https://github.com/geodynamics/citcoms
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Tip revision: 93827a482285dac89bdbc22d623ef4f4753ac4f5 authored by Eh Tan on 14 June 2007, 22:59 UTC
Update ChangeLog upto r7249
Tip revision: 93827a4
Size_does_matter.c
/*
 *~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 *
 *<LicenseText>
 *
 * CitcomS by Louis Moresi, Shijie Zhong, Lijie Han, Eh Tan,
 * Clint Conrad, Michael Gurnis, and Eun-seo Choi.
 * Copyright (C) 1994-2005, California Institute of Technology.
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation; either version 2 of the License, or
 * (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software
 * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA
 *
 *</LicenseText>
 *
 *~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 */
#include <math.h>
#include <sys/types.h>
#include "element_definitions.h"
#include "global_defs.h"


void twiddle_thumbs(yawn,scratch_groin)
     struct All_variables *yawn;
     int scratch_groin;

{ /* Do nothing, just sit back and relax.
     Take it easy for a while, maybe size
     doesn't matter after all. There, there
     that's better. Now ... */

  return; }


/*	==================================================================================
	Function to give the global shape function from the local: Assumes ORTHOGONAL MESH
	==================================================================================      */

void get_global_shape_fn(E,el,GN,GNx,dOmega,pressure,sphere,rtf,lev,m)
     struct All_variables *E;
     int el,m;
     struct Shape_function *GN;
     struct Shape_function_dx *GNx;
     struct Shape_function_dA *dOmega;
     int pressure,lev,sphere;
     double rtf[4][9];
{
  int i,j,k,d,e;
  double jacobian;
  double determinant();
  double cofactor(),myatan();
  void   form_rtf_bc();

  struct Shape_function_dx LGNx;

  double dxda[4][4],cof[4][4],x[4],bc[4][4];


  const int dims=E->mesh.nsd;
  const int ends=enodes[dims];
  const int vpts=vpoints[dims];
  const int ppts=ppoints[dims];


  if(pressure < 2) {
    for(k=1;k<=vpts;k++) {       /* all of the vpoints */
      for(d=1;d<=dims;d++)  {
        x[d]=0.0;
        for(e=1;e<=dims;e++)
          dxda[d][e]=0.0;
        }

      for(d=1;d<=dims;d++)
        for(i=1;i<=ends;i++)
          x[d] += E->X[lev][m][d][E->IEN[lev][m][el].node[i]]*
                E->N.vpt[GNVINDEX(i,k)];

      for(d=1;d<=dims;d++)
	for(e=1;e<=dims;e++)
	  for(i=1;i<=ends;i++)
            dxda[d][e] += E->X[lev][m][e][E->IEN[lev][m][el].node[i]]
               * E->Nx.vpt[GNVXINDEX(d-1,i,k)];

      jacobian = determinant(dxda,E->mesh.nsd);
      dOmega->vpt[k] = jacobian;

      for(d=1;d<=dims;d++)
        for(e=1;e<=dims;e++)
          cof[d][e]=cofactor(dxda,d,e,dims);

      if (sphere)   {

        form_rtf_bc(k,x,rtf,bc);
        for(j=1;j<=ends;j++)
          for(d=1;d<=dims;d++)         {
            LGNx.vpt[GNVXINDEX(d-1,j,k)] = 0.0;
            for(e=1;e<=dims;e++)
              LGNx.vpt[GNVXINDEX(d-1,j,k)] +=
                 E->Nx.vpt[GNVXINDEX(e-1,j,k)] *cof[e][d];

            LGNx.vpt[GNVXINDEX(d-1,j,k)] /= jacobian;
            }

        for(j=1;j<=ends;j++)
          for(d=1;d<=dims;d++)         {
            GNx->vpt[GNVXINDEX(d-1,j,k)] =
                bc[d][1]*LGNx.vpt[GNVXINDEX(0,j,k)]
              + bc[d][2]*LGNx.vpt[GNVXINDEX(1,j,k)]
              + bc[d][3]*LGNx.vpt[GNVXINDEX(2,j,k)];
            }
        }
      else  {
        for(j=1;j<=ends;j++)
          for(d=1;d<=dims;d++)         {
            GNx->vpt[GNVXINDEX(d-1,j,k)] = 0.0;
            for(e=1;e<=dims;e++)
              GNx->vpt[GNVXINDEX(d-1,j,k)] +=
                 E->Nx.vpt[GNVXINDEX(e-1,j,k)] *cof[e][d];

            GNx->vpt[GNVXINDEX(d-1,j,k)] /= jacobian;
            }
        }
      }     /* end for k */
    }    /* end for pressure */

  if(pressure > 0 && pressure < 3) {
    for(k=1;k<=ppts;k++)         {   /* all of the ppoints */
      for(d=1;d<=dims;d++) {
        x[d]=0.0;
        for(e=1;e<=dims;e++)
          dxda[d][e]=0.0;
        }

      for(d=1;d<=dims;d++)
        for(i=1;i<=ends;i++)
          x[d] += E->X[lev][m][d][E->IEN[lev][m][el].node[i]]
                 *E->N.ppt[GNPINDEX(i,k)];

      for(d=1;d<=dims;d++)
	for(e=1;e<=dims;e++)
	  for(i=1;i<=ends;i++)
            dxda[d][e] += E->X[lev][m][e][E->IEN[lev][m][el].node[i]]
                     * E->Nx.ppt[GNPXINDEX(d-1,i,k)];

      jacobian = determinant(dxda,E->mesh.nsd);
      dOmega->ppt[k] = jacobian;

