Пример #1
0
HYPRE_Int
hypre_BoomerAMGCycleT( void              *amg_vdata, 
                   hypre_ParVector  **F_array,
                   hypre_ParVector  **U_array   )
{
   hypre_ParAMGData *amg_data = amg_vdata;

   /* Data Structure variables */

   hypre_ParCSRMatrix    **A_array;
   hypre_ParCSRMatrix    **P_array;
   hypre_ParCSRMatrix    **R_array;
   hypre_ParVector    *Vtemp;

   HYPRE_Int     **CF_marker_array;
   /* HYPRE_Int     **unknown_map_array; */
   /* HYPRE_Int     **point_map_array; */
   /* HYPRE_Int     **v_at_point_array; */

   HYPRE_Real    cycle_op_count;   
   HYPRE_Int       cycle_type;
   HYPRE_Int       num_levels;
   HYPRE_Int       max_levels;

   HYPRE_Real   *num_coeffs;
   HYPRE_Int      *num_grid_sweeps;   
   HYPRE_Int      *grid_relax_type;   
   HYPRE_Int     **grid_relax_points;  
 
   /* Local variables  */

   HYPRE_Int      *lev_counter;
   HYPRE_Int       Solve_err_flag;
   HYPRE_Int       k;
   HYPRE_Int       j;
   HYPRE_Int       level;
   HYPRE_Int       cycle_param;
   HYPRE_Int       coarse_grid;
   HYPRE_Int       fine_grid;
   HYPRE_Int       Not_Finished;
   HYPRE_Int       num_sweep;
   HYPRE_Int       relax_type;
   HYPRE_Int       relax_points;
   HYPRE_Real   *relax_weight;

   HYPRE_Int       relax_local;
   HYPRE_Int       relax_order;
   HYPRE_Int       old_version = 0;


   HYPRE_Real    alpha;
   HYPRE_Real    beta;
#if 0
   HYPRE_Real   *D_mat;
   HYPRE_Real   *S_vec;
#endif
   
   /* Acquire data and allocate storage */

   A_array           = hypre_ParAMGDataAArray(amg_data);
   P_array           = hypre_ParAMGDataPArray(amg_data);
   R_array           = hypre_ParAMGDataRArray(amg_data);
   CF_marker_array   = hypre_ParAMGDataCFMarkerArray(amg_data);
   /* unknown_map_array = hypre_ParAMGDataUnknownMapArray(amg_data); */
   /* point_map_array   = hypre_ParAMGDataPointMapArray(amg_data); */
   /* v_at_point_array  = hypre_ParAMGDataVatPointArray(amg_data); */
   Vtemp             = hypre_ParAMGDataVtemp(amg_data);
   num_levels        = hypre_ParAMGDataNumLevels(amg_data);
   max_levels        = hypre_ParAMGDataMaxLevels(amg_data);
   cycle_type        = hypre_ParAMGDataCycleType(amg_data);
   /* num_unknowns      =  hypre_ParCSRMatrixNumRows(A_array[0]); */

   num_grid_sweeps     = hypre_ParAMGDataNumGridSweeps(amg_data);
   grid_relax_type     = hypre_ParAMGDataGridRelaxType(amg_data);
   grid_relax_points   = hypre_ParAMGDataGridRelaxPoints(amg_data);
   relax_weight        = hypre_ParAMGDataRelaxWeight(amg_data); 

   relax_order         = hypre_ParAMGDataRelaxOrder(amg_data);

   cycle_op_count = hypre_ParAMGDataCycleOpCount(amg_data);

   lev_counter = hypre_CTAlloc(HYPRE_Int, num_levels);

   /* Initialize */

   Solve_err_flag = 0;

   if (grid_relax_points) old_version = 1;

   num_coeffs = hypre_CTAlloc(HYPRE_Real, num_levels);
   num_coeffs[0]    = hypre_ParCSRMatrixDNumNonzeros(A_array[0]);

   for (j = 1; j < num_levels; j++)
      num_coeffs[j] = hypre_ParCSRMatrixDNumNonzeros(A_array[j]);

   /*---------------------------------------------------------------------
    *    Initialize cycling control counter
    *
    *     Cycling is controlled using a level counter: lev_counter[k]
    *     
    *     Each time relaxation is performed on level k, the
    *     counter is decremented by 1. If the counter is then
    *     negative, we go to the next finer level. If non-
    *     negative, we go to the next coarser level. The
    *     following actions control cycling:
    *     
    *     a. lev_counter[0] is initialized to 1.
    *     b. lev_counter[k] is initialized to cycle_type for k>0.
    *     
    *     c. During cycling, when going down to level k, lev_counter[k]
    *        is set to the max of (lev_counter[k],cycle_type)
    *---------------------------------------------------------------------*/

