (edges[0] < 0 || edges[3] < 0 || edges[8] < 0)))
2179 mfem::err <<
"NURBSExtension::CheckPatch (patch = " <<
p 2180 <<
") : Bad orientation!\n";
2191 for (
int p = 0;
p < GetNBP();
p++)
2193 patchTopo->GetBdrElementEdges(
p, edges, oedge);
2195 for (
int i = 0; i < edges.
Size(); i++)
2197 edges[i] = edge_to_knot[edges[i]];
2200 edges[i] = -1 - edges[i];
2204 if ((Dimension() == 2 && (edges[0] < 0)) ||
2205 (Dimension() == 3 && (edges[0] < 0 || edges[1] < 0)))
2207 mfem::err <<
"NURBSExtension::CheckBdrPatch (boundary patch = " 2208 <<
p <<
") : Bad orientation!\n";
2219 patchTopo->GetElementEdges(
p, edges, orient);
2221 if (Dimension() == 2)
2223 kv[0] = KnotVec(edges[0]);
2224 kv[1] = KnotVec(edges[1]);
2228 kv[0] = KnotVec(edges[0]);
2229 kv[1] = KnotVec(edges[3]);
2230 kv[2] = KnotVec(edges[8]);
2240 patchTopo->GetElementEdges(
p, edges, orient);
2242 if (Dimension() == 2)
2244 kv[0] = KnotVec(edges[0]);
2245 kv[1] = KnotVec(edges[1]);
2249 kv[0] = KnotVec(edges[0]);
2250 kv[1] = KnotVec(edges[3]);
2251 kv[2] = KnotVec(edges[8]);
2261 patchTopo->GetBdrElementEdges(
p, edges, orient);
2263 if (Dimension() == 2)
2265 kv[0] = KnotVec(edges[0]);
2269 kv[0] = KnotVec(edges[0]);
2270 kv[1] = KnotVec(edges[1]);
2281 patchTopo->GetBdrElementEdges(
p, edges, orient);
2283 if (Dimension() == 2)
2285 kv[0] = KnotVec(edges[0]);
2289 kv[0] = KnotVec(edges[0]);
2290 kv[1] = KnotVec(edges[1]);
2296 MFEM_VERIFY(mOrders.Size() > 0,
"");
2297 mOrder = mOrders[0];
2298 for (
int i = 1; i < mOrders.Size(); i++)
2300 if (mOrders[i] != mOrder)
2310 mOrders.SetSize(NumOfKnotVectors);
2311 for (
int i = 0; i < NumOfKnotVectors; i++)
2313 mOrders[i] = knotVectors[i]->GetOrder();
2315 SetOrderFromOrders();
2320 int nv = patchTopo->GetNV();
2321 int ne = patchTopo->GetNEdges();
2322 int nf = patchTopo->GetNFaces();
2323 int np = patchTopo->GetNE();
2324 int meshCounter, spaceCounter,
dim = Dimension();
2330 e_meshOffsets.SetSize(ne);
2331 f_meshOffsets.SetSize(nf);
2332 p_meshOffsets.SetSize(np);
2334 v_spaceOffsets.SetSize(nv);
2335 e_spaceOffsets.SetSize(ne);
2336 f_spaceOffsets.SetSize(nf);
2337 p_spaceOffsets.SetSize(np);
2340 for (meshCounter = 0; meshCounter < nv; meshCounter++)
2342 v_meshOffsets[meshCounter] = meshCounter;
2343 v_spaceOffsets[meshCounter] = meshCounter;
2345 spaceCounter = meshCounter;
2348 for (
int e = 0; e < ne; e++)
2350 e_meshOffsets[e] = meshCounter;
2351 e_spaceOffsets[e] = spaceCounter;
2352 meshCounter += KnotVec(e)->GetNE() - 1;
2353 spaceCounter += KnotVec(e)->GetNCP() - 2;
2357 for (
int f = 0;
f < nf;
f++)
2359 f_meshOffsets[
f] = meshCounter;
2360 f_spaceOffsets[
f] = spaceCounter;
2362 patchTopo->GetFaceEdges(
f, edges, orient);
2365 (KnotVec(edges[0])->GetNE() - 1) *
2366 (KnotVec(edges[1])->GetNE() - 1);
2368 (KnotVec(edges[0])->GetNCP() - 2) *
2369 (KnotVec(edges[1])->GetNCP() - 2);
2373 for (
int p = 0;
p < np;
p++)
2375 p_meshOffsets[
p] = meshCounter;
2376 p_spaceOffsets[
p] = spaceCounter;
2378 patchTopo->GetElementEdges(
p, edges, orient);
2383 (KnotVec(edges[0])->GetNE() - 1) *
2384 (KnotVec(edges[1])->GetNE() - 1);
2386 (KnotVec(edges[0])->GetNCP() - 2) *