      for(d=1;d<=dims;d++)
        for(e=1;e<=dims;e++)
          cof[d][e]=cofactor(dxda,d,e,E->mesh.nsd);

      if (sphere)   {
        form_rtf_bc(k,x,rtf,bc);
        for(j=1;j<=ends;j++)
          for(d=1;d<=dims;d++)  {
            LGNx.ppt[GNPXINDEX(d-1,j,k)]=0.0;
            for(e=1;e<=dims;e++)
              LGNx.ppt[GNPXINDEX(d-1,j,k)] +=
                E->Nx.ppt[GNPXINDEX(e-1,j,k)]*cof[e][d];
	    LGNx.ppt[GNPXINDEX(d-1,j,k)] /= jacobian;
            }
        for(j=1;j<=ends;j++)
          for(d=1;d<=dims;d++)         {
            GNx->ppt[GNPXINDEX(d-1,j,k)]
             = bc[d][1]*LGNx.ppt[GNPXINDEX(0,j,k)]
             + bc[d][2]*LGNx.ppt[GNPXINDEX(1,j,k)]
             + bc[d][3]*LGNx.ppt[GNPXINDEX(2,j,k)];
          }
        }

      else  {
        for(j=1;j<=ends;j++)
          for(d=1;d<=dims;d++)  {
            GNx->ppt[GNPXINDEX(d-1,j,k)]=0.0;
            for(e=1;e<=dims;e++)
              GNx->ppt[GNPXINDEX(d-1,j,k)] +=
                E->Nx.ppt[GNPXINDEX(e-1,j,k)]*cof[e][d];
	    GNx->ppt[GNPXINDEX(d-1,j,k)] /= jacobian;
            }
        }

      }              /* end for k int */
    }      /* end for pressure */


  return;
}

/*   ======================================================================
     ======================================================================  */

void form_rtf_bc(k,x,rtf,bc)
 int k;
 double x[4],rtf[4][9],bc[4][4];
 {

  double myatan();

      rtf[3][k] = 1.0/sqrt(x[1]*x[1]+x[2]*x[2]+x[3]*x[3]);
      rtf[1][k] = acos(x[3]*rtf[3][k]);
      rtf[2][k] = myatan(x[2],x[1]);

      bc[1][1] = x[3]*cos(rtf[2][k]);
      bc[1][2] = x[3]*sin(rtf[2][k]);
      bc[1][3] = -sin(rtf[1][k])/rtf[3][k];
      bc[2][1] = -x[2];
      bc[2][2] = x[1];
      bc[2][3] = 0.0;
      bc[3][1] = x[1]*rtf[3][k];
      bc[3][2] = x[2]*rtf[3][k];
      bc[3][3] = x[3]*rtf[3][k];

  return;
  }


void get_side_x_cart(struct All_variables *E, double xx[4][5],
		     int el, int side, int m)
{
  double to,fo,dxdy[4][4];
  int i, node, s;
  const int oned = onedvpoints[E->mesh.nsd];

  to = E->eco[m][el].centre[1];
  fo = E->eco[m][el].centre[2];

  dxdy[1][1] = cos(to)*cos(fo);
  dxdy[1][2] = cos(to)*sin(fo);
  dxdy[1][3] = -sin(to);
  dxdy[2][1] = -sin(fo);
  dxdy[2][2] = cos(fo);
  dxdy[2][3] = 0.0;
  dxdy[3][1] = sin(to)*cos(fo);
  dxdy[3][2] = sin(to)*sin(fo);
  dxdy[3][3] = cos(to);

  for(i=1;i<=oned;i++) {     /* nodes */
    s = sidenodes[side][i];
    node = E->ien[m][el].node[s];
    xx[1][i] = E->x[m][1][node]*dxdy[1][1]
             + E->x[m][2][node]*dxdy[1][2]
             + E->x[m][3][node]*dxdy[1][3];
    xx[2][i] = E->x[m][1][node]*dxdy[2][1]
             + E->x[m][2][node]*dxdy[2][2]
             + E->x[m][3][node]*dxdy[2][3];
    xx[3][i] = E->x[m][1][node]*dxdy[3][1]
             + E->x[m][2][node]*dxdy[3][2]
             + E->x[m][3][node]*dxdy[3][3];
  }
}


/*   ======================================================================
     ======================================================================  */
void construct_surf_det (E)
     struct All_variables *E;
{

  int m,i,k,d,e,es,el;

  double jacobian;
  double determinant();
  double cofactor();

  const int oned = onedvpoints[E->mesh.nsd];

  double xx[4][5],dxda[4][4];

  for (m=1;m<=E->sphere.caps_per_proc;m++)
    for(k=1;k<=oned;k++)    { /* all of the vpoints*/
      E->surf_det[m][k] = (double *)malloc((1+E->lmesh.snel)*sizeof(double));
    }

  for (m=1;m<=E->sphere.caps_per_proc;m++)
  for (es=1;es<=E->lmesh.snel;es++)   {
    el = es * E->lmesh.elz;
    get_side_x_cart(E, xx, el, SIDE_TOP, m);

    for(k=1;k<=oned;k++)    { /* all of the vpoints*/
      for(d=1;d<=E->mesh.nsd-1;d++)
        for(e=1;e<=E->mesh.nsd-1;e++)
            dxda[d][e]=0.0;

      for(i=1;i<=oned;i++)      /* nodes */
        for(d=1;d<=E->mesh.nsd-1;d++)
          for(e=1;e<=E->mesh.nsd-1;e++)
             dxda[d][e] += xx[e][i]*E->Mx.vpt[GMVXINDEX(d-1,i,k)];

      jacobian = determinant(dxda,E->mesh.nsd-1);
      E->surf_det[m][k][es] = jacobian;
      }
    }

