示例#1
0
void  CRBox::mbkload (MBK::CFig *mbkfig
                     , int z
                     , int zup
                     , int rtype
                     , bool halfpitch
                     , bool xhalfpitch
                     , bool yhalfpitch
                     , bool rotate
                     , set<string>* subNetList )
{
    MBK::MIns::iterator   itIns, endInstances, endOrphans;
  MBK::MLosig::iterator   endSig;
  MBK::MLosig::iterator   sig;
                   long   mX, mY, mZ, x, y, zz, xadjust, yadjust, yoffsetslice;
                   long   XRW1, YRW1, XRW2, YRW2;
                   bool   use_global;
                   long   northPad, southPad, eastPad, westPad;
                   long   xoffsettrack, yoffsettrack;
        MBK::chain_list  *pChain;
        MBK::locon_list  *pLocon;
        MBK::phcon_list  *pPhcon;
        MBK::losig_list  *pSig;
        MBK::phseg_list  *pSeg, flatSeg;
        MBK::phvia_list  *pVIA;
        MBK::phfig_list  *pModel;
            MBK::CXRect  *rect;
              MBK::CIns  *pIns;
                   CNet  *pNet;
                 string   sig_name, term_name, ins_name;
      CDRGrid::iterator   coord;
                  CNode  *node;


  cmess1 << "\n";
  cmess1 << "  o  Loading design into grid...\n";

  ischip       = false;
  fig          = mbkfig;
  endInstances = fig->instances.end ();
  endOrphans   = fig->orphans.end   ();
  endSig       = fig->lofig.signals.end ();

  northPad     = 0;
  southPad     = 0;
  westPad      = 0;
  eastPad      = 0;
  xoffsettrack = 0;
  yoffsettrack = 0;

  // Half pitch offset.
  if ( halfpitch ) {
    xoffsettrack = D::X_GRID / 2;
    yoffsettrack = D::Y_GRID / 2;
  }
  else if ( xhalfpitch ) {
    xoffsettrack = D::X_GRID / 2;
  }
  else if ( yhalfpitch ) {
    yoffsettrack = D::Y_GRID / 2;
  }

  // Search for pads.
  for (itIns = fig->instances.begin(); itIns != endInstances; itIns++) {
    pModel = itIns->second->getmodel ();

    if ( MBK::IsPxLib(pModel) ) {
      switch ( itIns->second->phins->TRANSF ) {
        case NOSYM:
          ischip = true;
          if ( northPad == 0 ) {
            cmess2 << "     o  North pad found.\n";
            northPad = pModel->YAB2 - pModel->YAB1 - MBK::SCALE(15);
          }
          break;
        case SYM_Y:
          ischip = true;
          if ( southPad == 0 ) {
            cmess2 << "     o  South pad found.\n";
            southPad = pModel->YAB2 - pModel->YAB1 - MBK::SCALE(15);
          }
          break;
        case ROT_P:
          ischip = true;
          if ( eastPad == 0 ) {
            cmess2 << "     o  East pad found.\n";
            eastPad = pModel->YAB2 - pModel->YAB1 - MBK::SCALE(15);
          }
          break;
        case SY_RP:
          ischip = true;
          if ( westPad == 0 ) {
            cmess2 << "     o  West pad found.\n";
            westPad = pModel->YAB2 - pModel->YAB1 - MBK::SCALE(15);
          }
          break;
        default:
          cerr << hwarn ("")
               << "  Pad " << itIns->second->phins->INSNAME
               << " have an invalid orientation.\n";
          break;
      }
    }
  }


  //southPad = northPad = westPad = eastPad = MBK::SCALE(50);
  //westPad = MBK::SCALE(100);


  // Default Routing Widow size : the AB.
  XRW1 = fig->XAB1 () + westPad;
  YRW1 = fig->YAB1 () + southPad;
  XRW2 = fig->XAB2 () - eastPad;
  YRW2 = fig->YAB2 () - northPad;