   Not_Finished = 1;

   lev_counter[0] = 1;
   for (k = 1; k < num_levels; ++k) 
   {
      lev_counter[k] = cycle_type;
   }

   level = 0;
   cycle_param = 0;

   /*---------------------------------------------------------------------
    * Main loop of cycling
    *--------------------------------------------------------------------*/
  
   while (Not_Finished)
   {
      num_sweep = num_grid_sweeps[cycle_param];
      relax_type = grid_relax_type[cycle_param];
      if (relax_type != 7 && relax_type != 9) relax_type = 7;
      /*------------------------------------------------------------------
       * Do the relaxation num_sweep times
       *-----------------------------------------------------------------*/

      for (j = 0; j < num_sweep; j++)
      {

         if (num_levels == 1 && max_levels > 1)
         {
            relax_points = 0;
            relax_local = 0;
         }
         else
         {
            if (old_version)
               relax_points = grid_relax_points[cycle_param][j];
            relax_local = relax_order;
         }

         /*-----------------------------------------------
          * VERY sloppy approximation to cycle complexity
          *-----------------------------------------------*/

         if (old_version && level < num_levels -1)
         {
            switch (relax_points)
            {
               case 1:
               cycle_op_count += num_coeffs[level+1];
               break;
  
               case -1: 
               cycle_op_count += (num_coeffs[level]-num_coeffs[level+1]); 
               break;
            }
         }
	 else
         {
            cycle_op_count += num_coeffs[level]; 
         }

         /* note: this does not use relax_points, so it doesn't matter if
            its the "old version" */
         
         Solve_err_flag = hypre_BoomerAMGRelaxT(A_array[level], 
                                                F_array[level],
                                                CF_marker_array[level],
                                                relax_type,
                                                relax_points,
                                                relax_weight[level],
                                                U_array[level],
                                                Vtemp);
        
         
         if (Solve_err_flag != 0)
         {
            hypre_TFree(lev_counter);
            hypre_TFree(num_coeffs);
            return(Solve_err_flag);
         }
      }


      /*------------------------------------------------------------------
       * Decrement the control counter and determine which grid to visit next
       *-----------------------------------------------------------------*/

      --lev_counter[level];
       
      if (lev_counter[level] >= 0 && level != num_levels-1)
      {
                               
         /*---------------------------------------------------------------
          * Visit coarser level next.  Compute residual using hypre_ParCSRMatrixMatvec.
          * Use interpolation (since transpose i.e. P^TATR instead of
          * RAP) using hypre_ParCSRMatrixMatvecT.
          * Reset counters and cycling parameters for coarse level
          *--------------------------------------------------------------*/

         fine_grid = level;
         coarse_grid = level + 1;

         hypre_ParVectorSetConstantValues(U_array[coarse_grid], 0.0);
          
         hypre_ParVectorCopy(F_array[fine_grid],Vtemp);
         alpha = -1.0;
         beta = 1.0;
         hypre_ParCSRMatrixMatvecT(alpha, A_array[fine_grid], U_array[fine_grid],
                         beta, Vtemp);

         alpha = 1.0;
         beta = 0.0;

         hypre_ParCSRMatrixMatvecT(alpha,P_array[fine_grid],Vtemp,
                          beta,F_array[coarse_grid]);

         ++level;
         lev_counter[level] = hypre_max(lev_counter[level],cycle_type);
         cycle_param = 1;
         if (level == num_levels-1) cycle_param = 3;
      }

      else if (level != 0)
      {
                            
         /*---------------------------------------------------------------
          * Visit finer level next.
          * Use restriction (since transpose i.e. P^TA^TR instead of RAP)
          * and add correction using hypre_ParCSRMatrixMatvec.
          * Reset counters and cycling parameters for finer level.
          *--------------------------------------------------------------*/

         fine_grid = level - 1;
         coarse_grid = level;
         alpha = 1.0;
         beta = 1.0;

         hypre_ParCSRMatrixMatvec(alpha, R_array[fine_grid], U_array[coarse_grid],
                         beta, U_array[fine_grid]);            
 
         --level;
         cycle_param = 2;
         if (level == 0) cycle_param = 0;
      }
      else
      {
         Not_Finished = 0;
      }
   }

   hypre_ParAMGDataCycleOpCount(amg_data) = cycle_op_count;

   hypre_TFree(lev_counter);
   hypre_TFree(num_coeffs);

   return(Solve_err_flag);
}
Пример #2
0
int
hypre_BoomerAMGSetupStats( void               *amg_vdata,
                        hypre_ParCSRMatrix *A         )
{
   MPI_Comm 	      comm = hypre_ParCSRMatrixComm(A);   

   hypre_ParAMGData *amg_data = (hypre_ParAMGData*)amg_vdata;