2387 (KnotVec(edges[1])->GetNCP() - 2);
2392 (KnotVec(edges[0])->GetNE() - 1) *
2393 (KnotVec(edges[3])->GetNE() - 1) *
2394 (KnotVec(edges[8])->GetNE() - 1);
2396 (KnotVec(edges[0])->GetNCP() - 2) *
2397 (KnotVec(edges[3])->GetNCP() - 2) *
2398 (KnotVec(edges[8])->GetNCP() - 2);
2401 NumOfVertices = meshCounter;
2402 NumOfDofs = spaceCounter;
2407 int dim = Dimension();
2411 for (
int p = 0;
p < GetNP();
p++)
2413 GetPatchKnotVectors(
p, kv);
2415 int ne = kv[0]->GetNE();
2416 for (
int d = 1; d <
dim; d++)
2418 ne *= kv[d]->GetNE();
2421 NumOfElements += ne;
2427 int dim = Dimension() - 1;
2430 NumOfBdrElements = 0;
2431 for (
int p = 0;
p < GetNBP();
p++)
2433 GetBdrPatchKnotVectors(
p, kv);
2435 int ne = kv[0]->GetNE();
2436 for (
int d = 1; d <
dim; d++)
2438 ne *= kv[d]->GetNE();
2441 NumOfBdrElements += ne;
2449 if (Dimension() == 2)
2451 Get2DElementTopo(elements);
2455 Get3DElementTopo(elements);
2467 for (
int p = 0;
p < GetNP();
p++)
2473 int patch_attr = patchTopo->GetAttribute(
p);
2475 for (
int j = 0; j < ny; j++)
2477 for (
int i = 0; i < nx; i++)
2481 ind[0] = activeVert[p2g(i, j )];
2482 ind[1] = activeVert[p2g(i+1,j )];
2483 ind[2] = activeVert[p2g(i+1,j+1)];
2484 ind[3] = activeVert[p2g(i, j+1)];
2503 for (
int p = 0;
p < GetNP();
p++)
2510 int patch_attr = patchTopo->GetAttribute(
p);
2512 for (
int k = 0; k < nz; k++)
2514 for (
int j = 0; j < ny; j++)
2516 for (
int i = 0; i < nx; i++)
2520 ind[0] = activeVert[p2g(i, j, k)];
2521 ind[1] = activeVert[p2g(i+1,j, k)];
2522 ind[2] = activeVert[p2g(i+1,j+1,k)];
2523 ind[3] = activeVert[p2g(i, j+1,k)];
2525 ind[4] = activeVert[p2g(i, j, k+1)];
2526 ind[5] = activeVert[p2g(i+1,j, k+1)];
2527 ind[6] = activeVert[p2g(i+1,j+1,k+1)];
2528 ind[7] = activeVert[p2g(i, j+1,k+1)];
2530 elements[el] =
new Hexahedron(ind, patch_attr);
2544 if (Dimension() == 2)
2546 Get2DBdrElementTopo(boundary);
2550 Get3DBdrElementTopo(boundary);
2562 for (
int b = 0;
b < GetNBP();
b++)
2567 int bdr_patch_attr = patchTopo->GetBdrAttribute(
b);
2569 for (
int i = 0; i < nx; i++)
2571 if (activeBdrElem[g_be])
2573 int i_ = (okv[0] >= 0) ? i : (nx - 1 - i);
2574 ind[0] = activeVert[p2g[i_ ]];
2575 ind[1] = activeVert[p2g[i_+1]];
2577 boundary[l_be] =
new Segment(ind, bdr_patch_attr);
2593 for (
int b = 0;
b < GetNBP();
b++)
2599 int bdr_patch_attr = patchTopo->GetBdrAttribute(
b);
2601 for (
int j = 0; j < ny; j++)
2603 int j_ = (okv[1] >= 0) ? j : (ny - 1 - j);
2604 for (
int i = 0; i < nx; i++)
2606 if (activeBdrElem[g_be])
2608 int i_ = (okv[0] >= 0) ? i : (nx - 1 - i);
2609 ind[0] = activeVert[p2g(i_, j_ )];
2610 ind[1] = activeVert[p2g(i_+1,j_ )];
2611 ind[2] = activeVert[p2g(i_+1,j_+1)];
2612 ind[3] = activeVert[p2g(i_, j_+1)];
2625 activeDof.SetSize(GetNTotalDof());
2628 if (Dimension() == 2)
2630 Generate2DElementDofTable();
2634 Generate3DElementDofTable();
2637 NumOfActiveDofs = 0;
2638 for (
int d = 0; d < GetNTotalDof(); d++)
2642 activeDof[d] = NumOfActiveDofs;
2645 int *dof = el_dof->GetJ();
2646 int ndof = el_dof->Size_of_connections();
2647 for (
int i = 0; i < ndof; i++)
2649 dof[i] = activeDof[dof[i]] - 1;
2661 el_to_patch.
