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mmd.c

typedef int shortint;

/* *************************************************************** */
/* *************************************************************** */
/* ****     GENMMD ..... MULTIPLE MINIMUM EXTERNAL DEGREE     **** */
/* *************************************************************** */
/* *************************************************************** */

/*     AUTHOR - JOSEPH W.H. LIU */
/*              DEPT OF COMPUTER SCIENCE, YORK UNIVERSITY. */

/*     PURPOSE - THIS ROUTINE IMPLEMENTS THE MINIMUM DEGREE */
/*        ALGORITHM.  IT MAKES USE OF THE IMPLICIT REPRESENTATION */
/*        OF ELIMINATION GRAPHS BY QUOTIENT GRAPHS, AND THE */
/*        NOTION OF INDISTINGUISHABLE NODES.  IT ALSO IMPLEMENTS */
/*        THE MODIFICATIONS BY MULTIPLE ELIMINATION AND MINIMUM */
/*        EXTERNAL DEGREE. */
/*        --------------------------------------------- */
/*        CAUTION - THE ADJACENCY VECTOR ADJNCY WILL BE */
/*        DESTROYED. */
/*        --------------------------------------------- */

/*     INPUT PARAMETERS - */
/*        NEQNS  - NUMBER OF EQUATIONS. */
/*        (XADJ,ADJNCY) - THE ADJACENCY STRUCTURE. */
/*        DELTA  - TOLERANCE VALUE FOR MULTIPLE ELIMINATION. */
/*        MAXINT - MAXIMUM MACHINE REPRESENTABLE (SHORT) INTEGER */
/*                 (ANY SMALLER ESTIMATE WILL DO) FOR MARKING */
/*                 NODES. */

/*     OUTPUT PARAMETERS - */
/*        PERM   - THE MINIMUM DEGREE ORDERING. */
/*        INVP   - THE INVERSE OF PERM. */
/*        NOFSUB - AN UPPER BOUND ON THE NUMBER OF NONZERO */
/*                 SUBSCRIPTS FOR THE COMPRESSED STORAGE SCHEME. */

/*     WORKING PARAMETERS - */
/*        DHEAD  - VECTOR FOR HEAD OF DEGREE LISTS. */
/*        INVP   - USED TEMPORARILY FOR DEGREE FORWARD LINK. */
/*        PERM   - USED TEMPORARILY FOR DEGREE BACKWARD LINK. */
/*        QSIZE  - VECTOR FOR SIZE OF SUPERNODES. */
/*        LLIST  - VECTOR FOR TEMPORARY LINKED LISTS. */
/*        MARKER - A TEMPORARY MARKER VECTOR. */

/*     PROGRAM SUBROUTINES - */
/*        MMDELM, MMDINT, MMDNUM, MMDUPD. */

/* *************************************************************** */

/* Subroutine */ int genmmd_(int *neqns, int *xadj, shortint *adjncy, 
      shortint *invp, shortint *perm, int *delta, shortint *dhead, 
      shortint *qsize, shortint *llist, shortint *marker, int *maxint, 
      int *nofsub)
{
    /* System generated locals */
    int i__1;

    /* Local variables */
    static int mdeg, ehead, i, mdlmt, mdnode;
    extern /* Subroutine */ int mmdelm_(int *, int *, shortint *, 
          shortint *, shortint *, shortint *, shortint *, shortint *, 
          shortint *, int *, int *), mmdupd_(int *, int *, 
          int *, shortint *, int *, int *, shortint *, shortint 
          *, shortint *, shortint *, shortint *, shortint *, int *, 
          int *), mmdint_(int *, int *, shortint *, shortint *, 
          shortint *, shortint *, shortint *, shortint *, shortint *), 
          mmdnum_(int *, shortint *, shortint *, shortint *);
    static int nextmd, tag, num;


/* *************************************************************** */


/* *************************************************************** */

    /* Parameter adjustments */
    --marker;
    --llist;
    --qsize;
    --dhead;
    --perm;
    --invp;
    --adjncy;
    --xadj;

    /* Function Body */
    if (*neqns <= 0) {
      return 0;
    }

/*        ------------------------------------------------ */
/*        INITIALIZATION FOR THE MINIMUM DEGREE ALGORITHM. */
/*        ------------------------------------------------ */
    *nofsub = 0;
    mmdint_(neqns, &xadj[1], &adjncy[1], &dhead[1], &invp[1], &perm[1], &
          qsize[1], &llist[1], &marker[1]);

