master-9e13a9/doxygen/mortar__assembly_8cc_source.html

 /*
  * mortar_assembly.cc
  *
  *  Created on: Feb 22, 2017
  *      Author: jb
  */

 #include "flow/mortar_assembly.hh"
 #include "quadrature/intersection_quadrature.hh"
 #include "la/linsys.hh"
 #include "mesh/accessors.hh"
 #include "intersection/mixed_mesh_intersections.hh"
 #include <armadillo>

 P0_CouplingAssembler::P0_CouplingAssembler(AssemblyDataPtr data)
 : MortarAssemblyBase(data),
   tensor_average_(16),
   col_average_(4),
   quadrature_(*(data->mesh)),
   slave_ac_(data->mh_dh)
 {
     isec_data_list.reserve(30);


     for(uint row_dim=0; row_dim<4; row_dim ++)
         for(uint col_dim=0; col_dim<4; col_dim ++) {
             arma::vec row_avg = arma::vec(row_dim+1);
             row_avg.fill(1.0 / (row_dim+1));
             arma::vec col_avg = arma::vec(col_dim+1);
             col_avg.fill(1.0 / (col_dim+1));
             arma::mat avg = row_avg * col_avg.t(); // tensor product
             tensor_average(row_dim, col_dim) = avg;
             col_average_[row_dim] = row_avg;
         }
 }


 void P0_CouplingAssembler::pressure_diff(LocalElementAccessorBase<3> ele_ac, double delta) {
     isec_data_list.push_back(IsecData());
     IsecData &i_data = isec_data_list.back();

     i_data.dim= ele_ac.dim();
     i_data.delta = delta;
     i_data.dofs.resize(ele_ac.n_sides());
     i_data.vel_dofs.resize(ele_ac.n_sides());
     i_data.dirichlet_dofs.resize(ele_ac.n_sides());
     i_data.dirichlet_sol.resize(ele_ac.n_sides());
     i_data.n_dirichlet=0;
     i_data.ele_z_coord_=ele_ac.centre()[2];

     for(unsigned int i_side=0; i_side < ele_ac.n_sides(); i_side++ ) {
         i_data.dofs[i_side]=ele_ac.edge_row(i_side);
         i_data.vel_dofs[i_side] = ele_ac.side_row(i_side);
         //i_data.z_sides[i_side]=ele_ac.side(i_side)->centre()[2];
         //DebugOut().fmt("edge: {} {}", i_side, ele_ac.edge_row(i_side));
         Boundary * bcd = ele_ac.element_accessor().side(i_side)->cond();
         if (bcd) {
             ElementAccessor<3> b_ele = bcd->element_accessor();
             auto type = (DarcyMH::EqData::BC_Type)data_->bc_type.value(b_ele.centre(), b_ele);
             //DebugOut().fmt("bcd id: {} sidx: {} type: {}\n", ele->id(), i_side, type);
             if (type == DarcyMH::EqData::dirichlet) {
                 //DebugOut().fmt("Dirichlet: {}\n", ele->index());
                 double bc_pressure = data_->bc_pressure.value(b_ele.centre(), b_ele);
                 i_data.dirichlet_dofs[i_data.n_dirichlet] = i_side;
                 i_data.dirichlet_sol[i_data.n_dirichlet] = bc_pressure;
                 i_data.n_dirichlet++;
             }
         }
     }

 }


 /**
  * Works well but there is large error next to the boundary.
  */
 void P0_CouplingAssembler::assembly(LocalElementAccessorBase<3> master_ac)
 {


     // on the intersection element we consider
     // * intersection dofs for master and slave
     //   those are dofs of the space into which we interpolate
     //   base functions from individual master and slave elements
     //   For the master dofs both are usualy eqivalent.
     // * original dofs - for master same as intersection dofs, for slave
     //   all dofs of slave elements

     // form list of intersection dofs, in this case pressures in barycenters
     // but we do not use those form MH system in order to allow second schur somplement. We rather map these
     // dofs to pressure traces, i.e. we use averages of traces as barycentric values.