SetSize(NumOfActiveElems);
2662 el_to_IJK.SetSize(NumOfActiveElems, 2);
2664 for (
int p = 0;
p < GetNP();
p++)
2669 const int ord0 = kv[0]->
GetOrder();
2670 const int ord1 = kv[1]->
GetOrder();
2671 for (
int j = 0; j < kv[1]->
GetNKS(); j++)
2673 if (kv[1]->isElement(j))
2675 for (
int i = 0; i < kv[0]->
GetNKS(); i++)
2677 if (kv[0]->isElement(i))
2682 for (
int jj = 0; jj <= ord1; jj++)
2684 for (
int ii = 0; ii <= ord0; ii++)
2686 conn.
to = DofMap(p2g(i+ii,j+jj));
2687 activeDof[conn.
to] = 1;
2688 el_dof_list.
Append(conn);
2691 el_to_patch[el] =
p;
2692 el_to_IJK(el,0) = i;
2693 el_to_IJK(el,1) = j;
2704 el_dof =
new Table(NumOfActiveElems, el_dof_list);
2715 el_to_patch.
SetSize(NumOfActiveElems);
2716 el_to_IJK.SetSize(NumOfActiveElems, 3);
2718 for (
int p = 0;
p < GetNP();
p++)
2723 const int ord0 = kv[0]->
GetOrder();
2724 const int ord1 = kv[1]->
GetOrder();
2725 const int ord2 = kv[2]->
GetOrder();
2726 for (
int k = 0; k < kv[2]->
GetNKS(); k++)
2728 if (kv[2]->isElement(k))
2730 for (
int j = 0; j < kv[1]->
GetNKS(); j++)
2732 if (kv[1]->isElement(j))
2734 for (
int i = 0; i < kv[0]->
GetNKS(); i++)
2736 if (kv[0]->isElement(i))
2741 for (
int kk = 0; kk <= ord2; kk++)
2743 for (
int jj = 0; jj <= ord1; jj++)
2745 for (
int ii = 0; ii <= ord0; ii++)
2747 conn.
to = DofMap(p2g(i+ii, j+jj, k+kk));
2748 activeDof[conn.
to] = 1;
2749 el_dof_list.
Append(conn);
2754 el_to_patch[el] =
p;
2755 el_to_IJK(el,0) = i;
2756 el_to_IJK(el,1) = j;
2757 el_to_IJK(el,2) = k;
2770 el_dof =
new Table(NumOfActiveElems, el_dof_list);
2775 if (Dimension() == 2)
2777 Generate2DBdrElementDofTable();
2781 Generate3DBdrElementDofTable();
2784 int *dof = bel_dof->GetJ();
2785 int ndof = bel_dof->Size_of_connections();
2786 for (
int i = 0; i < ndof; i++)
2788 dof[i] = activeDof[dof[i]] - 1;
2795 int lbe = 0, okv[1];
2800 bel_to_patch.
SetSize(NumOfActiveBdrElems);
2801 bel_to_IJK.SetSize(NumOfActiveBdrElems, 1);
2803 for (
int b = 0;
b < GetNBP();
b++)
2806 const int nx = p2g.
nx();
2809 const int nks0 = kv[0]->
GetNKS();
2810 const int ord0 = kv[0]->
GetOrder();
2811 for (
int i = 0; i < nks0; i++)
2813 if (kv[0]->isElement(i))
2815 if (activeBdrElem[gbe])
2818 for (
int ii = 0; ii <= ord0; ii++)
2820 conn.
to = DofMap(p2g[(okv[0] >= 0) ? (i+ii) : (nx-i-ii)]);
2821 bel_dof_list.
Append(conn);
2823 bel_to_patch[lbe] =
b;
2824 bel_to_IJK(lbe,0) = (okv[0] >= 0) ? i : (-1-i);
2832 bel_dof =
new Table(NumOfActiveBdrElems, bel_dof_list);
2838 int lbe = 0, okv[2];
2843 bel_to_patch.
SetSize(NumOfActiveBdrElems);
2844 bel_to_IJK.SetSize(NumOfActiveBdrElems, 2);
2846 for (
int b = 0;
b < GetNBP();
b++)
2849 const int nx = p2g.
nx();
2850 const int ny = p2g.
ny();
2853 const int nks0 = kv[0]->
GetNKS();
2854 const int ord0 = kv[0]->
GetOrder();
2855 const int nks1 = kv[1]->
GetNKS();
2856 const int ord1 = kv[1]->
GetOrder();
2857 for (
int j = 0; j < nks1; j++)
2859 if (kv[1]->isElement(j))
2861 for (
int i = 0; i < nks0; i++)
2863 if (kv[0]->isElement(i))
2865 if (activeBdrElem[gbe])
2868 for (
int jj = 0; jj <= ord1; jj++)
2870 const int jj_ = (okv[1] >= 0) ? (j+jj) : (ny-j-jj);
2871 for (
int ii = 0; ii <= ord0; ii++)
2873 const int ii_ = (okv[0] >= 0) ? (i+ii) : (nx-i-ii);
2874 conn.
to = DofMap(p2g(ii_, jj_));
2875 bel_dof_list.
