https://github.com/geodynamics/citcoms
Tip revision: b5721c162b1b01c9fdbfb544f8d60bf3742dd916 authored by Eric Heien on 02 August 2011, 16:52:33 UTC
Further work in converting tracer code to C++
Further work in converting tracer code to C++
Tip revision: b5721c1
Full_boundary_conditions.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 "element_definitions.h"
#include "global_defs.h"
#include <math.h>
#include "lith_age.h"
#ifdef USE_GGRD
#include "ggrd_handling.h"
#endif
/* ========================================== */
static void horizontal_bc(struct All_variables *,float *[],int,int,float,unsigned int,char,int,int);
void assign_internal_bc(struct All_variables *,int );
static void velocity_apply_periodic_bcs();
static void temperature_apply_periodic_bcs();
void read_temperature_boundary_from_file(struct All_variables *);
void read_velocity_boundary_from_file(struct All_variables *);
/* ========================================== */
void full_velocity_boundary_conditions(struct All_variables *E)
{
void velocity_imp_vert_bc();
void velocity_apply_periodicapply_periodic_bcs();
void apply_side_sbc();
int j,noz,lv,k,node;
for(lv=E->mesh.gridmax;lv>=E->mesh.gridmin;lv--)
for (j=1;j<=E->sphere.caps_per_proc;j++) {
noz = E->mesh.NOZ[lv];
if(E->mesh.topvbc != 1) { /* free slip top */
horizontal_bc(E,E->sphere.cap[j].VB,noz,1,0.0,VBX,0,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,noz,3,0.0,VBZ,1,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,noz,2,0.0,VBY,0,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,noz,1,E->control.VBXtopval,SBX,1,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,noz,3,0.0,SBZ,0,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,noz,2,E->control.VBYtopval,SBY,1,lv,j);
}
if(E->mesh.botvbc != 1) { /* free slip bottom */
horizontal_bc(E,E->sphere.cap[j].VB,1,1,0.0,VBX,0,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,1,3,0.0,VBZ,1,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,1,2,0.0,VBY,0,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,1,1,E->control.VBXbotval,SBX,1,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,1,3,0.0,SBZ,0,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,1,2,E->control.VBYbotval,SBY,1,lv,j);
}
if(E->mesh.topvbc == 1) { /* velocity/no slip BC */
horizontal_bc(E,E->sphere.cap[j].VB,noz,1,E->control.VBXtopval,VBX,1,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,noz,3,0.0,VBZ,1,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,noz,2,E->control.VBYtopval,VBY,1,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,noz,1,0.0,SBX,0,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,noz,3,0.0,SBZ,0,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,noz,2,0.0,SBY,0,lv,j);
if(E->control.vbcs_file){ /* this should either only be called
once, or the input routines need
to be told what to do for each
multigrid level and cap. it might
be easiest to call only once and
have routines deal with multigrid
*/
if((lv == E->mesh.gridmin) && (j == E->sphere.caps_per_proc))
read_velocity_boundary_from_file(E);
}
}
if(E->mesh.botvbc == 1) { /* velocity bottom BC */
horizontal_bc(E,E->sphere.cap[j].VB,1,1,E->control.VBXbotval,VBX,1,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,1,3,0.0,VBZ,1,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,1,2,E->control.VBYbotval,VBY,1,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,1,1,0.0,SBX,0,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,1,3,0.0,SBZ,0,lv,j);
horizontal_bc(E,E->sphere.cap[j].VB,1,2,0.0,SBY,0,lv,j);
}
} /* end for j and lv */
if(E->control.side_sbcs)