  // Find the a seed cell (one either from sxlib or dp_sxlib to
  // track adjust the grid).
  for (itIns = fig->instances.begin(); ; itIns++) {
    if (itIns == endInstances) {
      xadjust      = xoffsettrack;
      yadjust      = yoffsettrack;
      yoffsetslice = 0;
      cout << hwarn ("")
           << "  Unable to found a seed cell (i.e. belonging to either\n"
           << "  sxlib or dp_sxlib) grid could be misplaced.\n";
      break;
    }

    pModel = itIns->second->getmodel ();

    if ( !MBK::IsPxLib(pModel) ) {
      cmess2 << "     o  Using seed cell \"" << itIns->first
             << "\" (model \"" << pModel->NAME << "\").\n";
      xadjust      = abs((itIns->second->phins->XINS - XRW1) % D::X_GRID ) + xoffsettrack;
      yadjust      = abs((itIns->second->phins->YINS - YRW1) % D::Y_GRID ) + yoffsettrack;
      yoffsetslice = abs((itIns->second->phins->YINS - YRW1) % D::Y_SLICE) + YRW1;

      break;
    }
  }
  
  xoffsetgrid = XRW1 + xadjust;
  yoffsetgrid = YRW1 + yadjust;

  cmess2 << "     o  Grid offset : ("
         << MBK::UNSCALE(xoffsetgrid) << ","
         << MBK::UNSCALE(yoffsetgrid) << ")"
         << " [adjust ("
         << MBK::UNSCALE(xadjust) << ","
         << MBK::UNSCALE(yadjust) << ")]\n";

  // Compute the routing grid size.
  mX = (XRW2 - XRW1) / D::X_GRID + ((xadjust==0)?1:0);
  mY = (YRW2 - YRW1) / D::Y_GRID + ((yadjust==0)?1:0);
  mZ = z;


  // Is the design a complete chip.
  if (ischip)
    cmess2 << "     o  Design have pads, treated as a complete chip.\n";


  // Selecting the whether to use global routing.
  use_global = (mX + mY) > (2 * D::GLOBAL_HP);
  if (rtype == D::ROUTING_CHOOSE) {
    if (use_global) {
      cmess2 << "     o  Big design, global routing enabled.\n";
      rglobal = true;

      if (z < 5) {
        cmess2 << "        - Forcing 4 routing layers.\n";
        mZ = 5;
      }
    } else {
      cmess2 << "     o  Small design, global routing disabled.\n";
      rglobal = false;
    }
  } else {
    if (rtype == D::ROUTING_GLOBAL) {
      rglobal = true;
      if (!use_global) {
        cout << hwarn ("")
             << "  You have enabled global routing on a small design,\n"
             << "  this will waste upper routing layers.\n";
      }
    }
    if (rtype == D::ROUTING_LOCAL ) {
      rglobal = false;
      if (use_global) {
        cout << hwarn ("")
             << "  You have disabled global routing on a big design,\n"
             << "  this will slow down the routing.\n";
      }
    }
  }


  cmess2 << "     o  Allocating grid size ["
         << mX << "," << mY << "," << mZ << "].\n";

  float  mXf      = mX;
  float  mYf      = mY;
  float  mZf      = mZ;
  float  overflow = INT_MAX;

  if ( mXf * mYf * mZf >= overflow ) {
    cerr << herr("")
         << "  Internal routing grid capacity exceeded :\n"
         << "  More than " << INT_MAX << "nodes (INT_MAX).\n";
    throw except_done();
  }

  // Allocating the routing grid.
  drgrid = new CDRGrid (xoffsetgrid, yoffsetgrid, mX, mY, mZ, zup);


  rect = new MBK::CXRect (drgrid);


  cmess2 << "     o  Loading external terminals.\n";

  // Browse layout for terminals.
  for (pPhcon = fig->phfig.fig->PHCON; pPhcon != NULL; pPhcon = pPhcon->NEXT) {
    if (fig->lofig.signals.find(pPhcon->NAME) == endSig) {
      cerr << hwarn ("")
           << "  The terminal \"" << pPhcon->NAME << "\" at ("
           << MBK::UNSCALE (pPhcon->XCON) << ","
           << MBK::UNSCALE (pPhcon->YCON) << ") layer "
           << MBK::layer2a (pPhcon->LAYER) << "\n"
           << "  do not not belong to any logical signal : ignored.\n";

      continue;
    }

    pNet = getnet (pPhcon->NAME);

    term_name  = "external.";
    term_name += pPhcon->NAME;

    flatSeg.X1    = pPhcon->XCON;
    flatSeg.Y1    = pPhcon->YCON;
    flatSeg.X2    = pPhcon->XCON;
    flatSeg.Y2    = pPhcon->YCON;
    flatSeg.WIDTH = MBK::env.layer2width (pPhcon->LAYER);
    flatSeg.LAYER = pPhcon->LAYER;
    flatSeg.NAME  = pPhcon->NAME;