     /**
      *  TODO:
      *  - pass through the master and all slaves and collect global dofs , bcd, solution.
      *    I.e. call Nx pressure_diff not NxNx.
      *
      *  - Is it safe to have duplicate rows in local_system?
      *  - Is it better to have more smaller local system then single big one?
      *  - use one big or more smaller local systems to set.
      */


     if (master_ac.dim() > 2) return; // supported only for 1D and 2D master elements
     auto &isec_list = mixed_mesh_.element_intersections_[master_ac.ele_global_idx()];
     if (isec_list.size() == 0) return; // skip empty masters

     //slave_ac_.setup(master_ac);

     ElementAccessor<3> ele = master_ac.element_accessor();
     arma::vec3 ele_centre = ele.centre();
     double m_sigma = data_->sigma.value( ele_centre, ele);
     double m_conductivity = data_->conductivity.value( ele_centre, ele);
     double m_crossection = data_->cross_section.value( ele_centre, ele );

     double master_sigma = 2*m_sigma*m_conductivity *
                     2/ m_crossection;
                     /**
                      * ?? How to deal with anisotropy ??
                      * 3d-2d : compute nv of 2d triangle
                      * 2d-2d : interpret as 2d-1d-2d, should be symmetric master-slave
                      * 2d-1d : nv is tangent to 2d and normal to 1d
                     arma::dot(data_->anisotropy.value( ele_centre, ele->element_accessor())*nv, nv)
                     */


     isec_data_list.clear();
     double cs_sqr_avg = 0.0;
     double isec_sum = 0.0;
     uint i = 0;
     for(; i < isec_list.size(); ++i) {
         bool non_zero = quadrature_.reinit(isec_list[i].second);
         slave_ac_.reinit( quadrature_.slave_idx() );
         if (slave_ac_.dim() == master_ac.dim()) break;
         if (! non_zero) continue; // skip quadratures close to zero

         double cs = data_->cross_section.value(slave_ac_.element_accessor().centre(), slave_ac_.element_accessor());
         double isec_measure = quadrature_.measure();
         //DebugOut() << print_var(cs) << print_var(isec_measure);
         cs_sqr_avg += cs*cs*isec_measure;
         isec_sum += isec_measure;
         //DebugOut().fmt("Assembly23: {} {} {} ", ele.idx(), slave_ac_.element_accessor()->id(), isec_measure);
         pressure_diff(slave_ac_, isec_measure);
     }
     if ( ! (slave_ac_.dim() == 2 && master_ac.dim() ==2 ) ) {
         if( fabs(isec_sum - ele.measure()) > 1E-5) {
             string out;
             for(auto & isec : isec_list) {
                 slave_ac_.reinit(isec.second->bulk_ele_idx());
                 out += fmt::format(" {}", slave_ac_.element_accessor().idx());
             }

             double diff = (isec_sum - ele.measure())/ele.measure();
             WarningOut() << print_var(diff)
                     << print_var(ele.idx())
                     << endl
                     << out;

         }
     }
     pressure_diff(master_ac, -isec_sum);

     //DebugOut().fmt( "cs2: {} d0: {}", cs_sqr_avg, delta_0);
     master_sigma = master_sigma * (cs_sqr_avg / isec_sum)
             / isec_sum;


     add_to_linsys(master_sigma);


     // 2d-2d
     //DebugOut() << "2d-2d";
     if (i < isec_list.size()) {
         isec_data_list.clear();
         isec_sum = 0.0;
         for(; i < isec_list.size(); ++i) {
                 quadrature_.reinit(isec_list[i].second);
                 slave_ac_.reinit( quadrature_.slave_idx() );
                 double isec_measure = quadrature_.measure();
                 isec_sum += isec_measure;
                 //DebugOut().fmt("Assembly22: {} {} {}", ele.idx(), slave_ac_.element_accessor().idx(), isec_measure);
                 pressure_diff(slave_ac_, isec_measure);
         }
         pressure_diff(master_ac, -isec_sum);

         master_sigma = 100 * m_conductivity/ m_crossection / isec_sum;

