void CleverNodeInjection<TYPE>::coarsen( SAMRAI::hier::Patch& coarse, const SAMRAI::hier::Patch& fine, const int dst_component, const int src_component, const SAMRAI::hier::Box& coarse_box, const SAMRAI::hier::IntVector& ratio) const { boost::shared_ptr<CleverNodeData<TYPE> > fine_data( SHARED_PTR_CAST(CleverNodeData<TYPE> , fine.getPatchData(src_component))); boost::shared_ptr<CleverNodeData<TYPE> > coarse_data( SHARED_PTR_CAST(CleverNodeData<TYPE> , coarse.getPatchData(dst_component))); const SAMRAI::hier::Box coarse_ghost_box = SAMRAI::pdat::NodeGeometry::toNodeBox(coarse_data->getGhostBox()); const SAMRAI::hier::Box fine_ghost_box = SAMRAI::pdat::NodeGeometry::toNodeBox(fine_data->getGhostBox()); const hier::Index filo = fine_data->getGhostBox().lower(); const hier::Index fihi = fine_data->getGhostBox().upper(); const hier::Index cilo = coarse_data->getGhostBox().lower(); const hier::Index cihi = coarse_data->getGhostBox().upper(); const hier::Index ifirstc = coarse_box.lower(); const hier::Index ilastc = coarse_box.upper(); for(int depth = 0; depth < coarse_data->getDepth(); depth++) { if (fine.getDim() == SAMRAI::tbox::Dimension(2)) { F90_FUNC(conavgclevernodedoub2d, CONAVGCLEVERNODEDOUB2D) (ifirstc(0), ifirstc(1), ilastc(0), ilastc(1), filo(0), filo(1), fihi(0), fihi(1), cilo(0), cilo(1), cihi(0), cihi(1), &ratio[0], fine_data->getPointer(depth), coarse_data->getPointer(depth)); } else { TBOX_ERROR("CleverNodeInjection error...\n" << "dim != 2 not supported." << std::endl); } } }
void Elastic::FAC::pack_v_v_rhs(double* buffer, const SAMRAI::hier::Patch& patch, const SAMRAI::hier::Box& region, const std::string& variable_name, const int &depth) const { boost::shared_ptr<SAMRAI::pdat::SideData<double> > v_ptr; if (variable_name == "Displacement") { v_ptr = boost::dynamic_pointer_cast<SAMRAI::pdat::SideData<double> > (patch.getPatchData(v_id)); } else if ("Fault Correction + RHS" == variable_name) { v_ptr = boost::dynamic_pointer_cast<SAMRAI::pdat::SideData<double> > (patch.getPatchData(v_rhs_id)); } else { TBOX_ERROR("Unregistered variable name '" << variable_name << "' in\n" << "Elastic::FAC::packDerivedDataIntoDoubleBuffer"); } SAMRAI::pdat::SideData<double>& v = *v_ptr; if(d_dim.getValue()==2) { const SAMRAI::hier::Index ip(1,0), jp(0,1); SAMRAI::pdat::CellIterator iend(SAMRAI::pdat::CellGeometry::end(region)); for (SAMRAI::pdat::CellIterator icell(SAMRAI::pdat::CellGeometry::begin(region)); icell!=iend; ++icell) { const SAMRAI::pdat::CellIndex ¢er(*icell); const SAMRAI::pdat::SideIndex x(center,0,SAMRAI::pdat::SideIndex::Lower), y(center,1,SAMRAI::pdat::SideIndex::Lower); double vx=v(x); double vy=v(y); if(!offset_vector_on_output) { vx=(v(x+ip) + vx)/2; vy=(v(y+jp) + vy)/2; } if (0==depth) { *buffer = vx; } else { *buffer = vy; } buffer = buffer + 1; } } else { const SAMRAI::hier::Index ip(1,0,0), jp(0,1,0), kp(0,0,1); SAMRAI::pdat::CellIterator iend(SAMRAI::pdat::CellGeometry::end(region)); for (SAMRAI::pdat::CellIterator icell(SAMRAI::pdat::CellGeometry::begin(region)); icell!=iend; ++icell) { const SAMRAI::pdat::CellIndex ¢er(*icell); const SAMRAI::pdat::SideIndex x(center,0,SAMRAI::pdat::SideIndex::Lower), y(center,1,SAMRAI::pdat::SideIndex::Lower), z(center,2,SAMRAI::pdat::SideIndex::Lower); double vx=v(x); double vy=v(y); double vz=v(z); if(!offset_vector_on_output) { vx=(v(x+ip) + vx)/2; vy=(v(y+jp) + vy)/2; vz=(v(z+kp) + vz)/2; } if (0==depth) { *buffer = vx; } else if (1==depth) { *buffer = vy; } else { *buffer = vz; } ++buffer; } } }