/*        ---------------------------------------------- */
/*        NUM COUNTS THE NUMBER OF ORDERED NODES PLUS 1. */
/*        ---------------------------------------------- */
    num = 1;

/*        ----------------------------- */
/*        ELIMINATE ALL ISOLATED NODES. */
/*        ----------------------------- */
    nextmd = dhead[1];
L100:
    if (nextmd <= 0) {
      goto L200;
    }
    mdnode = nextmd;
    nextmd = invp[mdnode];
    marker[mdnode] = *maxint;
    invp[mdnode] = -num;
    ++num;
    goto L100;

L200:
/*        ---------------------------------------- */
/*        SEARCH FOR NODE OF THE MINIMUM DEGREE. */
/*        MDEG IS THE CURRENT MINIMUM DEGREE; */
/*        TAG IS USED TO FACILITATE MARKING NODES. */
/*        ---------------------------------------- */
    if (num > *neqns) {
      goto L1000;
    }
    tag = 1;
    dhead[1] = 0;
    mdeg = 2;
L300:
    if (dhead[mdeg] > 0) {
      goto L400;
    }
    ++mdeg;
    goto L300;
L400:
/*            ------------------------------------------------- */
/*            USE VALUE OF DELTA TO SET UP MDLMT, WHICH GOVERNS */
/*            WHEN A DEGREE UPDATE IS TO BE PERFORMED. */
/*            ------------------------------------------------- */
    mdlmt = mdeg + *delta;
    ehead = 0;

L500:
    mdnode = dhead[mdeg];
    if (mdnode > 0) {
      goto L600;
    }
    ++mdeg;
    if (mdeg > mdlmt) {
      goto L900;
    }
    goto L500;
L600:
/*                ---------------------------------------- */
/*                REMOVE MDNODE FROM THE DEGREE STRUCTURE. */
/*                ---------------------------------------- */
    nextmd = invp[mdnode];
    dhead[mdeg] = nextmd;
    if (nextmd > 0) {
      perm[nextmd] = -mdeg;
    }
    invp[mdnode] = -num;
    *nofsub = *nofsub + mdeg + qsize[mdnode] - 2;
    if (num + qsize[mdnode] > *neqns) {
      goto L1000;
    }
/*                ---------------------------------------------- */
/*                ELIMINATE MDNODE AND PERFORM QUOTIENT GRAPH */
/*                TRANSFORMATION.  RESET TAG VALUE IF NECESSARY. */
/*                ---------------------------------------------- */
    ++tag;
    if (tag < *maxint) {
      goto L800;
    }
    tag = 1;
    i__1 = *neqns;
    for (i = 1; i <= i__1; ++i) {
      if (marker[i] < *maxint) {
          marker[i] = 0;
      }
/* L700: */
    }
L800:
    mmdelm_(&mdnode, &xadj[1], &adjncy[1], &dhead[1], &invp[1], &perm[1], &
          qsize[1], &llist[1], &marker[1], maxint, &tag);
    num += qsize[mdnode];
    llist[mdnode] = ehead;
    ehead = mdnode;
    if (*delta >= 0) {
      goto L500;
    }
L900:
/*            ------------------------------------------- */
/*            UPDATE DEGREES OF THE NODES INVOLVED IN THE */
/*            MINIMUM DEGREE NODES ELIMINATION. */
/*            ------------------------------------------- */
    if (num > *neqns) {
      goto L1000;
    }
    mmdupd_(&ehead, neqns, &xadj[1], &adjncy[1], delta, &mdeg, &dhead[1], &
          invp[1], &perm[1], &qsize[1], &llist[1], &marker[1], maxint, &tag)
          ;
    goto L300;

L1000:
    mmdnum_(neqns, &perm[1], &invp[1], &qsize[1]);
    return 0;

} /* genmmd_ */

/* *************************************************************** */
/* *************************************************************** */
/* ***     MMDINT ..... MULT MINIMUM DEGREE INITIALIZATION     *** */
/* *************************************************************** */
/* *************************************************************** */

