📄 mkwayrefine.c
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/* * Copyright 1997, Regents of the University of Minnesota * * mkwayrefine.c * * This file contains the driving routines for multilevel k-way refinement * * Started 7/28/97 * George * * $Id: mkwayrefine.c,v 1.2 1998/11/27 18:16:19 karypis Exp $ */#include <metis.h>/************************************************************************** This function is the entry point of refinement**************************************************************************/void MocRefineKWayHorizontal(CtrlType *ctrl, GraphType *orggraph, GraphType *graph, int nparts, float *ubvec){ IFSET(ctrl->dbglvl, DBG_TIME, starttimer(ctrl->UncoarsenTmr)); /* Compute the parameters of the coarsest graph */ MocComputeKWayPartitionParams(ctrl, graph, nparts); for (;;) { IFSET(ctrl->dbglvl, DBG_TIME, starttimer(ctrl->RefTmr)); if (!MocIsHBalanced(graph->ncon, nparts, graph->npwgts, ubvec)) { MocComputeKWayBalanceBoundary(ctrl, graph, nparts); MCGreedy_KWayEdgeBalanceHorizontal(ctrl, graph, nparts, ubvec, 4); ComputeKWayBoundary(ctrl, graph, nparts); } MCRandom_KWayEdgeRefineHorizontal(ctrl, graph, nparts, ubvec, 10); IFSET(ctrl->dbglvl, DBG_TIME, stoptimer(ctrl->RefTmr)); if (graph == orggraph) break; graph = graph->finer; IFSET(ctrl->dbglvl, DBG_TIME, starttimer(ctrl->ProjectTmr)); MocProjectKWayPartition(ctrl, graph, nparts); IFSET(ctrl->dbglvl, DBG_TIME, stoptimer(ctrl->ProjectTmr)); } if (!MocIsHBalanced(graph->ncon, nparts, graph->npwgts, ubvec)) { MocComputeKWayBalanceBoundary(ctrl, graph, nparts); MCGreedy_KWayEdgeBalanceHorizontal(ctrl, graph, nparts, ubvec, 4); ComputeKWayBoundary(ctrl, graph, nparts); MCRandom_KWayEdgeRefineHorizontal(ctrl, graph, nparts, ubvec, 10); } IFSET(ctrl->dbglvl, DBG_TIME, stoptimer(ctrl->UncoarsenTmr));}/************************************************************************** This function allocates memory for k-way edge refinement**************************************************************************/void MocAllocateKWayPartitionMemory(CtrlType *ctrl, GraphType *graph, int nparts){ int nvtxs, ncon, pad64; nvtxs = graph->nvtxs; ncon = graph->ncon; pad64 = (3*nvtxs)%2; graph->rdata = idxmalloc(3*nvtxs+(sizeof(RInfoType)/sizeof(idxtype))*nvtxs+pad64, "AllocateKWayPartitionMemory: rdata"); graph->where = graph->rdata; graph->bndptr = graph->rdata + nvtxs; graph->bndind = graph->rdata + 2*nvtxs; graph->rinfo = (RInfoType *)(graph->rdata + 3*nvtxs + pad64); graph->npwgts = fmalloc(ncon*nparts, "MocAllocateKWayPartitionMemory: npwgts");}/************************************************************************** This function computes the initial id/ed **************************************************************************/void MocComputeKWayPartitionParams(CtrlType *ctrl, GraphType *graph, int nparts){ int i, j, k, l, nvtxs, ncon, nbnd, mincut, me, other; idxtype *xadj, *adjncy, *adjwgt, *where, *bndind, *bndptr; RInfoType *rinfo, *myrinfo; EDegreeType *myedegrees; float *nvwgt, *npwgts; nvtxs = graph->nvtxs; ncon = graph->ncon; xadj = graph->xadj; nvwgt = graph->nvwgt; adjncy = graph->adjncy; adjwgt = graph->adjwgt; where = graph->where; npwgts = sset(ncon*nparts, 0.0, graph->npwgts); bndind = graph->bndind; bndptr = idxset(nvtxs, -1, graph->bndptr); rinfo = graph->rinfo; /*------------------------------------------------------------ / Compute now the id/ed degrees /------------------------------------------------------------*/ ctrl->wspace.cdegree = 0; nbnd = mincut = 0; for (i=0; i<nvtxs; i++) { me = where[i]; saxpy(ncon, 1.0, nvwgt+i*ncon, 1, npwgts+me*ncon, 1); myrinfo = rinfo+i; myrinfo->id = myrinfo->ed = myrinfo->ndegrees = 0; myrinfo->edegrees = NULL; for (j=xadj[i]; j<xadj[i+1]; j++) { if (me != where[adjncy[j]]) myrinfo->ed += adjwgt[j]; } myrinfo->id = graph->adjwgtsum[i] - myrinfo->ed; if (myrinfo->ed > 0) mincut += myrinfo->ed; if (myrinfo->ed-myrinfo->id >= 0) BNDInsert(nbnd, bndind, bndptr, i); /* Time to compute the particular external degrees */ if (myrinfo->ed > 0) { myedegrees = myrinfo->edegrees = ctrl->wspace.edegrees+ctrl->wspace.cdegree; ctrl->wspace.cdegree += xadj[i+1]-xadj[i]; for (j=xadj[i]; j<xadj[i+1]; j++) { other = where[adjncy[j]]; if (me != other) { for (k=0; k<myrinfo->ndegrees; k++) { if (myedegrees[k].pid == other) { myedegrees[k].ed += adjwgt[j]; break; } } if (k == myrinfo->ndegrees) { myedegrees[myrinfo->ndegrees].pid = other; myedegrees[myrinfo->ndegrees++].ed = adjwgt[j]; } } } ASSERT(myrinfo->ndegrees <= xadj[i+1]-xadj[i]); } } graph->mincut = mincut/2; graph->nbnd = nbnd;}/************************************************************************** This function projects a partition, and at the same time computes the* parameters for refinement.**************************************************************************/void MocProjectKWayPartition(CtrlType *ctrl, GraphType *graph, int nparts){ int i, j, k, nvtxs, nbnd, me, other, istart, iend, ndegrees; idxtype *xadj, *adjncy, *adjwgt, *adjwgtsum; idxtype *cmap, *where, *bndptr, *bndind; idxtype *cwhere; GraphType *cgraph; RInfoType *crinfo, *rinfo, *myrinfo; EDegreeType *myedegrees; idxtype *htable; cgraph = graph->coarser; cwhere = cgraph->where; crinfo = cgraph->rinfo; nvtxs = graph->nvtxs; cmap = graph->cmap; xadj = graph->xadj; adjncy = graph->adjncy; adjwgt = graph->adjwgt; adjwgtsum = graph->adjwgtsum; MocAllocateKWayPartitionMemory(ctrl, graph, nparts); where = graph->where; rinfo = graph->rinfo; bndind = graph->bndind; bndptr = idxset(nvtxs, -1, graph->bndptr); /* Go through and project partition and compute id/ed for the nodes */ for (i=0; i<nvtxs; i++) { k = cmap[i]; where[i] = cwhere[k]; cmap[i] = crinfo[k].ed; /* For optimization */ } htable = idxset(nparts, -1, idxwspacemalloc(ctrl, nparts)); ctrl->wspace.cdegree = 0; for (nbnd=0, i=0; i<nvtxs; i++) { me = where[i]; myrinfo = rinfo+i; myrinfo->id = myrinfo->ed = myrinfo->ndegrees = 0; myrinfo->edegrees = NULL; myrinfo->id = adjwgtsum[i]; if (cmap[i] > 0) { /* If it is an interface node. Note cmap[i] = crinfo[cmap[i]].ed */ istart = xadj[i]; iend = xadj[i+1]; myedegrees = myrinfo->edegrees = ctrl->wspace.edegrees+ctrl->wspace.cdegree; ctrl->wspace.cdegree += iend-istart; ndegrees = 0; for (j=istart; j<iend; j++) { other = where[adjncy[j]]; if (me != other) { myrinfo->ed += adjwgt[j]; if ((k = htable[other]) == -1) { htable[other] = ndegrees; myedegrees[ndegrees].pid = other; myedegrees[ndegrees++].ed = adjwgt[j]; } else { myedegrees[k].ed += adjwgt[j]; } } } myrinfo->id -= myrinfo->ed; /* Remove space for edegrees if it was interior */ if (myrinfo->ed == 0) { myrinfo->edegrees = NULL; ctrl->wspace.cdegree -= iend-istart; } else { if (myrinfo->ed-myrinfo->id >= 0) BNDInsert(nbnd, bndind, bndptr, i); myrinfo->ndegrees = ndegrees; for (j=0; j<ndegrees; j++) htable[myedegrees[j].pid] = -1; } } } scopy(graph->ncon*nparts, cgraph->npwgts, graph->npwgts); graph->mincut = cgraph->mincut; graph->nbnd = nbnd; FreeGraph(graph->coarser); graph->coarser = NULL; idxwspacefree(ctrl, nparts); ASSERT(CheckBnd2(graph));}/************************************************************************** This function computes the boundary definition for balancing**************************************************************************/void MocComputeKWayBalanceBoundary(CtrlType *ctrl, GraphType *graph, int nparts){ int i, nvtxs, nbnd; idxtype *bndind, *bndptr; nvtxs = graph->nvtxs; bndind = graph->bndind; bndptr = idxset(nvtxs, -1, graph->bndptr); /* Compute the new boundary */ nbnd = 0; for (i=0; i<nvtxs; i++) { if (graph->rinfo[i].ed > 0) BNDInsert(nbnd, bndind, bndptr, i); } graph->nbnd = nbnd;}⌨️ 快捷键说明
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