  return;
}



/*   ======================================================================
     surface (6 sides) determinant of boundary element
     ======================================================================  */
void construct_bdry_det(struct All_variables *E)
{

  int m,i,k,d,e,es,el,side;

  double jacobian;
  double determinant();
  double cofactor();

  const int oned = onedvpoints[E->mesh.nsd];

  double xx[4][5],dxda[4][4];

  for (m=1;m<=E->sphere.caps_per_proc;m++)
    for (side=SIDE_BEGIN; side<=SIDE_END; side++)
      for(d=1; d<=oned; d++)
	E->boundary.det[m][side][d] = (double *)malloc((1+E->boundary.nel)*sizeof(double));

  for (m=1;m<=E->sphere.caps_per_proc;m++)
    for (es=1;es<=E->boundary.nel;es++) {
      el = E->boundary.element[m][es];

      for (side=SIDE_BEGIN; side<=SIDE_END; side++) {
	get_side_x_cart(E, xx, el, side, m);

	for(k=1;k<=oned;k++) { /* all of the vpoints*/

	  for(d=1;d<=E->mesh.nsd-1;d++)
	    for(e=1;e<=E->mesh.nsd-1;e++)
	      dxda[d][e]=0.0;

	  for(i=1;i<=oned;i++) /* nodes */
	    for(d=1;d<=E->mesh.nsd-1;d++)
	      for(e=1;e<=E->mesh.nsd-1;e++)
		dxda[d][e] += xx[sidedim[side][e]][i]*E->Mx.vpt[GMVXINDEX(d-1,i,k)];

	  jacobian = determinant(dxda,E->mesh.nsd-1);
	  E->boundary.det[m][side][k][es] = jacobian;
	}

	/*
	fprintf(stderr, "Boundary det: %d %d- %e %e %e %e; sum = %e\n", el, side,
	      E->boundary.det[m][side][1][es],
	      E->boundary.det[m][side][2][es],
	      E->boundary.det[m][side][3][es],
	      E->boundary.det[m][side][4][es],
	      E->boundary.det[m][side][1][es]+
	      E->boundary.det[m][side][2][es]+
	      E->boundary.det[m][side][3][es]+
	      E->boundary.det[m][side][4][es]);
	*/
      }


    }
}



/*   ======================================================================
     ======================================================================  */
void get_global_1d_shape_fn(E,el,GM,dGammax,top,m)
     struct All_variables *E;
     int el,top,m;
     struct Shape_function1 *GM;
     struct Shape_function1_dA *dGammax;
{
  int ii,i,k,d,e;

  double jacobian;
  double determinant();

  const int oned = onedvpoints[E->mesh.nsd];

  double xx[4][5],dxda[4][4];

  for (ii=0;ii<=top;ii++)   {   /* ii=0 for bottom and ii=1 for top */

    get_side_x_cart(E, xx, el, ii+1, m);

    for(k=1;k<=oned;k++)    { /* all of the vpoints*/
      for(d=1;d<=E->mesh.nsd-1;d++)
	for(e=1;e<=E->mesh.nsd-1;e++)
	  dxda[d][e]=0.0;

      for(i=1;i<=oned;i++)      /* nodes */
	for(d=1;d<=E->mesh.nsd-1;d++)
	  for(e=1;e<=E->mesh.nsd-1;e++)
	    dxda[d][e] += xx[e][i]*E->Mx.vpt[GMVXINDEX(d-1,i,k)];

      jacobian = determinant(dxda,E->mesh.nsd-1);
      dGammax->vpt[GMVGAMMA(ii,k)] = jacobian;
    }
  }

  return;
}


/*   ======================================================================
     For calculating pressure boundary term --- Choi, 11/13/02
     ======================================================================  */
void get_global_side_1d_shape_fn(E,el,GM,GMx,dGamma,side,m)
     struct All_variables *E;
     int el,side,m;
     struct Shape_function1 *GM;
     struct Shape_function1_dx *GMx;
     struct Shape_function_side_dA *dGamma;
{
  int i,k,d,e;

  double jacobian;
  double determinant();

  const int oned = onedvpoints[E->mesh.nsd];
  double xx[4][5],dxda[4][4];

  get_side_x_cart(E, xx, el, side, m);

  for(k=1;k<=oned;k++)    {

    for(d=1;d<=E->mesh.nsd-1;d++)
      for(e=1;e<=E->mesh.nsd-1;e++)
	dxda[d][e]=0.0;

    for(i=1;i<=oned;i++) {
      for(d=1;d<=E->mesh.nsd-1;d++)
	for(e=1;e<=E->mesh.nsd-1;e++) {
	  dxda[d][e] += xx[sidedim[side][e]][i]*E->Mx.vpt[GMVXINDEX(d-1,i,k)];
	}
    }

    jacobian = determinant(dxda,E->mesh.nsd-1);
    dGamma->vpt[k] = jacobian;
  }

  return;
}


/* ====================================================   */

void construct_c3x3matrix_el (E,el,cc,ccx,lev,m,pressure)
     struct All_variables *E;
     struct CC *cc;
     struct CCX *ccx;
     int lev,el,m,pressure;
{
  int a,i,j,k,d;
  double cofactor(),myatan();
  double x[4],u[4][4],ux[3][4][4],ua[4][4];
  double costt,cosff,sintt,sinff,rr,tt,ff;

  const int dims=E->mesh.nsd;
  const int ends=enodes[dims];
  const int vpts=vpoints[dims];
  const int ppts=ppoints[dims];