apply_side_sbc(E);
/* if(E->control.verbose) { */
/* for (j=1;j<=E->sphere.caps_per_proc;j++) */
/* for (node=1;node<=E->lmesh.nno;node++) */
/* fprintf(E->fp_out,"m=%d VB== %d %g %g %g flag %u %u %u\n",j,node,E->sphere.cap[j].VB[1][node],E->sphere.cap[j].VB[2][node],E->sphere.cap[j].VB[3][node],E->node[j][node]&VBX,E->node[j][node]&VBY,E->node[j][node]&VBZ); */
/* fflush(E->fp_out); */
/* } */
/* If any imposed internal velocity structure it goes here */
/*
apply stress or velocity boundary conditions, read from file
settings are to be implemented in those routines (will only do
anything at present, if E->mesh.toplayerbc != 0
*/
assign_internal_bc(E,1);
#ifdef USE_GGRD
if(E->control.ggrd.vtop_control) /* assign stress or velocity BCs */
ggrd_read_vtop_from_file(E,1);
#endif
return; }
/* ========================================== */
void full_temperature_boundary_conditions(struct All_variables *E)
{
int j,lev,noz;
lev = E->mesh.levmax;
for (j=1;j<=E->sphere.caps_per_proc;j++) {
noz = E->mesh.noz;
if(E->mesh.toptbc == 1) {
horizontal_bc(E,E->sphere.cap[j].TB,noz,3,E->control.TBCtopval,TBZ,1,lev,j);
horizontal_bc(E,E->sphere.cap[j].TB,noz,3,E->control.TBCtopval,FBZ,0,lev,j);
if(E->control.tbcs_file)
read_temperature_boundary_from_file(E);
}
else {
horizontal_bc(E,E->sphere.cap[j].TB,noz,3,E->control.TBCtopval,TBZ,0,lev,j);
horizontal_bc(E,E->sphere.cap[j].TB,noz,3,E->control.TBCtopval,FBZ,1,lev,j);
}
if(E->mesh.bottbc == 1) {
horizontal_bc(E,E->sphere.cap[j].TB,1,3,E->control.TBCbotval,TBZ,1,lev,j);
horizontal_bc(E,E->sphere.cap[j].TB,1,3,E->control.TBCbotval,FBZ,0,lev,j);
}
else {
horizontal_bc(E,E->sphere.cap[j].TB,1,3,E->control.TBCbotval,TBZ,0,lev,j);
horizontal_bc(E,E->sphere.cap[j].TB,1,3,E->control.TBCbotval,FBZ,1,lev,j);
}
if(E->control.lith_age_time==1) {
/* set the regions in which to use lithosphere files to determine temperature
note that this is called if the lithosphere age in inputted every time step
OR it is only maintained in the boundary regions */
lith_age_temperature_bound_adj(E,lev);
}
} /* end for j */
temperatures_conform_bcs(E);
E->temperatures_conform_bcs = temperatures_conform_bcs;
return; }
/* ========================================================= */
static void horizontal_bc(struct All_variables *E,float *BC[],int ROW,int dirn,float value,
unsigned int mask,char onoff,int level,int m)
{
int i,j,node,rowl;
/* safety feature */
if(dirn > E->mesh.nsd)
return;
if (ROW==1)
rowl = 1;
else
rowl = E->lmesh.NOZ[level];
if ( ( (ROW==1) && (E->parallel.me_loc[3]==0) ) ||
( (ROW==E->mesh.NOZ[level]) && (E->parallel.me_loc[3]==E->parallel.nprocz-1) ) ) {
/* turn bc marker to zero */
if (onoff == 0) {
for(j=1;j<=E->lmesh.NOY[level];j++)
for(i=1;i<=E->lmesh.NOX[level];i++) {
node = rowl+(i-1)*E->lmesh.NOZ[level]+(j-1)*E->lmesh.NOX[level]*E->lmesh.NOZ[level];
E->NODE[level][m][node] = E->NODE[level][m][node] & (~ mask);
} /* end for loop i & j */
}
/* turn bc marker to one */
else {
for(j=1;j<=E->lmesh.NOY[level];j++)
for(i=1;i<=E->lmesh.NOX[level];i++) {
node = rowl+(i-1)*E->lmesh.NOZ[level]+(j-1)*E->lmesh.NOX[level]*E->lmesh.NOZ[level];
E->NODE[level][m][node] = E->NODE[level][m][node] | (mask);
if(level==E->mesh.levmax) /* NB */
BC[dirn][node] = value;
} /* end for loop i & j */
}
} /* end for if ROW */
return;
}
static void velocity_apply_periodic_bcs(struct All_variables *E)
{
fprintf(E->fp,"Periodic boundary conditions\n");
return;
}
static void temperature_apply_periodic_bcs(struct All_variables *E)
{
fprintf(E->fp,"Periodic temperature boundary conditions\n");
return;
}
/* version */
/* $Id$ */
/* End of file */