Append(conn);
2878 bel_to_patch[lbe] =
b;
2879 bel_to_IJK(lbe,0) = (okv[0] >= 0) ? i : (-1-i);
2880 bel_to_IJK(lbe,1) = (okv[1] >= 0) ? j : (-1-j);
2890 bel_dof =
new Table(NumOfActiveBdrElems, bel_dof_list);
2896 for (
int gv = 0; gv < GetGNV(); gv++)
2897 if (activeVert[gv] >= 0)
2899 lvert_vert[activeVert[gv]] = gv;
2906 for (
int le = 0, ge = 0; ge < GetGNE(); ge++)
2909 lelem_elem[le++] = ge;
2921 NURBSFE->
SetIJK(el_to_IJK.GetRow(i));
2922 if (el_to_patch[i] != NURBSFE->
GetPatch())
2924 GetPatchKnotVectors(el_to_patch[i], NURBSFE->
KnotVectors());
2928 el_dof->GetRow(i, dofs);
2929 weights.GetSubVector(dofs, NURBSFE->
Weights());
2942 NURBSFE->
SetIJK(bel_to_IJK.GetRow(i));
2943 if (bel_to_patch[i] != NURBSFE->
GetPatch())
2945 GetBdrPatchKnotVectors(bel_to_patch[i], NURBSFE->
KnotVectors());
2946 NURBSFE->
SetPatch(bel_to_patch[i]);
2949 bel_dof->GetRow(i, dofs);
2950 weights.GetSubVector(dofs, NURBSFE->
Weights());
2960 if (patches.Size() == 0)
2962 GetPatchNets(Nodes, Dimension());
2968 if (patches.Size() == 0) {
return; }
2970 SetSolutionVector(Nodes, Dimension());
2976 if (patches.Size() == 0)
2978 mfem_error(
"NURBSExtension::SetKnotsFromPatches :" 2979 " No patches available!");
2984 for (
int p = 0;
p < patches.Size();
p++)
2986 GetPatchKnotVectors(
p, kv);
2988 for (
int i = 0; i < kv.
Size(); i++)
2990 *kv[i] = *patches[
p]->GetKV(i);
2994 SetOrdersFromKnotVectors();
3001 NumOfActiveElems = NumOfElements;
3002 activeElem.SetSize(NumOfElements);
3005 GenerateActiveVertices();
3007 GenerateElementDofTable();
3008 GenerateActiveBdrElems();
3009 GenerateBdrElementDofTable();
3011 ConnectBoundaries();
3023 const int vdim = fes->
GetVDim();
3025 for (
int p = 0;
p < GetNP();
p++)
3030 const int nx = kv[0]->GetNCP();
3031 const int ny = kv[1]->GetNCP();
3032 const int nz = (kv.
Size() == 2) ? 1 : kv[2]->GetNCP();
3033 for (
int k = 0; k < nz; k++)
3035 for (
int j = 0; j < ny; j++)
3037 for (
int i = 0; i < nx; i++)
3039 const int ll = (kv.