  if (pressure==0)           {
    for(k=1;k<=vpts;k++)           {       /* all of the vpoints */
      for(d=1;d<=dims;d++)
          x[d]=0.0;

      for(d=1;d<=dims;d++)
          for(a=1;a<=ends;a++)
            x[d] += E->X[lev][m][d][E->IEN[lev][m][el].node[a]]
                   *E->N.vpt[GNVINDEX(a,k)];

      rr = sqrt(x[1]*x[1]+x[2]*x[2]+x[3]*x[3]);
      tt = acos(x[3]/rr);
      ff = myatan(x[2],x[1]);

      costt = cos(tt);
      cosff = cos(ff);
      sintt = sin(tt);
      sinff = sin(ff);

      u[1][1] = costt*cosff; u[1][2] = costt*sinff;  u[1][3] =-sintt;
      u[2][1] =-sinff;       u[2][2] = cosff;        u[2][3] = 0.0;
      u[3][1] = sintt*cosff; u[3][2] = sintt*sinff;  u[3][3] = costt;

      ux[1][1][1] =-sintt*cosff;  ux[1][1][2] =-sintt*sinff;  ux[1][1][3] =-costt;
      ux[2][1][1] =-costt*sinff;  ux[2][1][2] = costt*cosff;  ux[2][1][3] =0.0;
      ux[1][2][1] =0.0;           ux[1][2][2] = 0.0;          ux[1][2][3] =0.0;
      ux[2][2][1] =-cosff;        ux[2][2][2] =-sinff;        ux[2][2][3] =0.0;
      ux[1][3][1] = costt*cosff;  ux[1][3][2] = costt*sinff;  ux[1][3][3] =-sintt;
      ux[2][3][1] =-sintt*sinff;  ux[2][3][2] = sintt*cosff;  ux[2][3][3] =0.0;

      for(a=1;a<=ends;a++)   {
          tt = E->SX[lev][m][1][E->IEN[lev][m][el].node[a]];
          ff = E->SX[lev][m][2][E->IEN[lev][m][el].node[a]];
          costt = cos(tt);
          cosff = cos(ff);
          sintt = sin(tt);
          sinff = sin(ff);

          ua[1][1] = costt*cosff; ua[1][2] = costt*sinff;  ua[1][3] =-sintt;
          ua[2][1] =-sinff;       ua[2][2] = cosff;        ua[2][3] = 0.0;
          ua[3][1] = sintt*cosff; ua[3][2] = sintt*sinff;  ua[3][3] = costt;

          for (i=1;i<=dims;i++)
            for (j=1;j<=dims;j++)   {
              cc->vpt[BVINDEX(i,j,a,k)] =
                    ua[j][1]*u[i][1]+ua[j][2]*u[i][2]+ua[j][3]*u[i][3];
              ccx->vpt[BVXINDEX(i,j,1,a,k)] =
                    ua[j][1]*ux[1][i][1]+ua[j][2]*ux[1][i][2]+ua[j][3]*ux[1][i][3];
              ccx->vpt[BVXINDEX(i,j,2,a,k)] =
                    ua[j][1]*ux[2][i][1]+ua[j][2]*ux[2][i][2]+ua[j][3]*ux[2][i][3];
              }
          }      /* end for local node */

        }        /* end for int points */
     }        /* end if */

   else if (pressure)  {

      for(k=1;k<=ppts;k++)           {       /* all of the ppoints */
        for(d=1;d<=dims;d++)
          x[d]=0.0;

        for(d=1;d<=dims;d++)
          for(a=1;a<=ends;a++)
            x[d] += E->X[lev][m][d][E->IEN[lev][m][el].node[a]]
                   *E->N.ppt[GNPINDEX(a,k)];

        rr = sqrt(x[1]*x[1]+x[2]*x[2]+x[3]*x[3]);
        tt = acos(x[3]/rr);
        ff = myatan(x[2],x[1]);

        costt = cos(tt);
        cosff = cos(ff);
        sintt = sin(tt);
        sinff = sin(ff);

        u[1][1] = costt*cosff; u[1][2] = costt*sinff;  u[1][3] =-sintt;
        u[2][1] =-sinff;       u[2][2] = cosff;        u[2][3] = 0.0;
        u[3][1] = sintt*cosff; u[3][2] = sintt*sinff;  u[3][3] = costt;

        ux[1][1][1] =-sintt*cosff;  ux[1][1][2] =-sintt*sinff;  ux[1][1][3] =-costt;
        ux[2][1][1] =-costt*sinff;  ux[2][1][2] = costt*cosff;  ux[2][1][3] =0.0;
        ux[1][2][1] =0.0;           ux[1][2][2] = 0.0;          ux[1][2][3] =0.0;
        ux[2][2][1] =-cosff;        ux[2][2][2] =-sinff;        ux[2][2][3] =0.0;
        ux[1][3][1] = costt*cosff;  ux[1][3][2] = costt*sinff;  ux[1][3][3] =-sintt;
        ux[2][3][1] =-sintt*sinff;  ux[2][3][2] = sintt*cosff;  ux[2][3][3] =0.0;

        for(a=1;a<=ends;a++)   {
          tt = E->SX[lev][m][1][E->IEN[lev][m][el].node[a]];
          ff = E->SX[lev][m][2][E->IEN[lev][m][el].node[a]];
          costt = cos(tt);
          cosff = cos(ff);
          sintt = sin(tt);
          sinff = sin(ff);

          ua[1][1] = costt*cosff; ua[1][2] = costt*sinff;  ua[1][3] =-sintt;
          ua[2][1] =-sinff;       ua[2][2] = cosff;        ua[2][3] = 0.0;
          ua[3][1] = sintt*cosff; ua[3][2] = sintt*sinff;  ua[3][3] = costt;

          for (i=1;i<=dims;i++)
            for (j=1;j<=dims;j++)   {
              cc->ppt[BPINDEX(i,j,a,k)] =
                    ua[j][1]*u[i][1]+ua[j][2]*u[i][2]+ua[j][3]*u[i][3];
              ccx->ppt[BPXINDEX(i,j,1,a,k)] =
                    ua[j][1]*ux[1][i][1]+ua[j][2]*ux[1][i][2]+ua[j][3]*ux[1][i][3];
              ccx->ppt[BPXINDEX(i,j,2,a,k)] =
                    ua[j][1]*ux[2][i][1]+ua[j][2]*ux[2][i][2]+ua[j][3]*ux[2][i][3];
              }

