gtsam: debug.c Source File

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 /*
  * Copyright 1997, Regents of the University of Minnesota
  *
  * debug.c
  *
  * This file contains code that performs self debuging
  *
  * Started 7/24/97
  * George
  *
  */
 
 #include "metislib.h"
 
 
 
 /*************************************************************************/
 /*************************************************************************/
 idx_t ComputeCut(graph_t *graph, idx_t *where)
 {
   idx_t i, j, cut;
 
   if (graph->adjwgt == NULL) {
     for (cut=0, i=0; i<graph->nvtxs; i++) {
       for (j=graph->xadj[i]; j<graph->xadj[i+1]; j++)
         if (where[i] != where[graph->adjncy[j]])
           cut++;
     }
   }
   else {
     for (cut=0, i=0; i<graph->nvtxs; i++) {
       for (j=graph->xadj[i]; j<graph->xadj[i+1]; j++)
         if (where[i] != where[graph->adjncy[j]])
           cut += graph->adjwgt[j];
     }
   }
 
   return cut/2;
 }
 
 
 /*************************************************************************/
 /*************************************************************************/
 idx_t ComputeVolume(graph_t *graph, idx_t *where)
 {
   idx_t i, j, k, me, nvtxs, nparts, totalv;
   idx_t *xadj, *adjncy, *vsize, *marker;
 
 
   nvtxs  = graph->nvtxs;
   xadj   = graph->xadj;
   adjncy = graph->adjncy;
   vsize  = graph->vsize;
 
   nparts = where[iargmax(nvtxs, where)]+1;
   marker = ismalloc(nparts, -1, "ComputeVolume: marker");
 
   totalv = 0;
 
   for (i=0; i<nvtxs; i++) {
     marker[where[i]] = i;
     for (j=xadj[i]; j<xadj[i+1]; j++) {
       k = where[adjncy[j]];
       if (marker[k] != i) {
         marker[k] = i;
         totalv += (vsize ? vsize[i] : 1);
       }
     }
   }
 
   gk_free((void **)&marker, LTERM);
 
   return totalv;
 }
 
 
 /*************************************************************************/
 /*************************************************************************/
 idx_t ComputeMaxCut(graph_t *graph, idx_t nparts, idx_t *where)
 {
   idx_t i, j, maxcut;
   idx_t *cuts;
 
   cuts = ismalloc(nparts, 0, "ComputeMaxCut: cuts");
 
   if (graph->adjwgt == NULL) {
     for (i=0; i<graph->nvtxs; i++) {
       for (j=graph->xadj[i]; j<graph->xadj[i+1]; j++)
         if (where[i] != where[graph->adjncy[j]]) 
           cuts[where[i]]++;
     }
   }
   else {
     for (i=0; i<graph->nvtxs; i++) {
       for (j=graph->xadj[i]; j<graph->xadj[i+1]; j++)
         if (where[i] != where[graph->adjncy[j]])
           cuts[where[i]] += graph->adjwgt[j];
     }
   }
 
   maxcut = cuts[iargmax(nparts, cuts)];
 
   printf("%zu => %"PRIDX"\n", iargmax(nparts, cuts), maxcut);
 
   gk_free((void **)&cuts, LTERM);
 
   return maxcut;
 }
 
 
 /*************************************************************************/
 /*************************************************************************/
 idx_t CheckBnd(graph_t *graph) 
 {
   idx_t i, j, nvtxs, nbnd;
   idx_t *xadj, *adjncy, *where, *bndptr, *bndind;
 
   nvtxs = graph->nvtxs;
   xadj = graph->xadj;
   adjncy = graph->adjncy;
   where = graph->where;
   bndptr = graph->bndptr;
   bndind = graph->bndind;
 
   for (nbnd=0, i=0; i<nvtxs; i++) {
     if (xadj[i+1]-xadj[i] == 0)
       nbnd++;   /* Islands are considered to be boundary vertices */
 
     for (j=xadj[i]; j<xadj[i+1]; j++) {
       if (where[i] != where[adjncy[j]]) {
         nbnd++;
         ASSERT(bndptr[i] != -1);
         ASSERT(bndind[bndptr[i]] == i);
         break;
       }
     }
   }
 
   ASSERTP(nbnd == graph->nbnd, ("%"PRIDX" %"PRIDX"\n", nbnd, graph->nbnd));
 
   return 1;
 }
 
 
 
 /*************************************************************************/
 /*************************************************************************/
 idx_t CheckBnd2(graph_t *graph) 
 {
   idx_t i, j, nvtxs, nbnd, id, ed;
   idx_t *xadj, *adjncy, *where, *bndptr, *bndind;
 
   nvtxs  = graph->nvtxs;
   xadj   = graph->xadj;
   adjncy = graph->adjncy;
   where  = graph->where;
   bndptr = graph->bndptr;
   bndind = graph->bndind;
 
   for (nbnd=0, i=0; i<nvtxs; i++) {
     id = ed = 0;
     for (j=xadj[i]; j<xadj[i+1]; j++) {
       if (where[i] != where[adjncy[j]]) 
         ed += graph->adjwgt[j];
       else
         id += graph->adjwgt[j];
     }
     if (ed - id >= 0 && xadj[i] < xadj[i+1]) {
       nbnd++;
       ASSERTP(bndptr[i] != -1, ("%"PRIDX" %"PRIDX" %"PRIDX"\n", i, id, ed));
       ASSERT(bndind[bndptr[i]] == i);
     }
   }
 