void Stokes::V_Coarsen_Patch_Strategy::postprocessCoarsen_2D (SAMRAI::hier::Patch& coarse, const SAMRAI::hier::Patch& fine, const SAMRAI::hier::Box& , const SAMRAI::hier::IntVector& ) { /* Fix up the boundary elements by iterating through the boundary boxes */ /* We only care about edges, not corners, so we only iterate over edge boundary boxes. */ const std::vector<SAMRAI::hier::BoundaryBox> &boundaries=coarse_fine[fine.getPatchLevelNumber()]->getEdgeBoundaries(coarse.getGlobalId()); boost::shared_ptr<SAMRAI::pdat::SideData<double> > v_fine = boost::dynamic_pointer_cast<SAMRAI::pdat::SideData<double> > (fine.getPatchData(v_id)); boost::shared_ptr<SAMRAI::pdat::SideData<double> > v = boost::dynamic_pointer_cast<SAMRAI::pdat::SideData<double> > (coarse.getPatchData(v_id)); TBOX_ASSERT(v); TBOX_ASSERT(v_fine); TBOX_ASSERT(v_fine->getDepth() == v->getDepth()); TBOX_ASSERT(v->getDepth() == 1); SAMRAI::hier::Box gbox(v_fine->getGhostBox()); SAMRAI::hier::Index ip(1,0), jp(0,1); for(size_t mm=0; mm<boundaries.size(); ++mm) { SAMRAI::hier::Box bbox=boundaries[mm].getBox(); int location_index=boundaries[mm].getLocationIndex(); SAMRAI::hier::Index lower=SAMRAI::hier::Index::coarsen(bbox.lower(), SAMRAI::hier::Index(2,2)), upper=SAMRAI::hier::Index::coarsen(bbox.upper(), SAMRAI::hier::Index(2,2)); for(int j=lower(1); j<=upper(1); ++j) for(int i=lower(0); i<=upper(0); ++i) { /* Fix vx */ if(location_index==0) { SAMRAI::pdat::SideIndex coarse(SAMRAI::hier::Index(i,j),0, SAMRAI::pdat::SideIndex::Upper); SAMRAI::pdat::SideIndex center(coarse*2); if(center[1]>=gbox.lower(1) && center[1]<gbox.upper(1)) { (*v)(coarse)=((*v_fine)(center) + (*v_fine)(center+jp))/2; } } else if(location_index==1) { SAMRAI::pdat::SideIndex coarse(SAMRAI::hier::Index(i,j),0, SAMRAI::pdat::SideIndex::Lower); SAMRAI::pdat::SideIndex center(coarse*2); if(center[1]>=gbox.lower(1) && center[1]<gbox.upper(1)) { (*v)(coarse)=((*v_fine)(center) + (*v_fine)(center+jp))/2; } } /* Fix vy */ else if(location_index==2) { SAMRAI::pdat::SideIndex coarse(SAMRAI::hier::Index(i,j),1, SAMRAI::pdat::SideIndex::Upper); SAMRAI::pdat::SideIndex center(coarse*2); if(center[0]>=gbox.lower(0) && center[0]<gbox.upper(0)) { (*v)(coarse)=((*v_fine)(center) + (*v_fine)(center+ip))/2; } } else if(location_index==3) { SAMRAI::pdat::SideIndex coarse(SAMRAI::hier::Index(i,j),1, SAMRAI::pdat::SideIndex::Lower); SAMRAI::pdat::SideIndex center(coarse*2); if(center[0]>=gbox.lower(0) && center[0]<gbox.upper(0)) { (*v)(coarse)=((*v_fine)(center) + (*v_fine)(center+ip))/2; } } else { abort(); } } } }