          }      /* end for local node */

        }        /* end for int points */


      }         /* end if pressure  */

   return;
  }


void construct_side_c3x3matrix_el(struct All_variables *E,int el,
				  struct CC *cc,struct CCX *ccx,
				  int lev,int m,int pressure,int side)
{
  int a,aa,i,j,k,d;
  double cofactor(),myatan();
  double x[4],u[4][4],ux[3][4][4],ua[4][4];
  double costt,cosff,sintt,sinff,rr,tt,ff;

  const int dims=E->mesh.nsd;
  const int ends=enodes[dims-1];
  const int vpts=onedvpoints[dims];
  const int ppts=ppoints[dims];

  if(pressure==0) {
    for(k=1;k<=vpts;k++) {       /* all of the vpoints */
      for(d=1;d<=dims;d++)
	x[d]=0.0;
      for(d=1;d<=dims;d++)
	for(aa=1;aa<=ends;aa++) {
	  a=sidenodes[side][aa];
	  x[d] += E->X[lev][m][d][E->IEN[lev][m][el].node[a]]
	    *E->M.vpt[GMVINDEX(aa,k)];

	}

      rr = sqrt(x[1]*x[1]+x[2]*x[2]+x[3]*x[3]);
      tt = acos(x[3]/rr);
      ff = myatan(x[2],x[1]);

      costt = cos(tt);
      cosff = cos(ff);
      sintt = sin(tt);
      sinff = sin(ff);

      u[1][1] = costt*cosff; u[1][2] = costt*sinff;  u[1][3] =-sintt;
      u[2][1] =-sinff;       u[2][2] = cosff;        u[2][3] = 0.0;
      u[3][1] = sintt*cosff; u[3][2] = sintt*sinff;  u[3][3] = costt;

      ux[1][1][1] =-sintt*cosff;  ux[1][1][2] =-sintt*sinff;  ux[1][1][3] =-costt;
      ux[2][1][1] =-costt*sinff;  ux[2][1][2] = costt*cosff;  ux[2][1][3] =0.0;
      ux[1][2][1] =0.0;           ux[1][2][2] = 0.0;          ux[1][2][3] =0.0;
      ux[2][2][1] =-cosff;        ux[2][2][2] =-sinff;        ux[2][2][3] =0.0;
      ux[1][3][1] = costt*cosff;  ux[1][3][2] = costt*sinff;  ux[1][3][3] =-sintt;
      ux[2][3][1] =-sintt*sinff;  ux[2][3][2] = sintt*cosff;  ux[2][3][3] =0.0;

      for(aa=1;aa<=ends;aa++) {
	a=sidenodes[side][aa];
	tt = E->SX[lev][m][1][E->IEN[lev][m][el].node[a]];
	ff = E->SX[lev][m][2][E->IEN[lev][m][el].node[a]];
	costt = cos(tt);
	cosff = cos(ff);
	sintt = sin(tt);
	sinff = sin(ff);

	ua[1][1] = costt*cosff; ua[1][2] = costt*sinff;  ua[1][3] =-sintt;
	ua[2][1] =-sinff;       ua[2][2] = cosff;        ua[2][3] = 0.0;
	ua[3][1] = sintt*cosff; ua[3][2] = sintt*sinff;  ua[3][3] = costt;

	for (i=1;i<=dims;i++)
	  for (j=1;j<=dims;j++)   {
	    cc->vpt[BVINDEX(i,j,a,k)] =
	      ua[j][1]*u[i][1]+ua[j][2]*u[i][2]+ua[j][3]*u[i][3];
	    ccx->vpt[BVXINDEX(i,j,1,a,k)] =
	      ua[j][1]*ux[1][i][1]+ua[j][2]*ux[1][i][2]+ua[j][3]*ux[1][i][3];
	    ccx->vpt[BVXINDEX(i,j,2,a,k)] =
	      ua[j][1]*ux[2][i][1]+ua[j][2]*ux[2][i][2]+ua[j][3]*ux[2][i][3];
	  }

      }      /* end for local node */
    }        /* end for int points */
  }    /* end if */
  else {
    for(k=1;k<=ppts;k++) {       /* all of the ppoints */
      for(d=1;d<=E->mesh.nsd;d++)
       	x[d]=0.0;
      for(a=1;a<=ends;a++) {
       	aa=sidenodes[side][a];
       	x[d] += E->X[lev][m][d][E->IEN[lev][m][el].node[aa]]
       	  *E->M.ppt[GMPINDEX(a,k)];
      }
      rr = sqrt(x[1]*x[1]+x[2]*x[2]+x[3]*x[3]);
      tt = acos(x[3]/rr);
      ff = myatan(x[2],x[1]);

      costt = cos(tt);
      cosff = cos(ff);
      sintt = sin(tt);
      sinff = sin(ff);