Size() == 2) ? p2g(i,j) : p2g(i,j,k);
3040 const int l = DofMap(ll);
3041 for (
int vd = 0; vd < vdim; vd++)
3059 const int vdim = fes->
GetVDim();
3061 for (
int p = 0;
p < GetNP();
p++)
3063 os <<
"\n# patch " <<
p <<
"\n\n";
3066 const int nx = kv[0]->GetNCP();
3067 const int ny = kv[1]->GetNCP();
3068 const int nz = (kv.Size() == 2) ? 1 : kv[2]->GetNCP();
3069 for (
int k = 0; k < nz; k++)
3071 for (
int j = 0; j < ny; j++)
3073 for (
int i = 0; i < nx; i++)
3075 const int ll = (kv.Size() == 2) ? p2g(i,j) : p2g(i,j,k);
3076 const int l = DofMap(ll);
3078 for (
int vd = 1; vd < vdim; vd++)
3091 for (
int p = 0;
p < patches.Size();
p++)
3093 for (
int dir = 0; dir < patches[
p]->GetNKV(); dir++)
3095 int oldd = patches[
p]->GetKV(dir)->GetOrder();
3096 int newd = std::min(oldd + rel_degree, degree);
3099 patches[
p]->DegreeElevate(dir, newd - oldd);
3107 for (
int p = 0;
p < patches.Size();
p++)
3109 patches[
p]->UniformRefinement();
3120 for (
int p = 0;
p < patches.Size();
p++)
3122 patchTopo->GetElementEdges(
p, edges, orient);
3126 pkv[0] = kv[KnotInd(edges[0])];
3127 pkv[1] = kv[KnotInd(edges[1])];
3131 pkv[0] = kv[KnotInd(edges[0])];
3132 pkv[1] = kv[KnotInd(edges[3])];
3133 pkv[2] = kv[KnotInd(edges[8])];
3136 patches[
p]->KnotInsert(pkv);
3147 for (
int p = 0;
p < patches.Size();
p++)
3149 patchTopo->GetElementEdges(
p, edges, orient);
3153 pkv[0] = kv[KnotInd(edges[0])];
3154 pkv[1] = kv[KnotInd(edges[1])];
3158 pkv[0] = kv[KnotInd(edges[0])];
3159 pkv[1] = kv[KnotInd(edges[3])];
3160 pkv[2] = kv[KnotInd(edges[8])];
3163 patches[
p]->KnotInsert(pkv);
3170 if (Dimension() == 2)
3172 Get2DPatchNets(coords, vdim);
3176 Get3DPatchNets(coords, vdim);
3185 patches.SetSize(GetNP());
3186 for (
int p = 0;
p < GetNP();
p++)
3192 for (
int j = 0; j < kv[1]->GetNCP(); j++)
3194 for (
int i = 0; i < kv[0]->GetNCP(); i++)
3196 const int l = DofMap(p2g(i,j));
3197 for (
int d = 0; d < vdim; d++)
3199 Patch(i,j,d) = coords(l*vdim + d)*weights(l);
3201 Patch(i,j,vdim) = weights(l);
3212 patches.SetSize(GetNP());
3213 for (
int p = 0;
p < GetNP();
p++)
3219 for (
int k = 0; k < kv[2]->GetNCP(); k++)
3221 for (
int j = 0; j < kv[1]->GetNCP(); j++)
3223 for (
int i = 0; i < kv[0]->GetNCP(); i++)
3225 const int l = DofMap(p2g(i,j,k));
3226 for (
int d = 0; d < vdim; d++)
3228 Patch(i,j,k,d) = coords(l*vdim + d)*weights(l);
3230 Patch(i,j,k,vdim) = weights(l);
3239 if (Dimension() == 2)
3241 Set2DSolutionVector(coords, vdim);
3245 Set3DSolutionVector(coords, vdim);
3254 weights.SetSize(GetNDof());
3255 for (
int p = 0;
p < GetNP();
p++)
3259 MFEM_ASSERT(vdim+1 == Patch.
GetNC(),
"");
3261 for (
int j = 0; j < kv[1]->GetNCP(); j++)
3263 for (
int i = 0; i < kv[0]->GetNCP(); i++)
3265 const int l = p2g(i,j);
3266 for (
int d = 0; d < vdim; d++)
3268 coords(l*vdim + d) = Patch(i,j,d)/Patch(i,j,vdim);
3270 weights(l) = Patch(i,j,vdim);
3282 weights.SetSize(GetNDof());
3283 for (
int p = 0;
p < GetNP();
p++)
3287 MFEM_ASSERT(vdim+1 == Patch.
GetNC(),
"");
3289 for (
int k = 0; k < kv[2]->GetNCP(); k++)
3291 for (
int j = 0; j < kv[1]->GetNCP(); j++)
3293 for (
int i = 0; i < kv[0]->GetNCP(); i++)
3295 const int l = p2g(i,j,k);
3296 for (
int d = 0; d < vdim; d++)
3298 coords(l*vdim + d) = Patch(i,j,k,d)/Patch(i,j,k,vdim);
3300 weights(l) = Patch(i,j,k,vdim);
3312 partitioning(orig.partitioning ? new int[orig.GetGNE()] : NULL),
3314 ldof_group(orig.ldof_group)
3319 std::memcpy(partitioning, orig.partitioning, orig.