/*     AUTHOR - JOSEPH W.H. LIU */
/*              DEPT OF COMPUTER SCIENCE, YORK UNIVERSITY. */

/*     PURPOSE - THIS ROUTINE PERFORMS INITIALIZATION FOR THE */
/*        MULTIPLE ELIMINATION VERSION OF THE MINIMUM DEGREE */
/*        ALGORITHM. */

/*     INPUT PARAMETERS - */
/*        NEQNS  - NUMBER OF EQUATIONS. */
/*        (XADJ,ADJNCY) - ADJACENCY STRUCTURE. */

/*     OUTPUT PARAMETERS - */
/*        (DHEAD,DFORW,DBAKW) - DEGREE DOUBLY LINKED STRUCTURE. */
/*        QSIZE  - SIZE OF SUPERNODE (INITIALIZED TO ONE). */
/*        LLIST  - LINKED LIST. */
/*        MARKER - MARKER VECTOR. */

/* *************************************************************** */

/* Subroutine */ int mmdint_(int *neqns, int *xadj, shortint *adjncy, 
      shortint *dhead, shortint *dforw, shortint *dbakw, shortint *qsize, 
      shortint *llist, shortint *marker)
{
    /* System generated locals */
    int i__1;

    /* Local variables */
    static int ndeg, node, fnode;


/* *************************************************************** */


/* *************************************************************** */

    /* Parameter adjustments */
    --marker;
    --llist;
    --qsize;
    --dbakw;
    --dforw;
    --dhead;
    --adjncy;
    --xadj;

    /* Function Body */
    i__1 = *neqns;
    for (node = 1; node <= i__1; ++node) {
      dhead[node] = 0;
      qsize[node] = 1;
      marker[node] = 0;
      llist[node] = 0;
/* L100: */
    }
/*        ------------------------------------------ */
/*        INITIALIZE THE DEGREE DOUBLY LINKED LISTS. */
/*        ------------------------------------------ */
    i__1 = *neqns;
    for (node = 1; node <= i__1; ++node) {
      ndeg = xadj[node + 1] - xadj[node] + 1;
      fnode = dhead[ndeg];
      dforw[node] = fnode;
      dhead[ndeg] = node;
      if (fnode > 0) {
          dbakw[fnode] = node;
      }
      dbakw[node] = -ndeg;
/* L200: */
    }
    return 0;

} /* mmdint_ */

/* *************************************************************** */
/* *************************************************************** */
/* **     MMDELM ..... MULTIPLE MINIMUM DEGREE ELIMINATION     *** */
/* *************************************************************** */
/* *************************************************************** */

/*     AUTHOR - JOSEPH W.H. LIU */
/*              DEPT OF COMPUTER SCIENCE, YORK UNIVERSITY. */

/*     PURPOSE - THIS ROUTINE ELIMINATES THE NODE MDNODE OF */
/*        MINIMUM DEGREE FROM THE ADJACENCY STRUCTURE, WHICH */
/*        IS STORED IN THE QUOTIENT GRAPH FORMAT.  IT ALSO */
/*        TRANSFORMS THE QUOTIENT GRAPH REPRESENTATION OF THE */
/*        ELIMINATION GRAPH. */

/*     INPUT PARAMETERS - */
/*        MDNODE - NODE OF MINIMUM DEGREE. */
/*        MAXINT - ESTIMATE OF MAXIMUM REPRESENTABLE (SHORT) */
/*                 INT. */
/*        TAG    - TAG VALUE. */

/*     UPDATED PARAMETERS - */
/*        (XADJ,ADJNCY) - UPDATED ADJACENCY STRUCTURE. */
/*        (DHEAD,DFORW,DBAKW) - DEGREE DOUBLY LINKED STRUCTURE. */
/*        QSIZE  - SIZE OF SUPERNODE. */
/*        MARKER - MARKER VECTOR. */
/*        LLIST  - TEMPORARY LINKED LIST OF ELIMINATED NABORS. */

/* *************************************************************** */

/* Subroutine */ int mmdelm_(int *mdnode, int *xadj, shortint *adjncy,
       shortint *dhead, shortint *dforw, shortint *dbakw, shortint *qsize, 
      shortint *llist, shortint *marker, int *maxint, int *tag)
{
    /* System generated locals */
    int i__1, i__2;