      u[1][1] = costt*cosff; u[1][2] = costt*sinff;  u[1][3] =-sintt;
      u[2][1] =-sinff;       u[2][2] = cosff;        u[2][3] = 0.0;
      u[3][1] = sintt*cosff; u[3][2] = sintt*sinff;  u[3][3] = costt;

      ux[1][1][1] =-sintt*cosff;  ux[1][1][2] =-sintt*sinff;  ux[1][1][3] =-costt;
      ux[2][1][1] =-costt*sinff;  ux[2][1][2] = costt*cosff;  ux[2][1][3] =0.0;
      ux[1][2][1] =0.0;           ux[1][2][2] = 0.0;          ux[1][2][3] =0.0;
      ux[2][2][1] =-cosff;        ux[2][2][2] =-sinff;        ux[2][2][3] =0.0;
      ux[1][3][1] = costt*cosff;  ux[1][3][2] = costt*sinff;  ux[1][3][3] =-sintt;
      ux[2][3][1] =-sintt*sinff;  ux[2][3][2] = sintt*cosff;  ux[2][3][3] =0.0;

      for(a=1;a<=ends;a++)   {
	aa=sidenodes[side][a];
	tt = E->SX[lev][m][1][E->IEN[lev][m][el].node[aa]];
	ff = E->SX[lev][m][2][E->IEN[lev][m][el].node[aa]];
	costt = cos(tt);
	cosff = cos(ff);
	sintt = sin(tt);
	sinff = sin(ff);

	ua[1][1] = costt*cosff; ua[1][2] = costt*sinff;  ua[1][3] =-sintt;
	ua[2][1] =-sinff;       ua[2][2] = cosff;        ua[2][3] = 0.0;
	ua[3][1] = sintt*cosff; ua[3][2] = sintt*sinff;  ua[3][3] = costt;

	for (i=1;i<=E->mesh.nsd;i++) {
	  for (j=1;j<=E->mesh.nsd;j++) {
	    cc->ppt[BPINDEX(i,j,a,k)] =
	      ua[j][1]*u[i][1]+ua[j][2]*u[i][2]+ua[j][3]*u[i][3];
	    ccx->ppt[BPXINDEX(i,j,1,a,k)] =
	      ua[j][1]*ux[1][i][1]+ua[j][2]*ux[1][i][2]+ua[j][3]*ux[1][i][3];
	    ccx->ppt[BPXINDEX(i,j,2,a,k)] =
	      ua[j][1]*ux[2][i][1]+ua[j][2]*ux[2][i][2]+ua[j][3]*ux[2][i][3];
	  }
	}
      }      /* end for local node */
    }      /* end for int points */
  }      /* end if pressure  */

  return;
}


/* ======================================= */
void construct_c3x3matrix(E)
     struct All_variables *E;
{
  int m,a,i,j,k,d,es,el,nel_surface,lev;
  double cofactor(),myatan();
  double x[4],u[4][4],ux[3][4][4],ua[4][4];
  double costt,cosff,sintt,sinff,rr,tt,ff;

  const int dims=E->mesh.nsd;
  const int ends=enodes[dims];
  const int vpts=vpoints[dims];
  const int ppts=ppoints[dims];

 for (lev=E->mesh.gridmin;lev<=E->mesh.gridmax;lev++)
  for (m=1;m<=E->sphere.caps_per_proc;m++)   {
    nel_surface = E->lmesh.NEL[lev]/E->lmesh.ELZ[lev];
    for (es=1;es<=nel_surface;es++)        {

      el = es*E->lmesh.ELZ[lev];

      for(k=1;k<=vpts;k++)           {       /* all of the vpoints */
        for(d=1;d<=dims;d++)
          x[d]=0.0;

        for(d=1;d<=dims;d++)
          for(a=1;a<=ends;a++)
            x[d] += E->X[lev][m][d][E->IEN[lev][m][el].node[a]]
                   *E->N.vpt[GNVINDEX(a,k)];

        rr = sqrt(x[1]*x[1]+x[2]*x[2]+x[3]*x[3]);
        tt = acos(x[3]/rr);
        ff = myatan(x[2],x[1]);

        costt = cos(tt);
        cosff = cos(ff);
        sintt = sin(tt);
        sinff = sin(ff);

        u[1][1] = costt*cosff; u[1][2] = costt*sinff;  u[1][3] =-sintt;
        u[2][1] =-sinff;       u[2][2] = cosff;        u[2][3] = 0.0;
        u[3][1] = sintt*cosff; u[3][2] = sintt*sinff;  u[3][3] = costt;

        ux[1][1][1] =-sintt*cosff;  ux[1][1][2] =-sintt*sinff;  ux[1][1][3] =-costt;
        ux[2][1][1] =-costt*sinff;  ux[2][1][2] = costt*cosff;  ux[2][1][3] =0.0;
        ux[1][2][1] =0.0;           ux[1][2][2] = 0.0;          ux[1][2][3] =0.0;
        ux[2][2][1] =-cosff;        ux[2][2][2] =-sinff;        ux[2][2][3] =0.0;
        ux[1][3][1] = costt*cosff;  ux[1][3][2] = costt*sinff;  ux[1][3][3] =-sintt;
        ux[2][3][1] =-sintt*sinff;  ux[2][3][2] = sintt*cosff;  ux[2][3][3] =0.0;

        for(a=1;a<=ends;a++)   {
          tt = E->SX[lev][m][1][E->IEN[lev][m][el].node[a]];
          ff = E->SX[lev][m][2][E->IEN[lev][m][el].node[a]];
          costt = cos(tt);
          cosff = cos(ff);
          sintt = sin(tt);
          sinff = sin(ff);