    rect->setSeg  (flatSeg);

    if ( rect->isInGrid() ) {
      pNet->newaccess ( term_name
                      , rect->grid
                      , MBK::env.layer2z (pPhcon->LAYER)
                      );
    } else {
      cerr << hwarn ("")
           << "  The terminal \"" << pPhcon->NAME << "\" at ("
           << MBK::UNSCALE (pPhcon->XCON) << ","
           << MBK::UNSCALE (pPhcon->YCON) << ") layer "
           << MBK::layer2a (pPhcon->LAYER) << "\n"
           << "  is outside the routing grid : ignored.\n";
    }

  }


  cmess2 << "     o  Finding obstacles.\n";


  // Browse father for obstacles (powers are obstacles) and already
  // routed or partially routed signals.
  for (pSeg = fig->phfig.fig->PHSEG; pSeg != NULL; pSeg = pSeg->NEXT) {
    // There must not be obstacle in the father!
    if (MBK::isobs (pSeg->LAYER)) {
      cerr << hwarn ("")
           << "  An obstacle has been found at design top level, ignored.\n";

      continue;
    }

    // Power grid.
    if (MBK::ISVDD (pSeg->NAME) || MBK::ISVSS (pSeg->NAME)) {
      if (pSeg->LAYER != MBK::CALU1) {
        rect->setSeg (*pSeg);
        
        //cerr << "+ Top power obstacle\n" << rect;

        if ( rect->isInGrid() )
          drgrid->nodes->obstacle (rect->grid, MBK::env.layer2z (pSeg->LAYER));
      }

      continue;
    }

    // Unnamed signals : ignored.
    if (pSeg->NAME == NULL) {
      cerr << hwarn ("")
           << "  An unnamed segment has been found at design top level, ignored.\n";

      continue;
    }

    // Partially routed signals.
    sig = fig->lofig.signals.find(pSeg->NAME);
    if ( sig == endSig) {
      cerr << hwarn ("")
           << "  The segment \"" << pSeg->NAME << "\" at ("
           << MBK::UNSCALE (pSeg->X1) << ","
           << MBK::UNSCALE (pSeg->Y1) << ") ("
           << MBK::UNSCALE (pSeg->X2) << ","
           << MBK::UNSCALE (pSeg->Y2) << ") layer "
           << MBK::layer2a (pSeg->LAYER) << "\n"
           << "  do not not belong to any logical signal : ignored.";

      continue;
    }

    pNet = getnet (getsigname(sig->second));
    if ( !pNet->fixed ) {
      cmess2 << "     o  Signal " << pNet->name << " is assumed to be routed.\n";
      pNet->fixed = true;
    }

    rect->setSeg  (*pSeg);

    if ( rect->isInGrid() ) {
      //pNet->newaccess ( pSeg->NAME
      //                , rect->grid
      //                , MBK::env.layer2z (pSeg->LAYER)
      //                );
      //cerr << "+ Net obstacle\n" << rect;
      drgrid->nodes->obstacle (rect->grid, MBK::env.layer2z (pSeg->LAYER));
    } else {
      cerr << hwarn ("")
           << "  The segment \"" << pSeg->NAME << "\" at ("
           << MBK::UNSCALE (pSeg->X1) << ","
           << MBK::UNSCALE (pSeg->Y1) << ") ("
           << MBK::UNSCALE (pSeg->X2) << ","
           << MBK::UNSCALE (pSeg->Y2) << ") layer "
           << MBK::layer2a (pSeg->LAYER) << "\n"
           << "  is outside the routing grid : ignored.";
    }
  }