    /* Local variables */
    static int node, link, rloc, rlmt, i, j, nabor, rnode, elmnt, xqnbr, 
          istop, jstop, istrt, jstrt, nxnode, pvnode, nqnbrs, npv;


/* *************************************************************** */


/* *************************************************************** */

/*        ----------------------------------------------- */
/*        FIND REACHABLE SET AND PLACE IN DATA STRUCTURE. */
/*        ----------------------------------------------- */
    /* Parameter adjustments */
    --marker;
    --llist;
    --qsize;
    --dbakw;
    --dforw;
    --dhead;
    --adjncy;
    --xadj;

    /* Function Body */
    marker[*mdnode] = *tag;
    istrt = xadj[*mdnode];
    istop = xadj[*mdnode + 1] - 1;
/*        ------------------------------------------------------- */
/*        ELMNT POINTS TO THE BEGINNING OF THE LIST OF ELIMINATED */
/*        NABORS OF MDNODE, AND RLOC GIVES THE STORAGE LOCATION */
/*        FOR THE NEXT REACHABLE NODE. */
/*        ------------------------------------------------------- */
    elmnt = 0;
    rloc = istrt;
    rlmt = istop;
    i__1 = istop;
    for (i = istrt; i <= i__1; ++i) {
      nabor = adjncy[i];
      if (nabor == 0) {
          goto L300;
      }
      if (marker[nabor] >= *tag) {
          goto L200;
      }
      marker[nabor] = *tag;
      if (dforw[nabor] < 0) {
          goto L100;
      }
      adjncy[rloc] = nabor;
      ++rloc;
      goto L200;
L100:
      llist[nabor] = elmnt;
      elmnt = nabor;
L200:
      ;
    }
L300:
/*            ----------------------------------------------------- */
/*            MERGE WITH REACHABLE NODES FROM GENERALIZED ELEMENTS. */
/*            ----------------------------------------------------- */
    if (elmnt <= 0) {
      goto L1000;
    }
    adjncy[rlmt] = -elmnt;
    link = elmnt;
L400:
    jstrt = xadj[link];
    jstop = xadj[link + 1] - 1;
    i__1 = jstop;
    for (j = jstrt; j <= i__1; ++j) {
      node = adjncy[j];
      link = -node;
      if (node < 0) {
          goto L400;
      } else if (node == 0) {
          goto L900;
      } else {
          goto L500;
      }
L500:
      if (marker[node] >= *tag || dforw[node] < 0) {
          goto L800;
      }
      marker[node] = *tag;
/*                            --------------------------------- */
/*                            USE STORAGE FROM ELIMINATED NODES */
/*                            IF NECESSARY. */
/*                            --------------------------------- */
L600:
      if (rloc < rlmt) {
          goto L700;
      }
      link = -adjncy[rlmt];
      rloc = xadj[link];
      rlmt = xadj[link + 1] - 1;
      goto L600;
L700:
      adjncy[rloc] = node;
      ++rloc;
L800:
      ;
    }
L900:
    elmnt = llist[elmnt];
    goto L300;
L1000:
    if (rloc <= rlmt) {
      adjncy[rloc] = 0;
    }
/*        -------------------------------------------------------- */
/*        FOR EACH NODE IN THE REACHABLE SET, DO THE FOLLOWING ... */
/*        -------------------------------------------------------- */
    link = *mdnode;
L1100:
    istrt = xadj[link];
    istop = xadj[link + 1] - 1;
    i__1 = istop;
    for (i = istrt; i <= i__1; ++i) {
      rnode = adjncy[i];
      link = -rnode;
      if (rnode < 0) {
          goto L1100;
      } else if (rnode == 0) {
          goto L1800;
      } else {
          goto L1200;
      }
L1200:
/*                -------------------------------------------- */
/*                IF RNODE IS IN THE DEGREE LIST STRUCTURE ... */
/*                -------------------------------------------- */
      pvnode = dbakw[rnode];
      if (pvnode == 0 || pvnode == -(*maxint)) {
          goto L1300;
      }
/*                    ------------------------------------- */
/*                    THEN REMOVE RNODE FROM THE STRUCTURE. */
/*                    ------------------------------------- */
      nxnode = dforw[rnode];
      if (nxnode > 0) {
          dbakw[nxnode] = pvnode;
      }
      if (pvnode > 0) {
          dforw[pvnode] = nxnode;
      }
      npv = -pvnode;
      if (pvnode < 0) {
          dhead[npv] = nxnode;
      }
L1300:
/*                ---------------------------------------- */
/*                PURGE INACTIVE QUOTIENT NABORS OF RNODE. */
/*                ---------------------------------------- */
      jstrt = xadj[rnode];
      jstop = xadj[rnode + 1] - 1;
      xqnbr = jstrt;
      i__2 = jstop;
      for (j = jstrt; j <= i__2; ++j) {
          nabor = adjncy[j];
          if (nabor == 0) {
            goto L1500;
          }
          if (marker[nabor] >= *tag) {
            goto L1400;
          }
          adjncy[xqnbr] = nabor;
          ++xqnbr;
L1400:
          ;
      }
L1500:
/*                ---------------------------------------- */
/*                IF NO ACTIVE NABOR AFTER THE PURGING ... */
/*                ---------------------------------------- */
      nqnbrs = xqnbr - jstrt;
      if (nqnbrs > 0) {
          goto L1600;
      }
/*                    ----------------------------- */
/*                    THEN MERGE RNODE WITH MDNODE. */
/*                    ----------------------------- */
      qsize[*mdnode] += qsize[rnode];
      qsize[rnode] = 0;
      marker[rnode] = *maxint;
      dforw[rnode] = -(*mdnode);
      dbakw[rnode] = -(*maxint);
      goto L1700;
L1600:
/*                -------------------------------------- */
/*                ELSE FLAG RNODE FOR DEGREE UPDATE, AND */
/*                ADD MDNODE AS A NABOR OF RNODE. */
/*                -------------------------------------- */
      dforw[rnode] = nqnbrs + 1;
      dbakw[rnode] = 0;
      adjncy[xqnbr] = *mdnode;
      ++xqnbr;
      if (xqnbr <= jstop) {
          adjncy[xqnbr] = 0;
      }