          ua[1][1] = costt*cosff; ua[1][2] = costt*sinff;  ua[1][3] =-sintt;
          ua[2][1] =-sinff;       ua[2][2] = cosff;        ua[2][3] = 0.0;
          ua[3][1] = sintt*cosff; ua[3][2] = sintt*sinff;  ua[3][3] = costt;

          for (i=1;i<=dims;i++)
            for (j=1;j<=dims;j++)   {
              E->CC[lev][m][es].vpt[BVINDEX(i,j,a,k)] =
                    ua[j][1]*u[i][1]+ua[j][2]*u[i][2]+ua[j][3]*u[i][3];
              E->CCX[lev][m][es].vpt[BVXINDEX(i,j,1,a,k)] =
                    ua[j][1]*ux[1][i][1]+ua[j][2]*ux[1][i][2]+ua[j][3]*ux[1][i][3];
              E->CCX[lev][m][es].vpt[BVXINDEX(i,j,2,a,k)] =
                    ua[j][1]*ux[2][i][1]+ua[j][2]*ux[2][i][2]+ua[j][3]*ux[2][i][3];
              }
          }      /* end for local node */

        }        /* end for int points */

      for(k=1;k<=ppts;k++)           {       /* all of the ppoints */
        for(d=1;d<=dims;d++)
          x[d]=0.0;

        for(d=1;d<=dims;d++)
          for(a=1;a<=ends;a++)
            x[d] += E->X[lev][m][d][E->IEN[lev][m][el].node[a]]
                   *E->N.ppt[GNPINDEX(a,k)];

        rr = sqrt(x[1]*x[1]+x[2]*x[2]+x[3]*x[3]);
        tt = acos(x[3]/rr);
        ff = myatan(x[2],x[1]);

        costt = cos(tt);
        cosff = cos(ff);
        sintt = sin(tt);
        sinff = sin(ff);

        u[1][1] = costt*cosff; u[1][2] = costt*sinff;  u[1][3] =-sintt;
        u[2][1] =-sinff;       u[2][2] = cosff;        u[2][3] = 0.0;
        u[3][1] = sintt*cosff; u[3][2] = sintt*sinff;  u[3][3] = costt;

        ux[1][1][1] =-sintt*cosff;  ux[1][1][2] =-sintt*sinff;  ux[1][1][3] =-costt;
        ux[2][1][1] =-costt*sinff;  ux[2][1][2] = costt*cosff;  ux[2][1][3] =0.0;
        ux[1][2][1] =0.0;           ux[1][2][2] = 0.0;          ux[1][2][3] =0.0;
        ux[2][2][1] =-cosff;        ux[2][2][2] =-sinff;        ux[2][2][3] =0.0;
        ux[1][3][1] = costt*cosff;  ux[1][3][2] = costt*sinff;  ux[1][3][3] =-sintt;
        ux[2][3][1] =-sintt*sinff;  ux[2][3][2] = sintt*cosff;  ux[2][3][3] =0.0;

        for(a=1;a<=ends;a++)   {
          tt = E->SX[lev][m][1][E->IEN[lev][m][el].node[a]];
          ff = E->SX[lev][m][2][E->IEN[lev][m][el].node[a]];
          costt = cos(tt);
          cosff = cos(ff);
          sintt = sin(tt);
          sinff = sin(ff);

          ua[1][1] = costt*cosff; ua[1][2] = costt*sinff;  ua[1][3] =-sintt;
          ua[2][1] =-sinff;       ua[2][2] = cosff;        ua[2][3] = 0.0;
          ua[3][1] = sintt*cosff; ua[3][2] = sintt*sinff;  ua[3][3] = costt;

          for (i=1;i<=dims;i++)
            for (j=1;j<=dims;j++)   {
              E->CC[lev][m][es].ppt[BPINDEX(i,j,a,k)] =
                    ua[j][1]*u[i][1]+ua[j][2]*u[i][2]+ua[j][3]*u[i][3];
              E->CCX[lev][m][es].ppt[BPXINDEX(i,j,1,a,k)] =
                    ua[j][1]*ux[1][i][1]+ua[j][2]*ux[1][i][2]+ua[j][3]*ux[1][i][3];
              E->CCX[lev][m][es].ppt[BPXINDEX(i,j,2,a,k)] =
                    ua[j][1]*ux[2][i][1]+ua[j][2]*ux[2][i][2]+ua[j][3]*ux[2][i][3];
              }

          }      /* end for local node */

        }        /* end for int points */


      }         /* end for es */
    }           /* end for m */

   return;
   }



/*  ==========================================
    construct the lumped mass matrix. The full
    matrix is the FE integration of the density
    field. The lumped version is the diagonal
    matrix obtained by letting the shape function
    Na be delta(a,b)
    ========================================== */

void mass_matrix(E)
     struct All_variables *E;

{ int m,node,i,nint,e,lev;
  int n[9];
  void get_global_shape_fn();
  double myatan(),rtf[4][9],area,centre[4],temp[9],dx1,dx2,dx3;
  struct Shape_function GN;
  struct Shape_function_dA dOmega;
  struct Shape_function_dx GNx;

  const int vpts=vpoints[E->mesh.nsd];
  const int sphere_key=1;