   /*hypre_SeqAMGData *seq_data = hypre_ParAMGDataSeqData(amg_data);*/

   /* Data Structure variables */

   hypre_ParCSRMatrix **A_array;
   hypre_ParCSRMatrix **P_array;

   hypre_CSRMatrix *A_diag;
   double          *A_diag_data;
   int             *A_diag_i;

   hypre_CSRMatrix *A_offd;   
   double          *A_offd_data;
   int             *A_offd_i;

   hypre_CSRMatrix *P_diag;
   double          *P_diag_data;
   int             *P_diag_i;

   hypre_CSRMatrix *P_offd;   
   double          *P_offd_data;
   int             *P_offd_i;


   int	    numrows;

   HYPRE_BigInt	    *row_starts;

 
   int      num_levels; 
   int      coarsen_type;
   int      interp_type;
   int      measure_type;
   double   global_nonzeros;

   double  *send_buff;
   double  *gather_buff;
 
   /* Local variables */

   int       level;
   int       j;
   HYPRE_BigInt fine_size;
 
   int       min_entries;
   int       max_entries;

   int       num_procs,my_id, num_threads;


   double    min_rowsum;
   double    max_rowsum;
   double    sparse;


   int       i;
   

   HYPRE_BigInt coarse_size;
   int       entries;

   double    avg_entries;
   double    rowsum;

   double    min_weight;
   double    max_weight;

   int       global_min_e;
   int       global_max_e;
   double    global_min_rsum;
   double    global_max_rsum;
   double    global_min_wt;
   double    global_max_wt;

   double  *num_coeffs;
   double  *num_variables;
   double   total_variables; 
   double   operat_cmplxty;
   double   grid_cmplxty;

   /* amg solve params */
   int      max_iter;
   int      cycle_type;    
   int     *num_grid_sweeps;  
   int     *grid_relax_type;   
   int      relax_order;
   int    **grid_relax_points; 
   double  *relax_weight;
   double  *omega;
   double   tol;


   int one = 1;
   int minus_one = -1;
   int zero = 0;
   int smooth_type;
   int smooth_num_levels;
   int agg_num_levels;
   /*int seq_cg = 0;*/
   
   /*if (seq_data)
      seq_cg = 1;*/


   MPI_Comm_size(comm, &num_procs);   
   MPI_Comm_rank(comm,&my_id);
   num_threads = hypre_NumThreads();

   if (my_id == 0)
      printf("\nNumber of MPI processes: %d , Number of OpenMP threads: %d\n", num_procs, num_threads);
   A_array = hypre_ParAMGDataAArray(amg_data);
   P_array = hypre_ParAMGDataPArray(amg_data);
   num_levels = hypre_ParAMGDataNumLevels(amg_data);
   coarsen_type = hypre_ParAMGDataCoarsenType(amg_data);
   interp_type = hypre_ParAMGDataInterpType(amg_data);
   measure_type = hypre_ParAMGDataMeasureType(amg_data);
   smooth_type = hypre_ParAMGDataSmoothType(amg_data);
   smooth_num_levels = hypre_ParAMGDataSmoothNumLevels(amg_data);
   agg_num_levels = hypre_ParAMGDataAggNumLevels(amg_data);


   /*----------------------------------------------------------
    * Get the amg_data data
    *----------------------------------------------------------*/

   num_levels = hypre_ParAMGDataNumLevels(amg_data);
   max_iter   = hypre_ParAMGDataMaxIter(amg_data);
   cycle_type = hypre_ParAMGDataCycleType(amg_data);    
   num_grid_sweeps = hypre_ParAMGDataNumGridSweeps(amg_data);  
   grid_relax_type = hypre_ParAMGDataGridRelaxType(amg_data);
   grid_relax_points = hypre_ParAMGDataGridRelaxPoints(amg_data);
   relax_weight = hypre_ParAMGDataRelaxWeight(amg_data); 
   relax_order = hypre_ParAMGDataRelaxOrder(amg_data); 
   omega = hypre_ParAMGDataOmega(amg_data); 
   tol = hypre_ParAMGDataTol(amg_data);

   /*block_mode = hypre_ParAMGDataBlockMode(amg_data);*/

   send_buff     = hypre_CTAlloc(double, 6);
#ifdef HYPRE_NO_GLOBAL_PARTITION
   gather_buff = hypre_CTAlloc(double,6);    
#else
   gather_buff = hypre_CTAlloc(double,6*num_procs);    
#endif

   if (my_id==0)
   {
      printf("\nBoomerAMG SETUP PARAMETERS:\n\n");
      printf(" Max levels = %d\n",hypre_ParAMGDataMaxLevels(amg_data));
      printf(" Num levels = %d\n\n",num_levels);
      printf(" Strength Threshold = %f\n", 
                         hypre_ParAMGDataStrongThreshold(amg_data));
      printf(" Interpolation Truncation Factor = %f\n", 
                         hypre_ParAMGDataTruncFactor(amg_data));
      printf(" Maximum Row Sum Threshold for Dependency Weakening = %f\n\n", 
                         hypre_ParAMGDataMaxRowSum(amg_data));