void Stokes::FACOps::residual_3D (SAMRAI::pdat::CellData<double> &p, SAMRAI::pdat::SideData<double> &v, SAMRAI::pdat::CellData<double> &cell_viscosity, SAMRAI::pdat::CellData<double> &p_rhs, SAMRAI::pdat::SideData<double> &v_rhs, SAMRAI::pdat::CellData<double> &p_resid, SAMRAI::pdat::SideData<double> &v_resid, SAMRAI::hier::Patch &patch, const SAMRAI::hier::Box &pbox, const SAMRAI::geom::CartesianPatchGeometry &geom) { boost::shared_ptr<SAMRAI::pdat::EdgeData<double> > edge_viscosity_ptr = boost::dynamic_pointer_cast<SAMRAI::pdat::EdgeData<double> > (patch.getPatchData(edge_viscosity_id)); SAMRAI::pdat::EdgeData<double> &edge_viscosity(*edge_viscosity_ptr); const double *Dx = geom.getDx(); const SAMRAI::hier::Index ip(1,0,0), jp(0,1,0), kp(0,0,1); const SAMRAI::hier::Index pp[]={ip,jp,kp}; SAMRAI::pdat::CellIterator cend(SAMRAI::pdat::CellGeometry::end(pbox)); for(SAMRAI::pdat::CellIterator ci(SAMRAI::pdat::CellGeometry::begin(pbox)); ci!=cend; ++ci) { const SAMRAI::pdat::CellIndex ¢er(*ci); SAMRAI::pdat::CellIndex up(center), down(center), right(center), left(center), front(center), back(center); ++right[0]; --left[0]; ++up[1]; --down[1]; ++front[2]; --back[2]; /* p */ if(center[0]!=pbox.upper(0) && center[1]!=pbox.upper(1) && center[2]!=pbox.upper(2)) { const SAMRAI::pdat::SideIndex x(center,0,SAMRAI::pdat::SideIndex::Lower), y(center,1,SAMRAI::pdat::SideIndex::Lower), z(center,2,SAMRAI::pdat::SideIndex::Lower); double dvx_dx=(v(x+ip) - v(x))/Dx[0]; double dvy_dy=(v(y+jp) - v(y))/Dx[1]; double dvz_dz=(v(z+kp) - v(z))/Dx[2]; p_resid(center)=p_rhs(center) - dvx_dx - dvy_dy - dvz_dz; } for(Gamra::Dir ix=0;ix<3;++ix) { const Gamra::Dir iy(ix.next(3)); const Gamra::Dir iz(iy.next(3)); const SAMRAI::pdat::SideIndex x(center,ix,SAMRAI::pdat::SideIndex::Lower), y(center,iy,SAMRAI::pdat::SideIndex::Lower), z(center,iz,SAMRAI::pdat::SideIndex::Lower); const SAMRAI::pdat::EdgeIndex edge_y(center,iy,SAMRAI::pdat::EdgeIndex::LowerLeft), edge_z(center,iz,SAMRAI::pdat::EdgeIndex::LowerLeft); if(center[iy]!=pbox.upper(iy) && center[iz]!=pbox.upper(iz)) { if((center[ix]==pbox.lower(ix) && v(x-pp[ix])==boundary_value) || (center[ix]==pbox.upper(ix) && v(x+pp[ix])==boundary_value)) { v_resid(x)=0; } else { v_resid(x)=v_rhs(x) - v_operator_3D(v,p,cell_viscosity,edge_viscosity, center,edge_y,edge_z,x,y,z, pp[ix],pp[iy],pp[iz],Dx[ix],Dx[iy],Dx[iz]); } } } } }
void Elastic::FAC::pack_strain(double* buffer, const SAMRAI::hier::Patch& patch, const SAMRAI::hier::Box& region, const int &depth) const { boost::shared_ptr<SAMRAI::pdat::SideData<double> > v_ptr= boost::dynamic_pointer_cast<SAMRAI::pdat::SideData<double> > (patch.getPatchData(v_id)); SAMRAI::pdat::SideData<double>& v = *v_ptr; boost::shared_ptr<SAMRAI::pdat::CellData<double> > dv_diagonal; boost::shared_ptr<SAMRAI::pdat::SideData<double> > dv_mixed; if(!faults.empty()) { dv_diagonal=boost::dynamic_pointer_cast<SAMRAI::pdat::CellData<double> > (patch.getPatchData(dv_diagonal_id)); dv_mixed=boost::dynamic_pointer_cast<SAMRAI::pdat::SideData<double> > (patch.getPatchData(dv_mixed_id)); } const Gamra::Dir dim=d_dim.getValue(); if(have_embedded_boundary()) { boost::shared_ptr<SAMRAI::pdat::SideData<double> > level_set_ptr; if(have_embedded_boundary()) level_set_ptr=boost::dynamic_pointer_cast<SAMRAI::pdat::SideData<double> > (patch.getPatchData(level_set_id)); } Gamra::Dir ix(Gamra::Dir::from_int(depth/dim)), iy(Gamra::Dir::from_int(depth%dim)); const SAMRAI::hier::Index zero(SAMRAI::hier::Index::getZeroIndex(d_dim)); SAMRAI::hier::Index ip(zero), jp(zero); ip[ix]=1; jp[iy]=1; const double *dx(boost::dynamic_pointer_cast <SAMRAI::geom::CartesianPatchGeometry> (patch.getPatchGeometry())->getDx()); SAMRAI::pdat::CellIterator iend(SAMRAI::pdat::CellGeometry::end(region)); for(SAMRAI::pdat::CellIterator icell(SAMRAI::pdat::CellGeometry::begin(region)); icell!