         add_to_linsys(master_sigma);
     }
 }

 void P0_CouplingAssembler::add_to_linsys(double scale)
 {
     // rows
      for(IsecData &row_ele : isec_data_list) {
          //columns
          for(IsecData &col_ele : isec_data_list) {


              double s =  -scale * row_ele.delta * col_ele.delta;
              //DebugOut().fmt("s: {} {} {} {}", s, scale, row_ele.delta, col_ele.delta);
              product_ = s * tensor_average(row_ele.dim, col_ele.dim);

              loc_system_.reset(row_ele.dofs, col_ele.dofs);

              for(uint i=0; i< row_ele.n_dirichlet; i++)
                  loc_system_.set_solution_row(row_ele.dirichlet_dofs[i], row_ele.dirichlet_sol[i], -1.0);
              for(uint i=0; i< col_ele.n_dirichlet; i++) loc_system_.set_solution_col(col_ele.dirichlet_dofs[i], col_ele.dirichlet_sol[i]);
              //ASSERT( arma::norm(product_,2) == 0.0 );
              loc_system_.set_matrix(product_);
              // Must have z-coords for every side, can not use averaging vector
              loc_system_.set_rhs( -s * col_average_[row_ele.dim] * col_ele.ele_z_coord_ );
              loc_system_.eliminate_solution();

              if (fix_velocity_flag) {
                  this->fix_velocity_local(row_ele, col_ele);
              } else {
                  data_->lin_sys->set_local_system(loc_system_);
              }
          }
      }
 }


 void P0_CouplingAssembler::fix_velocity_local(const IsecData &row_ele, const IsecData & col_ele)
 {

     uint n_rows = row_ele.vel_dofs.n_rows;
     uint n_cols = col_ele.dofs.n_rows;
     arma::vec pressure(n_cols);
     arma::vec add_velocity(n_rows);
     double * solution = data_->lin_sys->get_solution_array();
     for(uint icol=0; icol < n_cols; icol++ ) pressure[icol] = solution[col_ele.dofs[icol]];
     add_velocity =  loc_system_.get_matrix() * pressure - loc_system_.get_rhs();
     //DebugOut() << "fix_velocity\n" << pressure << add_velocity;
     for(uint irow=0; irow < n_rows; irow++ ) solution[row_ele.vel_dofs[irow]] += add_velocity[irow] ;
 }

 void P1_CouplingAssembler::add_sides(LocalElementAccessorBase<3> ele_ac, unsigned int shift, vector<int> &dofs, vector<double> &dirichlet)
 {
     for(unsigned int i_side=0; i_side < ele_ac.n_sides(); i_side++ ) {
         dofs[shift+i_side] =  ele_ac.edge_row(i_side);
         Boundary * bcd = ele_ac.element_accessor().side(i_side)->cond();

         if (bcd) {
             ElementAccessor<3> b_ele = bcd->element_accessor();
             auto type = (DarcyMH::EqData::BC_Type)data_->bc_type.value(b_ele.centre(), b_ele);
             //DebugOut().fmt("bcd id: {} sidx: {} type: {}\n", ele->id(), i_side, type);
             if (type == DarcyMH::EqData::dirichlet) {
                 //DebugOut().fmt("Dirichlet: {}\n", ele->index());
                 dofs[shift + i_side] = -dofs[shift + i_side];
                 double bc_pressure = data_->bc_pressure.value(b_ele.centre(), b_ele);
                 dirichlet[shift + i_side] = bc_pressure;
             }
         }
     }
 }


 /**
  * P1 connection of different dimensions
  *
  * - 20.11. 2014 - very poor convergence, big error in pressure even at internal part of the fracture
  */

 void P1_CouplingAssembler::assembly(LocalElementAccessorBase<3> ele_ac) {
 /*
     const IsecList &master_list = master_list_[ele_ac.ele_global_idx()];
     if (master_list.size() == 0) return; // skip empty masters
     double master_sigma=data_->sigma.value( ele_ac.element_accessor()->centre(), ele_ac.element_accessor());

