path: root/Carpet/Carpet/src/Shutdown.cc

#include <cstdio>
#include <cstdlib>

#include <cctk.h>
#include <cctk_Parameters.h>

#include <CactusTimerSet.hh>
#include <Timer.hh>

#include <dist.hh>

#include <carpet.hh>



namespace Carpet {
  
  using namespace std;
  
  
  
  int Shutdown (tFleshConfig* fc)
  {
    DECLARE_CCTK_PARAMETERS;
    
    Waypoint ("Starting shutdown");
    
    const int convlev = 0;
    cGH* cctkGH = fc->GH[convlev];
    
    static Timers::Timer timer ("Shutdown");
    timer.start();
    for (int rl=reflevels-1; rl>=0; --rl) {
      BEGIN_REVERSE_MGLEVEL_LOOP(cctkGH) {
        ENTER_LEVEL_MODE (cctkGH, rl) {
          BeginTimingLevel (cctkGH);
          
          do_early_global_mode = reflevel==reflevels-1;
          do_late_global_mode = reflevel==0;
          do_early_meta_mode = do_early_global_mode and mglevel==0;
          do_late_meta_mode = do_late_global_mode and mglevel==mglevels-1;
          do_global_mode = do_late_global_mode;
          do_meta_mode = do_late_meta_mode;
          
          Checkpoint ("Shutdown at iteration %d time %g%s%s",
                      cctkGH->cctk_iteration, (double)cctkGH->cctk_time,
                      (do_global_mode ? " (global)" : ""),
                      (do_meta_mode ? " (meta)" : ""));
          
          // Terminate
          Checkpoint ("Scheduling TERMINATE");
          CCTK_ScheduleTraverse ("CCTK_TERMINATE", cctkGH, CallFunction);
          
          EndTimingLevel (cctkGH);
        } LEAVE_LEVEL_MODE;
      } END_REVERSE_MGLEVEL_LOOP;
    } // for rl

    // Stop all timers before shutdown, since timers may rely on data
    // structures which are destroyed during shutdown
    int const ierr = CCTK_TimerStop ("CCTK total time");
    assert (not ierr);
    timer.stop();
    if (output_timers_every > 0) {
      Timers::CactusTimerSet::writeData (cctkGH, timer_file);
    }
    
    BEGIN_REVERSE_MGLEVEL_LOOP(cctkGH) {
      do_early_global_mode = true;
      do_late_global_mode = true;
      do_early_meta_mode = do_early_global_mode and mglevel==0;
      do_late_meta_mode = do_late_global_mode and mglevel==mglevels-1;
      do_global_mode = do_late_global_mode;
      do_meta_mode = do_late_meta_mode;
      
      // Shutdown
      Checkpoint ("Scheduling SHUTDOWN");
      CCTK_ScheduleTraverse ("CCTK_SHUTDOWN", cctkGH, CallFunction);
      
    } END_REVERSE_MGLEVEL_LOOP;
    
    
    
    if (output_timer_tree_every > 0) {
      Timers::Timer::outputTree("Evolve");
    }
    
    if (output_xml_timer_tree) {
      Timers::Timer::outputTreeXML();
    }
        
    
    
    // Free all memory, call all destructors
    for (size_t gi=0; gi<arrdata.size(); ++gi) {
      for (size_t m=0; m<arrdata.AT(gi).size(); ++m) {
        for (size_t vi=0; vi<arrdata.AT(gi).AT(m).data.size(); ++vi) {
          ggf*& f = arrdata.AT(gi).AT(m).data.AT(vi);
          if (f) {
            delete f; f = 0;
          }
        }
      }
    }
    // for (int gi=0; gi<CCTK_NumGroups(); ++gi) {
    //   const int tls = 0;
    //   CCTK_GroupStorageDecrease(cctkGH, 1, &gi, &tls, 0);
    // }
    
    for (size_t gi=0; gi<arrdata.size(); ++gi) {
      if (CCTK_GroupTypeI(gi) == CCTK_GF) {
        for (size_t m=0; m<arrdata.AT(gi).size(); ++m) {
          arrdata.AT(gi).AT(m).tt = 0;
          arrdata.AT(gi).AT(m).dd = 0;
          arrdata.AT(gi).AT(m).hh = 0;
        }
      } else {
        for (size_t m=0; m<arrdata.AT(gi).size(); ++m) {
          delete arrdata.AT(gi).AT(m).tt; arrdata.AT(gi).AT(m).tt = 0;
          delete arrdata.AT(gi).AT(m).dd; arrdata.AT(gi).AT(m).dd = 0;
          delete arrdata.AT(gi).AT(m).hh; arrdata.AT(gi).AT(m).hh = 0;
        }
      }
    }
    
    delete tt; tt = 0;
    for (size_t m=0; m<vdd.size(); ++m) {
      delete vdd.AT(m); vdd.AT(m) = 0;
    }
    for (size_t m=0; m<vhh.size(); ++m) {
      delete vhh.AT(m); vhh.AT(m) = 0;
    }
    
    
    
    // earlier checkpoint before finalising MPI
    Waypoint ("Done with shutdown");
    
    return 0;
  }
  
} // namespace Carpet