#include "pargrid.h" /*+ main - the main routine for this grid program Input Parameters: argc, argv - the usual argv[1] - the number of processors in the x direction argv[2] - the number of processors in the y direction argv[3] - the number of processors in the z direction argv[4] - the number of points in the x direction on each processor do not use less than 3 points argv[5] - the number of points in the y direction on each processor do not use less than 3 points argv[6] - the number of points in the z direction on each processor do not use less than 3 points argv[7] - symmetric = 0, nonsymmetric = 1 argv[8] - 0 = do not use, 1 = use inode/clique stuff argv[9] - number of components per grid point To Run, see tools. Notes: The grid program solves a linear system associated with a 3-D grid distributed across the processors. The 3-D grid is partitioned in all three dimensions among the processors. A 7pt stencil is used. +*/ int main(int argc, char **argv) { par_grid grid; BSprocinfo *procinfo; int inode, nonsymmetric; /* Call BSinit() to initialize BlocklSolve and MPI */ BSinit(&argc,&argv); /* set up the context for BlockSolve */ procinfo = BScreate_ctx(); CHKERRN(0); /* tell it to print out some information on the reordering */ BSctx_set_pr(procinfo,TRUE); CHKERRN(0); if(procinfo->my_id==0) { printf("\n"); printf("************** Blocksolve Example Grid6 *******************\n"); } /* read in grid parameters */ if (argc < 10) { SETERRC(ARG_ERR,"Argument list too small\n"); printf("Example: mpirun -np P grid5.ARCH PX PY PZ NX NY NZ SYM IN NC\n"); printf("ARCH = Machine architecture\n"); printf("P = number of processors\n"); printf("PX = the number of processors in the x direction\n"); printf("PY = the number of processors in the y direction\n"); printf("PZ = the number of processors in the z direction\n"); printf("NX = number of points in the x direction on each processor\n"); printf("NY = number of points in the y direction on each processor\n"); printf("NZ = number of points in the z direction on each processor\n"); printf("SYM = 0, use symmetric data structure, = 1, use nonsymmetric\n"); printf("IN = 0, do not use, = 1, use inode/clique stuff\n"); printf("NC = number of components per grid point\n"); return(-1); } sscanf(argv[1],"%d",&grid.worker_x); sscanf(argv[2],"%d",&grid.worker_y); sscanf(argv[3],"%d",&grid.worker_z); if (procinfo->my_id == 0) { printf("o Number of workers (x,y,z): %d %d %d\n", grid.worker_x,grid.worker_y,grid.worker_z); } if (procinfo->nprocs != grid.worker_x*grid.worker_y*grid.worker_z) { SETERRC(ARG_ERR,"Number of processors is not correct\n"); return(-1); } sscanf(argv[4],"%d",&grid.l_num_x); sscanf(argv[5],"%d",&grid.l_num_y); sscanf(argv[6],"%d",&grid.l_num_z); sscanf(argv[7],"%d",&nonsymmetric); sscanf(argv[8],"%d",&inode); sscanf(argv[9],"%d",&grid.ncomp); if(grid.ncomp<1) grid.ncomp = 1; if(grid.ncomp>20) grid.ncomp = 20; grid.symmetric = (!nonsymmetric); grid.icc_storage = (!nonsymmetric); grid.positive = FALSE; /* tell it to use the nonsymmetric matrix data structure */ if(nonsymmetric) { if (procinfo->my_id == 0) printf("o Using nonsymmetric data structure\n"); BSctx_set_method(procinfo,GMRES); BSctx_set_pre(procinfo,PRE_ILU); } else { if (procinfo->my_id == 0) printf("o Using symmetric data structure\n"); BSctx_set_method(procinfo,CG); BSctx_set_pre(procinfo,PRE_ICC); } /* decide whether to look for i-nodes or cliques */ if(inode) { if (procinfo->my_id == 0) printf("o Using inode/clique information\n"); BSctx_set_si(procinfo,FALSE); CHKERRN(0); } else { if (procinfo->my_id == 0) printf("o Not using inode/clique information\n"); BSctx_set_si(procinfo,TRUE); CHKERRN(0); } if (procinfo->my_id == 0) printf("o Multi component grid, %d components per point\n",grid.ncomp); /* local grid size and type */ grid.type = 7; if (procinfo->my_id == 0) { printf("o Local discretizations (x,y,z): %d %d %d\n", grid.l_num_x,grid.l_num_y,grid.l_num_z); } /* call the worker */ worker(&grid,procinfo); if(procinfo->my_id==0) { printf("************ End Blocksolve Example Grid6 *****************\n"); printf("\n"); } /* print logging if enabled */ BSprint_log(procinfo); CHKERRN(0); /* free the context */ BSfree_ctx(procinfo); CHKERRN(0); /* finalize BlockSolve and MPI */ BSfinalize(); exit(0); }