L1700:
      ;
    }
L1800:
    return 0;

} /* mmdelm_ */

/* *************************************************************** */
/* *************************************************************** */
/* *****     MMDUPD ..... MULTIPLE MINIMUM DEGREE UPDATE     ***** */
/* *************************************************************** */
/* *************************************************************** */

/*     AUTHOR - JOSEPH W.H. LIU */
/*              DEPT OF COMPUTER SCIENCE, YORK UNIVERSITY. */

/*     PURPOSE - THIS ROUTINE UPDATES THE DEGREES OF NODES */
/*        AFTER A MULTIPLE ELIMINATION STEP. */

/*     INPUT PARAMETERS - */
/*        EHEAD  - THE BEGINNING OF THE LIST OF ELIMINATED */
/*                 NODES (I.E., NEWLY FORMED ELEMENTS). */
/*        NEQNS  - NUMBER OF EQUATIONS. */
/*        (XADJ,ADJNCY) - ADJACENCY STRUCTURE. */
/*        DELTA  - TOLERANCE VALUE FOR MULTIPLE ELIMINATION. */
/*        MAXINT - MAXIMUM MACHINE REPRESENTABLE (SHORT) */
/*                 INTEGER. */

/*     UPDATED PARAMETERS - */
/*        MDEG   - NEW MINIMUM DEGREE AFTER DEGREE UPDATE. */
/*        (DHEAD,DFORW,DBAKW) - DEGREE DOUBLY LINKED STRUCTURE. */
/*        QSIZE  - SIZE OF SUPERNODE. */
/*        LLIST  - WORKING LINKED LIST. */
/*        MARKER - MARKER VECTOR FOR DEGREE UPDATE. */
/*        TAG    - TAG VALUE. */

/* *************************************************************** */

/* Subroutine */ int mmdupd_(int *ehead, int *neqns, int *xadj, 
      shortint *adjncy, int *delta, int *mdeg, shortint *dhead, 
      shortint *dforw, shortint *dbakw, shortint *qsize, shortint *llist, 
      shortint *marker, int *maxint, int *tag)
{
    /* System generated locals */
    int i__1, i__2;

    /* Local variables */
    static int node, mtag, link, mdeg0, i, j, enode, fnode, nabor, elmnt, 
          istop, jstop, q2head, istrt, jstrt, qxhead, iq2, deg, deg0;