  // Browse for obstacle VIAs.
  for (pVIA = fig->phfig.fig->PHVIA; pVIA != NULL; pVIA = pVIA->NEXT) {
    // Only power VIAs must be obstacles.
    if ( (! MBK::ISVDD (pVIA->NAME)) && (! MBK::ISVSS (pVIA->NAME))) {
      pNet = getnet (pVIA->NAME);
      if ( pNet && !pNet->fixed ) continue;
    }

    for (x = 0; x < 2; x++) {
      switch (x) {
        case 0: flatSeg.LAYER = MBK::topVIALayer    (pVIA->TYPE); break;
        case 1: flatSeg.LAYER = MBK::bottomVIALayer (pVIA->TYPE); break;
      }

      if (flatSeg.LAYER == MBK::CALU1) continue;

      long  xVIAshrink = 0;
      if (pVIA->DX) { xVIAshrink = (pVIA->DX - MBK::SCALE(3)) / 2; }
      flatSeg.X1    = pVIA->XVIA - xVIAshrink;
      flatSeg.X2    = pVIA->XVIA + xVIAshrink;
      flatSeg.Y1    = pVIA->YVIA;
      flatSeg.Y2    = pVIA->YVIA;
      flatSeg.WIDTH = pVIA->DY;

      rect->setSeg (flatSeg);

      //cerr << "+ Top VIA obstacle ("
      //     << MBK::UNSCALE(pVIA->XVIA) << ","
      //     << MBK::UNSCALE(pVIA->YVIA) << ") "
      //     << MBK::layer2a(flatSeg.LAYER) << endl;
      //cerr << rect;

      if ( rect->isInGrid() )
        drgrid->nodes->obstacle (rect->grid, MBK::env.layer2z (flatSeg.LAYER));
    }
  }


  // Browse instances & orphans for obstacles.
  for (itIns = fig->instances.begin(); ; itIns++) {
    if (itIns == endInstances) itIns = fig->orphans.begin ();
    if (itIns == endOrphans  ) break;

    pModel = itIns->second->getmodel ();

    cdebug << "+          - \"" << itIns->first
           << "\" (model \"" << pModel->NAME << "\").\n";


    // Find the obstacles in the current instance :
    // 1. - TALUx segments.
    // 2. - Power Terminals (vdd & vss), in CALUx layers & not CALU1.
    for (pSeg = pModel->PHSEG; pSeg != NULL; pSeg = pSeg->NEXT) {
      if (   MBK::isobs (pSeg->LAYER)
          || ((   MBK::ISVDD (pSeg->NAME)
               || MBK::ISVSS (pSeg->NAME)) && MBK::isCALU (pSeg->LAYER)
                                           && (pSeg->LAYER != MBK::CALU1))) {
        itIns->second->flatseg (flatSeg, *pSeg);
        rect->setSeg (flatSeg);

        //cerr << "+ Instance obstacle (" << flatSeg.X1 << "," << flatSeg.Y1 << ")"
        //     << MBK::layer2a(flatSeg.LAYER) << endl;

        if ( rect->isInGrid() )
          drgrid->nodes->obstacle (rect->grid, MBK::env.layer2z (pSeg->LAYER));

        if ( !MBK::ISVDD (pSeg->NAME) && !MBK::ISVSS (pSeg->NAME) )
          fig->addphseg ( flatSeg, true, ischip );
      }
    }
  }


  cmess2 << "     o  Loading nets into grid.\n";

  // Process the signals.
  for (pSig = fig->LOSIG (); pSig != NULL; pSig = pSig->NEXT) {
    sig_name = MBK::getsigname (pSig);

    cdebug << "+          - Signal \"" << sig_name << "\".\n";

    // Do not process power nets.
    // Temporary disabled.
    //if (   (MBK::ISVDD ((char*)sig_name.c_str ()) != 0)
    //    || (MBK::ISVSS ((char*)sig_name.c_str ()) != 0)) continue;

    // In the case of external terminals, override the signal name by
    // the terminal name.
    pChain = (MBK::chain_list*)(MBK::getptype (pSig->USER, LOFIGCHAIN)->DATA);
    for (; pChain != NULL; pChain = pChain->NEXT) {
      pLocon = (MBK::locon_list *)(pChain->DATA);

      if (pLocon->TYPE == EXTERNAL) {
        sig_name = pLocon->NAME;
        break;;
      }
    }

    pNet = getnet (sig_name);

    // Process each terminal of the signal.
    pChain = (MBK::chain_list*)(MBK::getptype (pSig->USER, LOFIGCHAIN)->DATA);

    for (; pChain != NULL; pChain = pChain->NEXT) {
      pLocon = (MBK::locon_list *)(pChain->DATA);

      if (pLocon->TYPE == EXTERNAL) {
        pNet->external = true;

        continue;
      }

      ins_name  = ((MBK::loins_list*)(pLocon->ROOT))->INSNAME;
      pIns      = fig->instances[ins_name];

      term_name = ins_name + "." + pLocon->NAME;
      cdebug << "+             I.T : " << term_name << " " << pIns->model->NAME << ".\n";