     // set mater sides
     add_sides(ele_ac, 3, dofs, dirichlet);

     for(uint i = 0; i < master_list.size(); ++i) {
         const IntersectionQuadrature &intersec = intersections_[ master_list[i] ];
         const Element * slave = intersec.slave_iter();
         ele_ac.reinit(intersec.slave_iter()->index());
         add_sides(ele_ac, 0, dofs, dirichlet);
 */

 /*
  * Local coordinates on 1D
  *         t0
  * node 0: 0.0
  * node 1: 1.0
  *
  * base fce points
  * t0 = 0.0    on side 0 node 0
  * t0 = 1.0    on side 1 node 1
  *
  * Local coordinates on 2D
  *         t0  t1
  * node 0: 0.0 0.0
  * node 1: 1.0 0.0
  * node 2: 0.0 1.0
  *
  * base fce points
  * t0=0.5, t1=0.0        on side 0 nodes (0,1)
  * t0=0.5, t1=0.5        on side 1 nodes (1,2)
  * t0=0.0, t1=0.5        on side 2 nodes (2,0)
  */

 /*

         arma::vec point_Y(1);
         point_Y.fill(1.0);
         arma::vec point_2D_Y(intersec.map_to_slave(point_Y)); // local coordinates of  Y on slave (1, t0, t1)
         arma::vec point_1D_Y(intersec.map_to_master(point_Y)); //  local coordinates of  Y on master (1, t0)

         arma::vec point_X(1);
         point_X.fill(0.0);
         arma::vec point_2D_X(intersec.map_to_slave(point_X)); // local coordinates of  X on slave (1, t0, t1)
         arma::vec point_1D_X(intersec.map_to_master(point_X)); // local coordinates of  X on master (1, t0)

         arma::mat base_2D(3, 3);
         // basis functions are numbered as sides
         // TODO:
         // Use RT finite element to evaluate following matrices.

         // Ravirat - Thomas base functions evaluated in points (0,0), (1,0), (0,1)
         // 2D RT_i(t0, t1) = a0 + a1*t0 + a2*t1
         //         a0     a1      a2
         base_2D << 1.0 << 0.0 << -2.0 << arma::endr // RT for side 0
                 << 1.0 << -2.0 << 0.0 << arma::endr // RT for side 1
                 << -1.0 << 2.0 << 2.0 << arma::endr;// RT for side 2


         arma::mat base_1D(2, 2);
         // Ravirat - Thomas base functions evaluated in points (0,0), (1,0), (0,1)
         // 1D RT_i(t0) =   a0 + a1 * t0
         //          a0     a1
         base_1D << 1.0 << -1.0 << arma::endr // RT for side 0,
                 << 0.0 << 1.0 << arma::endr; // RT for side 1,


         // Consider both 2D and 1D value are defined for the test function
         // related to the each of 5 DOFs involved in the intersection.
         // One of these values is always zero.
         // Compute difference of the 2D and 1D value for every DOF.
         // Compute value of this difference in both endpoints X,Y of the intersection.

         arma::vec difference_in_Y(5);
         arma::vec difference_in_X(5);
         // slave sides 0,1,2
         difference_in_Y.subvec(0, 2) = -base_2D * point_2D_Y;
         difference_in_X.subvec(0, 2) = -base_2D * point_2D_X;
         // master sides 3,4
         difference_in_Y.subvec(3, 4) = base_1D * point_1D_Y;
         difference_in_X.subvec(3, 4) = base_1D * point_1D_X;

         // applying the Simpson's rule
         // to the product of two linear functions f, g we get
         // (b-a)/6 * ( 3*f(a)*g(a) + 3*f(b)*g(b) + 2*f(a)*g(b) + 2*f(b)*g(a) )
         arma::mat A(5, 5);
         for (int i = 0; i < 5; ++i) {
             for (int j = 0; j < 5; ++j) {
                 A(i, j) = -master_sigma * intersec.intersection_true_size() *
                         ( difference_in_Y[i] * difference_in_Y[j]
                           + difference_in_Y[i] * difference_in_X[j]/2
                           + difference_in_X[i] * difference_in_Y[j]/2
                           + difference_in_X[i] * difference_in_X[j]
                         ) * (1.0 / 3.0);