/* *************************************************************** */


/* *************************************************************** */

    /* Parameter adjustments */
    --marker;
    --llist;
    --qsize;
    --dbakw;
    --dforw;
    --dhead;
    --adjncy;
    --xadj;

    /* Function Body */
    mdeg0 = *mdeg + *delta;
    elmnt = *ehead;
L100:
/*            ------------------------------------------------------- */
/*            FOR EACH OF THE NEWLY FORMED ELEMENT, DO THE FOLLOWING. */
/*            (RESET TAG VALUE IF NECESSARY.) */
/*            ------------------------------------------------------- */
    if (elmnt <= 0) {
      return 0;
    }
    mtag = *tag + mdeg0;
    if (mtag < *maxint) {
      goto L300;
    }
    *tag = 1;
    i__1 = *neqns;
    for (i = 1; i <= i__1; ++i) {
      if (marker[i] < *maxint) {
          marker[i] = 0;
      }
/* L200: */
    }
    mtag = *tag + mdeg0;
L300:
/*            --------------------------------------------- */
/*            CREATE TWO LINKED LISTS FROM NODES ASSOCIATED */
/*            WITH ELMNT: ONE WITH TWO NABORS (Q2HEAD) IN */
/*            ADJACENCY STRUCTURE, AND THE OTHER WITH MORE */
/*            THAN TWO NABORS (QXHEAD).  ALSO COMPUTE DEG0, */
/*            NUMBER OF NODES IN THIS ELEMENT. */
/*            --------------------------------------------- */
    q2head = 0;
    qxhead = 0;
    deg0 = 0;
    link = elmnt;
L400:
    istrt = xadj[link];
    istop = xadj[link + 1] - 1;
    i__1 = istop;
    for (i = istrt; i <= i__1; ++i) {
      enode = adjncy[i];
      link = -enode;
      if (enode < 0) {
          goto L400;
      } else if (enode == 0) {
          goto L800;
      } else {
          goto L500;
      }

L500:
      if (qsize[enode] == 0) {
          goto L700;
      }
      deg0 += qsize[enode];
      marker[enode] = mtag;
/*                        ---------------------------------- */
/*                        IF ENODE REQUIRES A DEGREE UPDATE, */
/*                        THEN DO THE FOLLOWING. */
/*                        ---------------------------------- */
      if (dbakw[enode] != 0) {
          goto L700;
      }
/*                            --------------------------------------- 
*/
/*                            PLACE EITHER IN QXHEAD OR Q2HEAD LISTS. 
*/
/*                            --------------------------------------- 
*/
      if (dforw[enode] == 2) {
          goto L600;
      }
      llist[enode] = qxhead;
      qxhead = enode;
      goto L700;
L600:
      llist[enode] = q2head;
      q2head = enode;
L700:
      ;
    }
L800:
/*            -------------------------------------------- */
/*            FOR EACH ENODE IN Q2 LIST, DO THE FOLLOWING. */
/*            -------------------------------------------- */
    enode = q2head;
    iq2 = 1;
L900:
    if (enode <= 0) {
      goto L1500;
    }
    if (dbakw[enode] != 0) {
      goto L2200;
    }
    ++(*tag);
    deg = deg0;
/*                    ------------------------------------------ */
/*                    IDENTIFY THE OTHER ADJACENT ELEMENT NABOR. */
/*                    ------------------------------------------ */
    istrt = xadj[enode];
    nabor = adjncy[istrt];
    if (nabor == elmnt) {
      nabor = adjncy[istrt + 1];
    }
/*                    ------------------------------------------------ */
/*                    IF NABOR IS UNELIMINATED, INCREASE DEGREE COUNT. */
/*                    ------------------------------------------------ */
    link = nabor;
    if (dforw[nabor] < 0) {
      goto L1000;
    }
    deg += qsize[nabor];
    goto L2100;
L1000:
/*                        -------------------------------------------- */
/*                        OTHERWISE, FOR EACH NODE IN THE 2ND ELEMENT, */
/*                        DO THE FOLLOWING. */
/*                        -------------------------------------------- */
    istrt = xadj[link];
    istop = xadj[link + 1] - 1;
    i__1 = istop;
    for (i = istrt; i <= i__1; ++i) {
      node = adjncy[i];
      link = -node;
      if (node == enode) {
          goto L1400;
      }
      if (node < 0) {
          goto L1000;
      } else if (node == 0) {
          goto L2100;
      } else {
          goto L1100;
      }