      // Find physical segments / CA of the terminal.
      for (pSeg = pIns->model->PHSEG; pSeg != NULL; pSeg = pSeg->NEXT) {
        if (!MBK::isCALU (pSeg->LAYER)) continue;
        if (pLocon->NAME != pSeg->NAME) continue;

        pIns->flatseg (flatSeg, *pSeg);
        rect->setSeg  (flatSeg);

        if ( MBK::IsPxLib(pIns->model) &&
             ( (pLocon->NAME == MBK::namealloc("pad" )) ||
               (pLocon->NAME == MBK::namealloc("vddi")) || 
               (pLocon->NAME == MBK::namealloc("vssi")) || 
               (pLocon->NAME == MBK::namealloc("vdde")) || 
               (pLocon->NAME == MBK::namealloc("vsse")) ) ) {
          flatSeg.NAME = (char*)sig_name.c_str();
          fig->addphseg (flatSeg,true,false);
          continue;
        }

        if (   (MBK::ISVDD ((char*)sig_name.c_str ()) != 0)
            || (MBK::ISVSS ((char*)sig_name.c_str ()) != 0)) continue;

        if (rect->isInGrid()) {
          if ( pNet->fixed ) {
            drgrid->nodes->obstacle (rect->grid, MBK::env.layer2z (pSeg->LAYER));
          } else {
            pNet->newaccess ( term_name
                            , rect->grid
                            , MBK::env.layer2z (pSeg->LAYER)
                            );
          }
        } else {
          //if ( MBK::IsPxLib(pModel) ) {
          //  flatSeg.NAME = (char*)sig_name.c_str();
          //  fig->addphseg (flatSeg,true,false);
          //} else {
            cerr << hwarn ("")
                 << "  The connector segment \"" << pSeg->NAME << "\" at ("
                 << MBK::UNSCALE (pSeg->X1) << ","
                 << MBK::UNSCALE (pSeg->Y1) << ") ("
                 << MBK::UNSCALE (pSeg->X2) << ","
                 << MBK::UNSCALE (pSeg->Y2) << ") layer "
                 << MBK::layer2a (pSeg->LAYER) << "\n"
                 << "  is outside of the grid : ignored.";
          }
        //}
      }
    } // End of "pChain" (terminal) loop.

    // Reorder terminals (nearest).
    pNet->order     ();
    pNet->lockalone (rglobal);
    
    cdebug << "+            " << pNet->bb << ".\n";
  } // End of "pSig" (signal) loop.

  // Restrict routed nets to the subNetList.
  if ( subNetList ) {
    for ( MNet::iterator it=nets.begin() ; it != nets.end() ; it++ ) {
      if ( subNetList->find(it->first) != subNetList->end() ) {
        cmess2 << "     o  Restricting nets to route.\n";
        cmess2 << "        - \"" << it->first << "\".\n";
      } else
        it->second->fixed = true;
    }
  }


  // Allocate the net scheduler.
  cmess2 << "     o  Allocating the net scheduler.\n";
  netsched  = new CASimple (&nets, drgrid);


  // Rebuild the power grid from the instances.
  if ( !ischip ) {
    cmess2 << "     o  Reading power grid.\n";
    powers[MBK::CALU1] = new MBK::CPowers ( fig
                                          , xadjust - xoffsettrack
                                          , yoffsetslice
                                          , C_HORIZONTAL
                                          , MBK::ALU1
                                          , D::WIDTH_VDD
                                          );
  }


  // Forbid the use of the edges of the routing box (only allow
  // peripheral terminals).
  coord = drgrid->origin;