GetGNE()*
sizeof(int));
3331 mfem_error(
"ParNURBSExtension::ParNURBSExtension :\n" 3332 " all elements in the parent must be active!");
3339 mfem_error(
"ParNURBSExtension::ParNURBSExtension :\n" 3340 " parent does not own the patch topology!");
3362 partitioning =
new int[
GetGNE()];
3363 for (
int i = 0; i <
GetGNE(); i++)
3365 partitioning[i] = part[i];
3367 SetActive(partitioning, active_bel);
3375 BuildGroups(partitioning, *serial_elem_dof);
3379 for (
int gel = 0, lel = 0; gel <
GetGNE(); gel++)
3385 int *gdofs = serial_elem_dof->
GetRow(gel);
3386 for (
int i = 0; i < ndofs; i++)
3397 : gtopo(par_parent->gtopo.GetComm())
3455 partitioning = NULL;
3457 MFEM_VERIFY(par_parent->partitioning,
3458 "parent ParNURBSExtension has no partitioning!");
3463 bool extract_weights =
false;
3468 SetActive(par_parent->partitioning, par_parent->
activeBdrElem);
3479 extract_weights =
true;
3482 Table *glob_elem_dof = GetGlobalElementDofTable();
3483 BuildGroups(par_parent->partitioning, *glob_elem_dof);
3484 if (extract_weights)
3491 for (
int gel = 0, lel = 0; gel <
GetGNE(); gel++)
3497 int *gdofs = glob_elem_dof->
GetRow(gel);
3498 for (
int i = 0; i < ndofs; i++)
3500 weights(ldofs[i]) = glob_weights(gdofs[i]);
3506 delete glob_elem_dof;
3509 Table *ParNURBSExtension::GetGlobalElementDofTable()
3513 return Get2DGlobalElementDofTable();
3517 return Get3DGlobalElementDofTable();
3521 Table *ParNURBSExtension::Get2DGlobalElementDofTable()
3524 const KnotVector *kv[2];
3526 Array<Connection> gel_dof_list;
3530 p2g.SetPatchDofMap(
p, kv);
3533 const int ord0 = kv[0]->GetOrder();
3534 const int ord1 = kv[1]->GetOrder();
3535 for (
int j = 0; j < kv[1]->GetNKS(); j++)
3537 if (kv[1]->isElement(j))
3539 for (
int i = 0; i < kv[0]->GetNKS(); i++)
3541 if (kv[0]->isElement(i))
3543 Connection conn(el,0);
3544 for (
int jj = 0; jj <= ord1; jj++)
3546 for (
int ii = 0; ii <= ord0; ii++)
3548 conn.to = p2g(i+ii,j+jj);
3549 gel_dof_list.Append(conn);
3559 return (
new Table(
GetGNE(), gel_dof_list));
3562 Table *ParNURBSExtension::Get3DGlobalElementDofTable()
3565 const KnotVector *kv[3];
3567 Array<Connection> gel_dof_list;
3571 p2g.SetPatchDofMap(
p, kv);
3574 const int ord0 = kv[0]->GetOrder();
3575 const int ord1 = kv[1]->GetOrder();
3576 const int ord2 = kv[2]->GetOrder();
3577 for (
int k = 0; k < kv[2]->GetNKS(); k++)
3579 if (kv[2]->isElement(k))
3581 for (
int j = 0; j < kv[1]->GetNKS(); j++)
3583 if (kv[1]->isElement(j))
3585 for (
int i = 0; i < kv[0]->GetNKS(); i++)
3587 if (kv[0]->isElement(i))
3589 Connection conn(el,0);
3590 for (
int kk = 0; kk <= ord2; kk++)
3592 for (
int jj = 0; jj <= ord1; jj++)
3594 for (
int ii = 0; ii <= ord0; ii++)
3596 conn.to = p2g(i+ii,j+jj,k+kk);
3597 gel_dof_list.Append(conn);
3610 return (
new Table(
GetGNE(), gel_dof_list));
3613 void ParNURBSExtension::SetActive(
const int *partitioning_,
3614 const Array<bool> &active_bel)
3620 for (
int i = 0; i <
GetGNE(); i++)
3621 if (partitioning_[i] == MyRank)
3629 for (
int i = 0; i <
GetGNBE(); i++)
3636 void ParNURBSExtension::BuildGroups(
const int *partitioning_,
3637 const Table &elem_dof)
3641 ListOfIntegerSets groups;
3646 for (
int i = 0; i < dof_proc.Size_of_connections(); i++)
3648 dof_proc.GetJ()[i] = partitioning_[dof_proc.GetJ()[i]];
3653 group.Recreate(1, &MyRank);
3654 groups.Insert(group);
3661 group.Recreate(dof_proc.RowSize(d), dof_proc.GetRow(d));
3669 #endif // MFEM_USE_MPI 3672 void NURBSPatchMap::GetPatchKnotVectors(
int p,
const KnotVector *kv[])
3678 kv[0] = Ext->
KnotVec(edges[0]);
3679 kv[1] = Ext->
KnotVec(edges[1]);
3685 kv[0] = Ext->
KnotVec(edges[0]);
3686 kv[1] = Ext->
KnotVec(edges[3]);
3687 kv[2] = Ext->
KnotVec(edges[8]);
3692 void NURBSPatchMap::GetBdrPatchKnotVectors(
int p,
const KnotVector *kv[],
3697 kv[0] = Ext->
KnotVec(edges[0], oedge[0], &okv[0]);
3702 kv[1] = Ext->
KnotVec(edges[1], oedge[1], &okv[1]);
3712 GetPatchKnotVectors(
p, kv);
3714 I = kv[0]->
GetNE() - 1;
3715 J = kv[1]->
GetNE() - 1;
3717 for (
int i = 0; i < verts.