L1100:
      if (qsize[node] == 0) {
          goto L1400;
      }
      if (marker[node] >= *tag) {
          goto L1200;
      }
/*                                -----------------------------------
-- */
/*                                CASE WHEN NODE IS NOT YET CONSIDERED
. */
/*                                -----------------------------------
-- */
      marker[node] = *tag;
      deg += qsize[node];
      goto L1400;
L1200:
/*                            ----------------------------------------
 */
/*                            CASE WHEN NODE IS INDISTINGUISHABLE FROM
 */
/*                            ENODE.  MERGE THEM INTO A NEW SUPERNODE.
 */
/*                            ----------------------------------------
 */
      if (dbakw[node] != 0) {
          goto L1400;
      }
      if (dforw[node] != 2) {
          goto L1300;
      }
      qsize[enode] += qsize[node];
      qsize[node] = 0;
      marker[node] = *maxint;
      dforw[node] = -enode;
      dbakw[node] = -(*maxint);
      goto L1400;
L1300:
/*                            -------------------------------------- 
*/
/*                            CASE WHEN NODE IS OUTMATCHED BY ENODE. 
*/
/*                            -------------------------------------- 
*/
      if (dbakw[node] == 0) {
          dbakw[node] = -(*maxint);
      }
L1400:
      ;
    }
    goto L2100;
L1500:
/*                ------------------------------------------------ */
/*                FOR EACH ENODE IN THE QX LIST, DO THE FOLLOWING. */
/*                ------------------------------------------------ */
    enode = qxhead;
    iq2 = 0;
L1600:
    if (enode <= 0) {
      goto L2300;
    }
    if (dbakw[enode] != 0) {
      goto L2200;
    }
    ++(*tag);
    deg = deg0;
/*                        --------------------------------- */
/*                        FOR EACH UNMARKED NABOR OF ENODE, */
/*                        DO THE FOLLOWING. */
/*                        --------------------------------- */
    istrt = xadj[enode];
    istop = xadj[enode + 1] - 1;
    i__1 = istop;
    for (i = istrt; i <= i__1; ++i) {
      nabor = adjncy[i];
      if (nabor == 0) {
          goto L2100;
      }
      if (marker[nabor] >= *tag) {
          goto L2000;
      }
      marker[nabor] = *tag;
      link = nabor;
/*                                ------------------------------ */
/*                                IF UNELIMINATED, INCLUDE IT IN */
/*                                DEG COUNT. */
/*                                ------------------------------ */
      if (dforw[nabor] < 0) {
          goto L1700;
      }
      deg += qsize[nabor];
      goto L2000;
L1700:
/*                                    ------------------------------- 
*/
/*                                    IF ELIMINATED, INCLUDE UNMARKED 
*/
/*                                    NODES IN THIS ELEMENT INTO THE 
*/
/*                                    DEGREE COUNT. */
/*                                    ------------------------------- 
*/
      jstrt = xadj[link];
      jstop = xadj[link + 1] - 1;
      i__2 = jstop;
      for (j = jstrt; j <= i__2; ++j) {
          node = adjncy[j];
          link = -node;
          if (node < 0) {
            goto L1700;
          } else if (node == 0) {
            goto L2000;
          } else {
            goto L1800;
          }

L1800:
          if (marker[node] >= *tag) {
            goto L1900;
          }
          marker[node] = *tag;
          deg += qsize[node];
L1900:
          ;
      }
L2000:
      ;
    }
L2100:
/*                    ------------------------------------------- */
/*                    UPDATE EXTERNAL DEGREE OF ENODE IN DEGREE */
/*                    STRUCTURE, AND MDEG (MIN DEG) IF NECESSARY. */
/*                    ------------------------------------------- */
    deg = deg - qsize[enode] + 1;
    fnode = dhead[deg];
    dforw[enode] = fnode;
    dbakw[enode] = -deg;
    if (fnode > 0) {
      dbakw[fnode] = enode;
    }
    dhead[deg] = enode;
    if (deg < *mdeg) {
      *mdeg = deg;
    }
L2200:
/*                    ---------------------------------- */
/*                    GET NEXT ENODE IN CURRENT ELEMENT. */
/*                    ---------------------------------- */
    enode = llist[enode];
    if (iq2 == 1) {
      goto L900;
    }
    goto L1600;
L2300:
/*            ----------------------------- */
/*            GET NEXT ELEMENT IN THE LIST. */
/*            ----------------------------- */
    *tag = mtag;
    elmnt = llist[elmnt];
    goto L100;