             }
         }
         auto dofs_cp=dofs;
         data_->lin_sys->set_values( dofs_cp, dofs_cp, A, rhs, dirichlet, dirichlet);

     }*/
 }


LocalElementAccessorBase::centre
const arma::vec3 centre() const
Definition: mh_dofhandler.hh:136

DarcyMH::EqData::dirichlet
Definition: darcy_flow_mh.hh:157

IsecData::dirichlet_sol
arma::vec dirichlet_sol
Definition: mortar_assembly.hh:61

LocalSystem::set_solution_col
void set_solution_col(uint loc_col, double solution)
Definition: local_system.cc:91

LocalSystem::get_matrix
const arma::mat & get_matrix()
Definition: local_system.hh:65

LocalSystem::get_rhs
const arma::vec & get_rhs()
Definition: local_system.hh:66

arma::vec3
Definition: doxy_dummy_defs.hh:17

Armor::mat
Mat< double, N, M > mat
Definition: armor.hh:214

P0_CouplingAssembler::add_to_linsys
void add_to_linsys(double scale)
Definition: mortar_assembly.cc:200

uint
unsigned int uint
Definition: mh_dofhandler.hh:108

mixed_mesh_intersections.hh

LocalSystem::set_matrix
void set_matrix(arma::mat matrix)
Definition: local_system.cc:203

LocalElementAccessorBase::reinit
void reinit(uint loc_ele_idx)
Definition: mh_dofhandler.hh:118

LocalElementAccessorBase::element_accessor
ElementAccessor< 3 > element_accessor()
Definition: mh_dofhandler.hh:132

accessors.hh

Side::cond
Boundary * cond() const
Definition: side_impl.hh:71

linsys.hh
Wrappers for linear systems based on MPIAIJ and MATIS format.

fmt::format
std::string format(CStringRef format_str, ArgList args)
Definition: format.h:3141

IntersectionQuadratureP0::slave_idx
uint slave_idx() const
Definition: intersection_quadrature.hh:187

ElementAccessor< 3 >

AssemblyDataPtr
std::shared_ptr< DarcyMH::EqData > AssemblyDataPtr
Definition: mortar_assembly.hh:19

LocalElementAccessorBase::side_row
uint side_row(uint i)
Definition: mh_dofhandler.hh:197

mortar_assembly.hh

Armor::vec
Mat< double, N, 1 > vec
Definition: armor.hh:211

P1_CouplingAssembler::add_sides
void add_sides(LocalElementAccessorBase< 3 > ele_ac, unsigned int shift, vector< int > &dofs, vector< double > &dirichlet)
Definition: mortar_assembly.cc:247

MixedMeshIntersections::element_intersections_
std::vector< std::vector< ILpair > > element_intersections_
Definition: mixed_mesh_intersections.hh:83

IntersectionQuadratureP0::reinit
bool reinit(const IntersectionLocalBase *isec)
Definition: intersection_quadrature.hh:162

ElementAccessor::side
SideIter side(const unsigned int loc_index)
Definition: accessors.hh:137

P0_CouplingAssembler::pressure_diff
void pressure_diff(LocalElementAccessorBase< 3 > ele_ac, double delta)
Definition: mortar_assembly.cc:38

MortarAssemblyBase::data_
AssemblyDataPtr data_
Definition: mortar_assembly.hh:46

IsecData
Definition: mortar_assembly.hh:54

std::vector< int >

P0_CouplingAssembler::quadrature_
IntersectionQuadratureP0 quadrature_
Definition: mortar_assembly.hh:84

P1_CouplingAssembler::assembly
void assembly(LocalElementAccessorBase< 3 > ele_ac)
Definition: mortar_assembly.cc:274

LocalElementAccessorBase::dim
uint dim()
Definition: mh_dofhandler.hh:124

MortarAssemblyBase::mixed_mesh_
MixedMeshIntersections & mixed_mesh_
Definition: mortar_assembly.hh:47