Size(); i++)
3722 for (
int i = 0; i < edges.
Size(); i++)
3729 K = kv[2]->
GetNE() - 1;
3731 for (
int i = 0; i < faces.
Size(); i++)
3742 GetPatchKnotVectors(
p, kv);
3747 for (
int i = 0; i < verts.
Size(); i++)
3752 for (
int i = 0; i < edges.
Size(); i++)
3761 for (
int i = 0; i < faces.
Size(); i++)
3773 GetBdrPatchKnotVectors(
p, kv, okv);
3775 I = kv[0]->
GetNE() - 1;
3777 for (
int i = 0; i < verts.
Size(); i++)
3788 J = kv[1]->
GetNE() - 1;
3790 for (
int i = 0; i < edges.
Size(); i++)
3801 GetBdrPatchKnotVectors(
p, kv, okv);
3805 for (
int i = 0; i < verts.
Size(); i++)
3818 for (
int i = 0; i < edges.
Size(); i++)
Array< KnotVector * > knotVectors
Abstract class for all finite elements.
Array< int > f_meshOffsets
void Create(ListOfIntegerSets &groups, int mpitag)
Set up the group topology given the list of sets of shared entities.
Array2D< int > bel_to_IJK
void SetSubVector(const Array< int > &dofs, const double value)
Set the entries listed in dofs to the given value.
void SetCoordsFromPatches(Vector &Nodes)
void ConnectBoundaries2D(int bnd0, int bnd1)
KnotVector * KnotVec(int edge)
Class for grid function - Vector with associated FE space.
void GetElementEdges(int i, Array< int > &edges, Array< int > &cor) const
Return the indices and the orientations of all edges of element i.
void DegreeElevate(int dir, int t)
NURBSPatch * Interpolate(NURBSPatch &p1, NURBSPatch &p2)
void Generate2DElementDofTable()
void MergeGridFunctions(GridFunction *gf_array[], int num_pieces, GridFunction &merged)
OutStream err(std::cerr)
Global stream used by the library for standard error output. Initially it uses the same std::streambu...
void PrintSolution(const GridFunction &sol, std::ostream &out) const
void LoadFE(int i, const FiniteElement *FE) const
void Generate3DElementDofTable()
void KnotInsert(int dir, const KnotVector &knot)
void MergeWeights(Mesh *mesh_array[], int num_pieces)
void SetSize(int s)
Resize the vector to size s.
void Print(std::ostream &out) const
void CalcDShape(Vector &grad, int i, double xi) const
void Get2DBdrElementTopo(Array< Element *> &boundary) const
void Rotate3D(double normal[], double angle)
Array< int > e_meshOffsets
void GetElements()
Count the number of elements.
void SetOrdersFromKnotVectors()
const NURBSExtension * GetNURBSext() const
An arbitrary order and dimension NURBS element.
void GetBdrElementVertices(int i, Array< int > &v) const
Returns the indices of the vertices of boundary element i.
void Generate3DBdrElementDofTable()
void SetIJK(const int *IJK) const
Array< int > e_spaceOffsets
void GetBdrElementTopo(Array< Element *> &boundary) const
void GenerateBdrElementDofTable()
int MyRank() const
Return the MPI rank within this object's communicator.
void LoadSolution(std::istream &input, GridFunction &sol) const
void GetElementLocalToGlobal(Array< int > &lelem_elem)
void Get2DElementTopo(Array< Element *> &elements) const
void KnotInsert(Array< KnotVector *> &kv)
void GetSubVector(const Array< int > &dofs, Vector &elemvect) const
Extract entries listed in dofs to the output Vector elemvect.
Data type quadrilateral element.
Array< int > edge_to_knot
void GenerateActiveVertices()
void GetVertexLocalToGlobal(Array< int > &lvert_vert)
void Set2DSolutionVector(Vector &Nodes, int vdim)
void skip_comment_lines(std::istream &is, const char comment_char)
Check if the stream starts with comment_char. If so skip it.
void DeleteAll()
Delete the whole array.
void SwapDirections(int dir1, int dir2)
friend class NURBSPatchMap
virtual void SetOrder() const
Update the NURBSFiniteElement according to the currently set knot vectors.