} /* mmdupd_ */

/* *************************************************************** */
/* *************************************************************** */
/* *****     MMDNUM ..... MULTI MINIMUM DEGREE NUMBERING     ***** */
/* *************************************************************** */
/* *************************************************************** */

/*     AUTHOR - JOSEPH W.H. LIU */
/*              DEPT OF COMPUTER SCIENCE, YORK UNIVERSITY. */

/*     PURPOSE - THIS ROUTINE PERFORMS THE FINAL STEP IN */
/*        PRODUCING THE PERMUTATION AND INVERSE PERMUTATION */
/*        VECTORS IN THE MULTIPLE ELIMINATION VERSION OF THE */
/*        MINIMUM DEGREE ORDERING ALGORITHM. */

/*     INPUT PARAMETERS - */
/*        NEQNS  - NUMBER OF EQUATIONS. */
/*        QSIZE  - SIZE OF SUPERNODES AT ELIMINATION. */

/*     UPDATED PARAMETERS - */
/*        INVP   - INVERSE PERMUTATION VECTOR.  ON INPUT, */
/*                 IF QSIZE(NODE)=0, THEN NODE HAS BEEN MERGED */
/*                 INTO THE NODE -INVP(NODE); OTHERWISE, */
/*                 -INVP(NODE) IS ITS INVERSE LABELLING. */

/*     OUTPUT PARAMETERS - */
/*        PERM   - THE PERMUTATION VECTOR. */

/* *************************************************************** */

/* Subroutine */ int mmdnum_(int *neqns, shortint *perm, shortint *invp, 
      shortint *qsize)
{
    /* System generated locals */
    int i__1;

    /* Local variables */
    static int node, root, nextf, father, nqsize, num;


/* *************************************************************** */


/* *************************************************************** */

    /* Parameter adjustments */
    --qsize;
    --invp;
    --perm;

    /* Function Body */
    i__1 = *neqns;
    for (node = 1; node <= i__1; ++node) {
      nqsize = qsize[node];
      if (nqsize <= 0) {
          perm[node] = invp[node];
      }
      if (nqsize > 0) {
          perm[node] = -invp[node];
      }
/* L100: */
    }
/*        ------------------------------------------------------ */
/*        FOR EACH NODE WHICH HAS BEEN MERGED, DO THE FOLLOWING. */
/*        ------------------------------------------------------ */
    i__1 = *neqns;
    for (node = 1; node <= i__1; ++node) {
      if (perm[node] > 0) {
          goto L500;
      }
/*                ----------------------------------------- */
/*                TRACE THE MERGED TREE UNTIL ONE WHICH HAS */
/*                NOT BEEN MERGED, CALL IT ROOT. */
/*                ----------------------------------------- */
      father = node;
L200:
      if (perm[father] > 0) {
          goto L300;
      }
      father = -perm[father];
      goto L200;
L300:
/*                ----------------------- */
/*                NUMBER NODE AFTER ROOT. */
/*                ----------------------- */
      root = father;
      num = perm[root] + 1;
      invp[node] = -num;
      perm[root] = num;
/*                ------------------------ */
/*                SHORTEN THE MERGED TREE. */
/*                ------------------------ */
      father = node;
L400:
      nextf = -perm[father];
      if (nextf <= 0) {
          goto L500;
      }
      perm[father] = -root;
      father = nextf;
      goto L400;
L500:
      ;
    }
/*        ---------------------- */
/*        READY TO COMPUTE PERM. */
/*        ---------------------- */
    i__1 = *neqns;
    for (node = 1; node <= i__1; ++node) {
      num = -invp[node];
      invp[node] = num;
      perm[num] = node;
/* L600: */
    }
    return 0;

} /* mmdnum_ */


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