   ASSERTP(nbnd == graph->nbnd, ("%"PRIDX" %"PRIDX"\n", nbnd, graph->nbnd));
 
   return 1;
 }
 
 
 /*************************************************************************/
 /*************************************************************************/
 idx_t CheckNodeBnd(graph_t *graph, idx_t onbnd) 
 {
   idx_t i, j, nvtxs, nbnd;
   idx_t *xadj, *adjncy, *where, *bndptr, *bndind;
 
   nvtxs = graph->nvtxs;
   xadj = graph->xadj;
   adjncy = graph->adjncy;
   where = graph->where;
   bndptr = graph->bndptr;
   bndind = graph->bndind;
 
   for (nbnd=0, i=0; i<nvtxs; i++) {
     if (where[i] == 2) 
       nbnd++;   
   }
 
   ASSERTP(nbnd == onbnd, ("%"PRIDX" %"PRIDX"\n", nbnd, onbnd));
 
   for (i=0; i<nvtxs; i++) {
     if (where[i] != 2) {
       ASSERTP(bndptr[i] == -1, ("%"PRIDX" %"PRIDX"\n", i, bndptr[i]));
     }
     else {
       ASSERTP(bndptr[i] != -1, ("%"PRIDX" %"PRIDX"\n", i, bndptr[i]));
     }
   }
 
   return 1;
 }
 
 
 
 /*************************************************************************/
 /*************************************************************************/
 idx_t CheckRInfo(ctrl_t *ctrl, ckrinfo_t *rinfo)
 {
   idx_t i, j;
   cnbr_t *nbrs;
 
   nbrs = ctrl->cnbrpool + rinfo->inbr;
 
   for (i=0; i<rinfo->nnbrs; i++) {
     for (j=i+1; j<rinfo->nnbrs; j++)
       ASSERTP(nbrs[i].pid != nbrs[j].pid, 
           ("%"PRIDX" %"PRIDX" %"PRIDX" %"PRIDX"\n", 
            i, j, nbrs[i].pid, nbrs[j].pid));
   }
 
   return 1;
 }
 
 
 
 /*************************************************************************/
 /*************************************************************************/
 idx_t CheckNodePartitionParams(graph_t *graph)
 {
   idx_t i, j, k, l, nvtxs, me, other;
   idx_t *xadj, *adjncy, *adjwgt, *vwgt, *where;
   idx_t edegrees[2], pwgts[3];
 
   nvtxs  = graph->nvtxs;
   xadj   = graph->xadj;
   vwgt   = graph->vwgt;
   adjncy = graph->adjncy;
   adjwgt = graph->adjwgt;
   where  = graph->where;
 
   /*------------------------------------------------------------
   / Compute now the separator external degrees
   /------------------------------------------------------------*/
   pwgts[0] = pwgts[1] = pwgts[2] = 0;
   for (i=0; i<nvtxs; i++) {
     me = where[i];
     pwgts[me] += vwgt[i];
 
     if (me == 2) { /* If it is on the separator do some computations */
       edegrees[0] = edegrees[1] = 0;
 
       for (j=xadj[i]; j<xadj[i+1]; j++) {
         other = where[adjncy[j]];
         if (other != 2)
           edegrees[other] += vwgt[adjncy[j]];
       }
       if (edegrees[0] != graph->nrinfo[i].edegrees[0] || 
           edegrees[1] != graph->nrinfo[i].edegrees[1]) {
         printf("Something wrong with edegrees: %"PRIDX" %"PRIDX" %"PRIDX" %"PRIDX" %"PRIDX"\n", 
             i, edegrees[0], edegrees[1], 
             graph->nrinfo[i].edegrees[0], graph->nrinfo[i].edegrees[1]);
         return 0;
       }
     }
   }
 
   if (pwgts[0] != graph->pwgts[0] || 
       pwgts[1] != graph->pwgts[1] || 
       pwgts[2] != graph->pwgts[2]) {
     printf("Something wrong with part-weights: %"PRIDX" %"PRIDX" %"PRIDX" %"PRIDX" %"PRIDX" %"PRIDX"\n", pwgts[0], pwgts[1], pwgts[2], graph->pwgts[0], graph->pwgts[1], graph->pwgts[2]);
     return 0;
   }
 
   return 1;
 }
 
 
 /*************************************************************************/
 /*************************************************************************/
 idx_t IsSeparable(graph_t *graph)
 {
   idx_t i, j, nvtxs, other;
   idx_t *xadj, *adjncy, *where;
 
   nvtxs = graph->nvtxs;
   xadj = graph->xadj;
   adjncy = graph->adjncy;
   where = graph->where;
 