KnotVector()
Create KnotVector.
static const int MaxOrder
Array< int > v_spaceOffsets
void GetElementTopo(Array< Element *> &elements) const
void Generate2DBdrElementDofTable()
Data type hexahedron element.
void GetBdrElementFace(int i, int *f, int *o) const
Return the index and the orientation of the face of bdr element i. (3D)
void GetBdrPatchKnotVectors(int p, Array< KnotVector *> &kv)
void ConnectBoundaries3D(int bnd0, int bnd1)
void GetElementFaces(int i, Array< int > &faces, Array< int > &ori) const
Return the indices and the orientations of all faces of element i.
ParNURBSExtension(const ParNURBSExtension &orig)
double f(const Vector &xvec)
void Set3DSolutionVector(Vector &Nodes, int vdim)
void GenerateActiveBdrElems()
int Append(const T &el)
Append element 'el' to array, resize if necessary.
int GetOrder() const
If all orders are identical, return that number. Otherwise, return NURBSFECollection::VariableOrder.
void Get3DPatchNets(const Vector &Nodes, int vdim)
void mfem_error(const char *msg)
Function called when an error is encountered. Used by the macros MFEM_ABORT, MFEM_ASSERT, MFEM_VERIFY.
const Array< int > & GetOrders() const
Read-only access to the orders of all knot vectors.
void Get2DPatchNets(const Vector &Nodes, int vdim)
void UniformRefinement(Vector &newknots) const
void CalcDnShape(Vector &gradn, int n, int i, double xi) const
void GetElementVertices(int i, Array< int > &v) const
Returns the indices of the vertices of element i.
void SetKnotsFromPatches()
void GetBdrElementEdges(int i, Array< int > &edges, Array< int > &cor) const
Return the indices and the orientations of all edges of bdr element i.
Array< const KnotVector * > & KnotVectors() const
Array< int > f_spaceOffsets
Array< bool > activeBdrElem
FiniteElementSpace * FESpace()
void GetRow(int i, Array< int > &row) const
Return row i in array row (the Table must be finalized)
void Get3DElementTopo(Array< Element *> &elements) const
void Get3DBdrElementTopo(Array< Element *> &boundary) const
int GetVDim() const
Returns vector dimension.
DofTransformation * GetElementVDofs(int i, Array< int > &vdofs) const
Returns indexes of degrees of freedom in array dofs for i'th element.
Mesh * GetMesh() const
Returns the mesh.
void Swap(Array< T > &, Array< T > &)
void Difference(const KnotVector &kv, Vector &diff) const
double p(const Vector &x, double t)
void LoadBE(int i, const FiniteElement *BE) const
void SetElement(int e) const
Class FiniteElementSpace - responsible for providing FEM view of the mesh, mainly managing the set of...
Array< int > v_meshOffsets
OutStream out(std::cout)
Global stream used by the library for standard output. Initially it uses the same std::streambuf as s...
void SetSize(int nsize)
Change the logical size of the array, keep existing entries.
void SetBdrPatchVertexMap(int p, const KnotVector *kv[], int *okv)
void Transpose(const Table &A, Table &At, int ncols_A_)
Transpose a Table.
Array< int > p_meshOffsets
void GetPatchKnotVectors(int p, Array< KnotVector *> &kv)
KnotVector & operator=(const KnotVector &kv)
void SetPatchVertexMap(int p, const KnotVector *kv[])
Helper struct for defining a connectivity table, see Table::MakeFromList.
Table * GetElementDofTable()
void SetOrderFromOrders()
NURBSExtension * NURBSext
Optional NURBS mesh extension.
void GetPatchNets(const Vector &Nodes, int vdim)
const KnotVector * GetKnotVector(int i) const
NURBSPatch * Revolve3D(NURBSPatch &patch, double n[], double ang, int times)
Array< int > p_spaceOffsets
void SetSolutionVector(Vector &Nodes, int vdim)
void SetBdrPatchDofMap(int p, const KnotVector *kv[], int *okv)
void CalcShape(Vector &shape, int i, double xi) const
void GenerateElementDofTable()
void Copy(Array ©) const
Create a copy of the internal array to the provided copy.
constexpr int dimension
This example only works in 3D. Kernels for 2D are not implemented.
int GetVSize() const
Return the number of vector dofs, i.e. GetNDofs() x GetVDim().
int Size() const
Return the logical size of the array.
int DofToVDof(int dof, int vd, int ndofs=-1) const
void DeleteAll()
Delete all dynamically allocated memory, resetting all dimensions to zero.
void DegreeElevate(int rel_degree, int degree=16)
void PrintFunctions(std::ostream &out, int samples=11) const
void SetPatch(int p) const
Data type line segment element.
Array< int > bel_to_patch
void SetPatchDofMap(int p, const KnotVector *kv[])
void ConvertToPatches(const Vector &Nodes)
int SetLoopDirection(int dir)
KnotVector * DegreeElevate(int t) const