P0_CouplingAssembler::fix_velocity_local
void fix_velocity_local(const IsecData &row_ele, const IsecData &col_ele)
Definition: mortar_assembly.cc:233

P0_CouplingAssembler::assembly
void assembly(LocalElementAccessorBase< 3 > ele_ac)
Definition: mortar_assembly.cc:80

IsecData::delta
double delta
Definition: mortar_assembly.hh:58

MortarAssemblyBase::loc_system_
LocalSystem loc_system_
Definition: mortar_assembly.hh:48

P0_CouplingAssembler::P0_CouplingAssembler
P0_CouplingAssembler(AssemblyDataPtr data)
Definition: mortar_assembly.cc:15

Boundary
Definition: boundaries.h:48

ElementAccessor::centre
arma::vec::fixed< spacedim > centre() const
Computes the barycenter.
Definition: accessors.hh:285

P0_CouplingAssembler::product_
arma::mat product_
Definition: mortar_assembly.hh:85

MortarAssemblyBase
Definition: mortar_assembly.hh:22

IsecData::vel_dofs
LocalSystem::DofVec vel_dofs
Definition: mortar_assembly.hh:55

LocalSystem::reset
void reset()
Resets the matrix, RHS, dofs to zero and clears solution settings.
Definition: local_system.cc:43

ElementAccessor::measure
double measure() const
Computes the measure of the element.
Definition: accessors.hh:254

LocalElementAccessorBase< 3 >

LocalElementAccessorBase::n_sides
uint n_sides()
Definition: mh_dofhandler.hh:128

LocalElementAccessorBase::ele_global_idx
uint ele_global_idx()
Definition: mh_dofhandler.hh:148

P0_CouplingAssembler::slave_ac_
LocalElementAccessorBase< 3 > slave_ac_
Definition: mortar_assembly.hh:86

LocalElementAccessorBase::edge_row
uint edge_row(uint i)
Definition: mh_dofhandler.hh:172

IsecData::dirichlet_dofs
LocalSystem::DofVec dirichlet_dofs
Definition: mortar_assembly.hh:60

P0_CouplingAssembler::tensor_average
arma::mat & tensor_average(unsigned int row_dim, unsigned int col_dim)
Definition: mortar_assembly.hh:73

IntersectionQuadratureP0::measure
double measure() const
Definition: intersection_quadrature.hh:190

MortarAssemblyBase::fix_velocity_flag
bool fix_velocity_flag
Definition: mortar_assembly.hh:49

LocalSystem::set_solution_row
void set_solution_row(uint loc_row, double solution, double diag=0.0)
Definition: local_system.cc:84

P0_CouplingAssembler::col_average_
std::vector< arma::vec > col_average_
Definition: mortar_assembly.hh:83

LocalSystem::set_rhs
void set_rhs(arma::vec rhs)
Definition: local_system.cc:209

intersection_quadrature.hh
???

IsecData::n_dirichlet
unsigned int n_dirichlet
Definition: mortar_assembly.hh:62

IsecData::dim
unsigned int dim
Definition: mortar_assembly.hh:57

WarningOut
#define WarningOut()
Macro defining &#39;warning&#39; record of log.
Definition: logger.hh:246

P0_CouplingAssembler::isec_data_list
vector< IsecData > isec_data_list
Definition: mortar_assembly.hh:79

IsecData::ele_z_coord_
double ele_z_coord_
Definition: mortar_assembly.hh:59

print_var
#define print_var(var)
Definition: logger.hh:260

DarcyMH::EqData::BC_Type
BC_Type
Definition: darcy_flow_mh.hh:155

ElementAccessor::idx
unsigned int idx() const
Return local idx of element in boundary / bulk part of element vector.
Definition: accessors.hh:111

LocalSystem::eliminate_solution
void eliminate_solution()
Definition: local_system.cc:109

Boundary::element_accessor
ElementAccessor< 3 > element_accessor()
Definition: boundaries.cc:48

IsecData::dofs
LocalSystem::DofVec dofs
Definition: mortar_assembly.hh:56