  /* ECO .size can also be defined here */

 for(lev=E->mesh.levmin;lev<=E->mesh.levmax;lev++)  {
  for (m=1;m<=E->sphere.caps_per_proc;m++)   {

    for(node=1;node<=E->lmesh.NNO[lev];node++)
      E->MASS[lev][m][node] = 0.0;

    for(e=1;e<=E->lmesh.NEL[lev];e++)  {

      get_global_shape_fn(E,e,&GN,&GNx,&dOmega,0,sphere_key,rtf,lev,m);

      area = centre[1] = centre[2] = centre[3] = 0.0;

      for(node=1;node<=enodes[E->mesh.nsd];node++)
           n[node] = E->IEN[lev][m][e].node[node];

      for(i=1;i<=E->mesh.nsd;i++)  {
        for(node=1;node<=enodes[E->mesh.nsd];node++)
           centre[i] += E->X[lev][m][i][E->IEN[lev][m][e].node[node]];

    	centre[i] = centre[i]/enodes[E->mesh.nsd];
        }     /* end for i */

      dx3 = sqrt(centre[1]*centre[1]+centre[2]*centre[2]+centre[3]*centre[3]);
      dx1 = acos( centre[3]/dx3 );
      dx2 = myatan(centre[2],centre[1]);

      E->ECO[lev][m][e].centre[1] = dx1;
      E->ECO[lev][m][e].centre[2] = dx2;
      E->ECO[lev][m][e].centre[3] = dx3;

      dx1 = max( fabs(E->SX[lev][m][1][n[3]]-E->SX[lev][m][1][n[1]]),
                 fabs(E->SX[lev][m][1][n[2]]-E->SX[lev][m][1][n[4]]) );
      E->ECO[lev][m][e].size[1] = dx1*E->ECO[lev][m][e].centre[3];

      dx1 = fabs(E->SX[lev][m][2][n[3]]-E->SX[lev][m][2][n[1]]);
      if (dx1>M_PI)
        dx1 = min(E->SX[lev][m][2][n[3]],E->SX[lev][m][2][n[1]]) + 2.0*M_PI -
              max(E->SX[lev][m][2][n[3]],E->SX[lev][m][2][n[1]]) ;

      dx2 = fabs(E->SX[lev][m][2][n[2]]-E->SX[lev][m][2][n[4]]);
      if (dx2>M_PI)
        dx2 = min(E->SX[lev][m][2][n[2]],E->SX[lev][m][2][n[4]]) + 2.0*M_PI -
              max(E->SX[lev][m][2][n[2]],E->SX[lev][m][2][n[4]]) ;

      dx2 = max(dx1,dx2);

      E->ECO[lev][m][e].size[2] = dx2*E->ECO[lev][m][e].centre[3]
                                 *sin(E->ECO[lev][m][e].centre[1]);

      dx3 = 0.25*(
            fabs(E->SX[lev][m][3][n[5]]+E->SX[lev][m][3][n[6]]
                +E->SX[lev][m][3][n[7]]+E->SX[lev][m][3][n[8]]
                -E->SX[lev][m][3][n[1]]-E->SX[lev][m][3][n[2]]
                -E->SX[lev][m][3][n[3]]-E->SX[lev][m][3][n[4]]));

      E->ECO[lev][m][e].size[3] = dx3;

      for(nint=1;nint<=vpts;nint++)
        area += g_point[nint].weight[E->mesh.nsd-1] * dOmega.vpt[nint];
      E->ECO[lev][m][e].area = area;

      for(node=1;node<=enodes[E->mesh.nsd];node++)  {
        temp[node] = 0.0;
        for(nint=1;nint<=vpts;nint++)
          temp[node] += dOmega.vpt[nint]*g_point[nint].weight[E->mesh.nsd-1]
                       *E->N.vpt[GNVINDEX(node,nint)];       /* int Na dV */
        }

      for(node=1;node<=enodes[E->mesh.nsd];node++)
         E->MASS[lev][m][E->IEN[lev][m][e].node[node]] += temp[node];

      for(node=1;node<=enodes[E->mesh.nsd];node++)
         E->TWW[lev][m][e].node[node] = temp[node];


      } /* end of ele*/

    }        /* m */

  if (E->control.NMULTIGRID||E->control.EMULTIGRID||E->mesh.levmax==lev)
     (E->exchange_node_f)(E,E->MASS[lev],lev);

  for (m=1;m<=E->sphere.caps_per_proc;m++)
    for(node=1;node<=E->lmesh.NNO[lev];node++)
      E->MASS[lev][m][node] = 1.0/E->MASS[lev][m][node];

   }        /* lev */


  /* compute volume of this processor mesh and the whole mesh */
  E->lmesh.volume = 0;
  E->mesh.volume = 0;

  for (m=1;m<=E->sphere.caps_per_proc;m++)
      for(e=1;e<=E->lmesh.nel;e++)
          E->lmesh.volume += E->eco[m][e].area;

  MPI_Allreduce(&E->lmesh.volume, &E->mesh.volume, 1, MPI_DOUBLE, MPI_SUM, E->parallel.world);



 if (E->control.verbose)  {
   fprintf(E->fp_out, "rank=%d my_volume=%e total_volume=%e\n",
           E->parallel.me, E->lmesh.volume, E->mesh.volume);

   for(lev=E->mesh.levmin;lev<=E->mesh.levmax;lev++)  {
     fprintf(E->fp_out,"output_mass lev=%d\n",lev);
     for (m=1;m<=E->sphere.caps_per_proc;m++)   {
       fprintf(E->fp_out,"m=%d %d \n",E->sphere.capid[m],m);
       for(e=1;e<=E->lmesh.NEL[lev];e++)
         fprintf(E->fp_out,"%d %g \n",e,E->ECO[lev][m][e].area);
       for (node=1;node<=E->lmesh.NNO[lev];node++)
	 fprintf(E->fp_out,"Mass[%d]= %g \n",node,E->MASS[lev][m][node]);
     }
   }
   fflush(E->fp_out);
 }

 return;
}


/* version */
/* $Id$ */

/* End of file  */
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