=iend; ++icell) { const SAMRAI::pdat::SideIndex s(*icell,ix,SAMRAI::pdat::SideIndex::Lower); if(ix==iy) { double diff(v(s+ip)-v(s)); if(!faults.empty()) diff-=(*dv_diagonal)(*icell,ix); *buffer=diff/dx[ix]; } else { const int ix_iy(index_map(ix,iy,dim)); double diff(- v(s-jp) - v(s+ip-jp) + v(s+jp) + v(s+ip+jp)); if(!faults.empty()) diff+=(*dv_mixed)(s,ix_iy+1) - (*dv_mixed)(s-jp,ix_iy) + (*dv_mixed)(s+ip,ix_iy+1) - (*dv_mixed)(s+ip-jp,ix_iy) + (*dv_mixed)(s+jp,ix_iy+1) - (*dv_mixed)(s,ix_iy) + (*dv_mixed)(s+ip+jp,ix_iy+1) - (*dv_mixed)(s+ip,ix_iy); *buffer=diff/(4*dx[iy]); } ++buffer; } }
void Elastic::Boundary_Conditions::set_embedded_boundary (const SAMRAI::hier::Patch& patch, const int &level_set_id, const int &dv_mixed_id) { boost::shared_ptr<SAMRAI::pdat::SideData<double> > level_set_ptr= boost::dynamic_pointer_cast<SAMRAI::pdat::SideData<double> > (patch.getPatchData(level_set_id)); SAMRAI::pdat::SideData<double> &level_set(*level_set_ptr); boost::shared_ptr<SAMRAI::pdat::SideData<double> > dv_mixed_ptr; if(dv_mixed_id!=invalid_id) dv_mixed_ptr=boost::dynamic_pointer_cast <SAMRAI::pdat::SideData<double> >(patch.getPatchData(dv_mixed_id)); const SAMRAI::tbox::Dimension dimension(patch.getDim()); const Gamra::Dir dim(dimension.getValue()); const SAMRAI::hier::Box gbox=level_set.getGhostBox(); const SAMRAI::hier::Box box=level_set.getBox(); boost::shared_ptr<SAMRAI::geom::CartesianPatchGeometry> geom = boost::dynamic_pointer_cast<SAMRAI::geom::CartesianPatchGeometry> (patch.getPatchGeometry()); /* Corners are not synced, so we set the level set to a generic * negative value and dv_mixed to zero. Setting dv_mixed to zero * implies that we do not care about faults that intersect that * corner (nor should we). */ for(Gamra::Dir ix=0; ix<dim; ++ix) { const Gamra::Dir iy(ix.next(dim)); const Gamra::Dir iz(iy.next(dim)); std::vector<std::vector<int> > corners(dim); corners[ix].push_back(box.lower(ix)); corners[ix].push_back(box.upper(ix)+1); if(geom->getTouchesRegularBoundary(iy,0)) corners[iy].push_back(gbox.lower(iy)); if(geom->getTouchesRegularBoundary(iy,1)) corners[iy].push_back(gbox.upper(iy)); if(dim==3) { if(geom->getTouchesRegularBoundary(iz,0)) corners[iz].push_back(gbox.lower(iz)); if(geom->getTouchesRegularBoundary(iz,1)) corners[iz].push_back(gbox.upper(iz)); } SAMRAI::pdat::SideIndex x(SAMRAI::hier::Index(dimension),ix, SAMRAI::pdat::SideIndex::Lower); for(std::vector<int>::iterator i=corners[ix].begin(); i!=corners[ix].end(); ++i) { x[ix]=*i; if(dim==2) { for(std::vector<int>::iterator j=corners[iy].begin(); j!=corners[iy].end();++j) { x[iy]=*j; set_embedded_values(x,dim,level_set,dv_mixed_ptr); } } else { for(std::vector<int>::iterator j=corners[iy].begin(); j!=corners[iy].end();++j) for(int kk=gbox.lower(iz); kk<=gbox.upper(iz); ++kk) { x[iy]=*j; x[iz]=kk; set_embedded_values(x,dim,level_set,dv_mixed_ptr); } for(std::vector<int>::iterator k=corners[iz].begin(); k!=corners[iz].end();++k) { for(int jj=gbox.lower(iy); jj<=gbox.upper(iy); ++jj) { x[iy]=jj; x[iz]=*k; set_embedded_values(x,dim,level_set,dv_mixed_ptr); } } } } } }