   for (i=0; i<nvtxs; i++) {
     if (where[i] == 2)
       continue;
     other = (where[i]+1)%2;
     for (j=xadj[i]; j<xadj[i+1]; j++) {
       ASSERTP(where[adjncy[j]] != other, 
           ("%"PRIDX" %"PRIDX" %"PRIDX" %"PRIDX" %"PRIDX" %"PRIDX"\n", 
            i, where[i], adjncy[j], where[adjncy[j]], xadj[i+1]-xadj[i], 
            xadj[adjncy[j]+1]-xadj[adjncy[j]]));
     }
   }
 
   return 1;
 }
 
 
 /*************************************************************************/
 /*************************************************************************/
 void CheckKWayVolPartitionParams(ctrl_t *ctrl, graph_t *graph)
 {
   idx_t i, ii, j, k, kk, l, nvtxs, nbnd, mincut, minvol, me, other, pid;
   idx_t *xadj, *vsize, *adjncy, *pwgts, *where, *bndind, *bndptr;
   vkrinfo_t *rinfo, *myrinfo, *orinfo, tmprinfo;
   vnbr_t *mynbrs, *onbrs, *tmpnbrs;
 
   WCOREPUSH;
 
   nvtxs  = graph->nvtxs;
   xadj   = graph->xadj;
   vsize  = graph->vsize;
   adjncy = graph->adjncy;
   where  = graph->where;
   rinfo  = graph->vkrinfo;
 
   tmpnbrs = (vnbr_t *)wspacemalloc(ctrl, ctrl->nparts*sizeof(vnbr_t));
 
   /*------------------------------------------------------------
   / Compute now the iv/ev degrees
   /------------------------------------------------------------*/
   for (i=0; i<nvtxs; i++) {
     me = where[i];
 
     myrinfo = rinfo+i;
     mynbrs  = ctrl->vnbrpool + myrinfo->inbr;
 
     for (k=0; k<myrinfo->nnbrs; k++)
       tmpnbrs[k] = mynbrs[k];
 
     tmprinfo.nnbrs = myrinfo->nnbrs;
     tmprinfo.nid    = myrinfo->nid;
     tmprinfo.ned    = myrinfo->ned;
 
     myrinfo = &tmprinfo;
     mynbrs  = tmpnbrs;
 
     for (k=0; k<myrinfo->nnbrs; k++)
       mynbrs[k].gv = 0;
 
     for (j=xadj[i]; j<xadj[i+1]; j++) {
       ii     = adjncy[j];
       other  = where[ii];
       orinfo = rinfo+ii;
       onbrs  = ctrl->vnbrpool + orinfo->inbr;
 
       if (me == other) {
         /* Find which domains 'i' is connected and 'ii' is not and update their gain */
         for (k=0; k<myrinfo->nnbrs; k++) {
           pid = mynbrs[k].pid;
           for (kk=0; kk<orinfo->nnbrs; kk++) {
             if (onbrs[kk].pid == pid)
               break;
           }
           if (kk == orinfo->nnbrs) 
             mynbrs[k].gv -= vsize[ii];
         }
       }
       else {
         /* Find the orinfo[me].ed and see if I'm the only connection */
         for (k=0; k<orinfo->nnbrs; k++) {
           if (onbrs[k].pid == me)
             break;
         }
 
         if (onbrs[k].ned == 1) { /* I'm the only connection of 'ii' in 'me' */
           for (k=0; k<myrinfo->nnbrs; k++) {
             if (mynbrs[k].pid == other) {
               mynbrs[k].gv += vsize[ii];
               break;
             }
           }
 
           /* Increase the gains for all the common domains between 'i' and 'ii' */
           for (k=0; k<myrinfo->nnbrs; k++) {
             if ((pid = mynbrs[k].pid) == other)
               continue;
             for (kk=0; kk<orinfo->nnbrs; kk++) {
               if (onbrs[kk].pid == pid) {
                 mynbrs[k].gv += vsize[ii];
                 break;
               }
             }
           }
 
         }
         else {
           /* Find which domains 'i' is connected and 'ii' is not and update their gain */
           for (k=0; k<myrinfo->nnbrs; k++) {
             if ((pid = mynbrs[k].pid) == other)
               continue;
             for (kk=0; kk<orinfo->nnbrs; kk++) {
               if (onbrs[kk].pid == pid)
                 break;
             }
             if (kk == orinfo->nnbrs) 
               mynbrs[k].gv -= vsize[ii];
           }
         }
       }
     }
 
     myrinfo = rinfo+i;
     mynbrs  = ctrl->vnbrpool + myrinfo->inbr;
 
     for (k=0; k<myrinfo->nnbrs; k++) {
       pid = mynbrs[k].pid;
       for (kk=0; kk<tmprinfo.nnbrs; kk++) {
         if (tmpnbrs[kk].pid == pid) {
           if (tmpnbrs[kk].gv != mynbrs[k].gv)
             printf("[%8"PRIDX" %8"PRIDX" %8"PRIDX" %+8"PRIDX" %+8"PRIDX"]\n", 
                 i, where[i], pid, mynbrs[k].gv, tmpnbrs[kk].gv);
           break;
         }
       }
     }
 
   }
 
   WCOREPOP;
 }
 
 