  // Left & Right vertical edges.
  if ( xadjust == 0 ) {
    for (x = 0; x < mX; x += mX - 1) {
      for (y = 0; y < mY; y++) {
        for (zz = 1; zz < mZ; zz++) {
          node = &( coord.set(x,y,zz).node() );
          
          if ( !node->terminal() ) node->data.obstacle = true;
        }
      }
    }
  }

  // Bottom & top horizontal edges.
  if ( yadjust == 0 ) {
    for (y = 0; y < mY; y += mY - 1) {
      for (x = 0; x < mX; x++) {
        for (zz = 1; zz < mZ; zz++) {
          node = &( coord.set(x,y,zz).node() );
          
          if ( !node->terminal() ) node->data.obstacle = true;
        }
      }
    }
  }

  // On routing level above zupper (ALU4), use only half of the tracks.
  for (zz = zup; zz < mZ; zz++) {
    switch ((zz+rotate) % 2) {
      case 0:
        // Vertical tracks.
        for (x = 2; x < mX; x += 2) {
          for (y = 1; y < mY - 1; y++) {
            node = &( coord.set(x,y,zz).node() );

            if ( !node->terminal() ) node->data.obstacle = true;
          }
        }
        break;
      case 1:
        // Horizontal tracks.
        for (y = 2; y < mY; y += 2) {
          for (x = 1; x < mX; x++) {
            node = &( coord.set(x,y,zz).node() );
            if ( !node->terminal() ) node->data.obstacle = true;
          }
        }
        break;
    }
  }


  // This flag ensure that a figure has been successfully loaded.
  loaded = true;


  delete rect;
}
CRBox::CRBox (int rtype, bool debug)
{
  int     X, Y, Z;
  CNet   *pNet;
  CTerm  *pTerm;
  //CCoord  coord;


  cdebug << "ENTERING: CRBox::CRBox ()\n";
  X = 10 ; //10;
  Y = 15 ; //15;
  Z = 3;


  // Creating routing matrix.
  cdebug << "  Routing matrix size := (10, 15, 5)\n";

  drgrid = new CDRGrid (0, 0, X, Y, Z, 4);


  // Adding signal "sig_one".
  cdebug << "  Creating net \"sig_one\".\n";
  pNet = getnet ("sig_one");


  // Adding terminal "i0" of "sig_one".
  cdebug << "    Adding terminal \"i0\".\n";
  cdebug << "      Adding CA \"(0,0,0)\".\n";
  pNet->newaccess ("i0", 0, 0, 0);
  //cdebug << "      Adding CA \"(0,0,1)\".\n";
  //nets["sig_one"]->newaccess ("i0", 0, 0, 1);
  //cdebug << "      Adding CA \"(0,1,1)\".\n";
  //nets["sig_one"]->newaccess ("i0", 0, 1, 1);


  // Adding terminal "i1" of "sig_one".
  cdebug << "    Adding terminal \"i1\".\n";
  cdebug << "      Adding CA \"(9,0,0)\".\n";
  pNet->newaccess ("i1", 9, 0, 0);


  // Adding terminal "o" of "sig_one".
  cdebug << "    Adding terminal \"o\".\n";
  //cdebug << "      Adding CA \"(5,10,0)\".\n";
  //nets["sig_one"]->newaccess ("o", 5, 10, 0);

  //cdebug << "      Adding CA \"(7,12,0)\".\n";
  //nets["sig_one"]->newaccess ("o", 7, 12, 0);


  // Adding signal "sig_two".
  //cdebug << "  Creating net \"sig_two\".\n";
  //nets["sig_two"] = new CNet ("sig_two");


  // Adding terminal "i0" of "sig_two".
  //cdebug << "    Adding terminal \"i0\".\n";
  //cdebug << "      Adding CA \"(4,1,0)\".\n";
  //nets["sig_two"]->newaccess ("i0", 4, 1, 0);


  // Adding terminal "o" of "sig_two".
  //cdebug << "    Adding terminal \"o\".\n";
  //cdebug << "      Adding CA \"(4,11,0)\".\n";
  //nets["sig_two"]->newaccess ("o", 4, 11, 0);


  //{
  //  int j;

  //  for (j = 0; j < Y; j++) {
  //    (*::grid)[coord.set (160, j, 1)]->data.pri = 128;
  //    (*::grid)[coord.set (160, j, 2)]->data.pri = 128;
  //  } 
  //}
  // Putting obstacles.
  //(*::grid)[coord.set (5, 5, 2)]->data.pri = 128;
  //(*::grid)[coord.set (6, 5, 2)]->data.pri = 128;
  //(*::grid)[coord.set (7, 5, 2)]->data.pri = 128;
  //(*::grid)[coord.set (8, 5, 2)]->data.pri = 128;
  //(*::grid)[coord.set (9, 5, 2)]->data.pri = 128;


  netsched  = new CASimple (&nets, drgrid);

  cdebug << "EXITING: CRBox::CRBox ()\n";
}