      if (coarsen_type == 0)
      {
	printf(" Coarsening Type = Cleary-Luby-Jones-Plassman\n");
      }
      else if (abs(coarsen_type) == 1) 
      {
	printf(" Coarsening Type = Ruge\n");
      }
      else if (abs(coarsen_type) == 2) 
      {
	printf(" Coarsening Type = Ruge2B\n");
      }
      else if (abs(coarsen_type) == 3) 
      {
	printf(" Coarsening Type = Ruge3\n");
      }
      else if (abs(coarsen_type) == 4) 
      {
	printf(" Coarsening Type = Ruge 3c \n");
      }
      else if (abs(coarsen_type) == 5) 
      {
	printf(" Coarsening Type = Ruge relax special points \n");
      }
      else if (abs(coarsen_type) == 6) 
      {
	printf(" Coarsening Type = Falgout-CLJP \n");
      }
      else if (abs(coarsen_type) == 8) 
      {
	printf(" Coarsening Type = PMIS \n");
      }
      else if (abs(coarsen_type) == 10) 
      {
	printf(" Coarsening Type = HMIS \n");
      }
      else if (abs(coarsen_type) == 11) 
      {
	printf(" Coarsening Type = Ruge 1st pass only \n");
      }
      else if (abs(coarsen_type) == 9) 
      {
	printf(" Coarsening Type = PMIS fixed random \n");
      }
      else if (abs(coarsen_type) == 7) 
      {
	printf(" Coarsening Type = CLJP, fixed random \n");
      }
      if (coarsen_type > 0) 
      {
	printf(" Hybrid Coarsening (switch to CLJP when coarsening slows)\n");
      }
      

      if (coarsen_type)
      	printf(" measures are determined %s\n\n", 
                  (measure_type ? "globally" : "locally"));

      if (agg_num_levels)
	printf(" no. of levels of aggressive coarsening: %d\n\n", agg_num_levels);

#ifdef HYPRE_NO_GLOBAL_PARTITION
      printf( "\n No global partition option chosen.\n\n");
#endif

      if (interp_type == 0)
      {
	printf(" Interpolation = modified classical interpolation\n");
      }
      else if (interp_type == 1) 
      {
	printf(" Interpolation = LS interpolation \n");
      }
      else if (interp_type == 2) 
      {
	printf(" Interpolation = modified classical interpolation for hyperbolic PDEs\n");
      }
      else if (interp_type == 3) 
      {
	printf(" Interpolation = direct interpolation with separation of weights\n");
      }
      else if (interp_type == 4) 
      {
	printf(" Interpolation = multipass interpolation\n");
      }
      else if (interp_type == 5) 
      {
	printf(" Interpolation = multipass interpolation with separation of weights\n");
      }
      else if (interp_type == 6) 
      {
	printf(" Interpolation = extended+i interpolation\n");
      }
      else if (interp_type == 7) 
      {
	printf(" Interpolation = extended+i interpolation (only when needed)\n");
      }
      else if (interp_type == 8) 
      {
	printf(" Interpolation = standard interpolation\n");
      }
      else if (interp_type == 9) 
      {
	printf(" Interpolation = standard interpolation with separation of weights\n");
      }
      else if (interp_type == 12) 
      {
	printf(" FF interpolation \n");
      }
      else if (interp_type == 13) 
      {
	printf(" FF1 interpolation \n");
      }

      {
         printf( "\nOperator Matrix Information:\n\n");
      }
#if HYPRE_LONG_LONG
      printf("                  nonzero         entries p");
      printf("er row        row sums\n");
      printf("lev        rows   entries  sparse  min  max   ");
      printf("avg       min         max\n");
      printf("=======================================");
      printf("==================================\n");
#else      
      printf("            nonzero         entries p");
      printf("er row        row sums\n");
      printf("lev   rows  entries  sparse  min  max   ");
      printf("avg       min         max\n");
      printf("=======================================");
      printf("============================\n");
#endif
   }
  
   /*-----------------------------------------------------
    *  Enter Statistics Loop
    *-----------------------------------------------------*/

   num_coeffs = hypre_CTAlloc(double,num_levels);

   num_variables = hypre_CTAlloc(double,num_levels);

   for (level = 0; level < num_levels; level++)
   { 

      {
         A_diag = hypre_ParCSRMatrixDiag(A_array[level]);
         A_diag_data = hypre_CSRMatrixData(A_diag);
         A_diag_i = hypre_CSRMatrixI(A_diag);
         
         A_offd = hypre_ParCSRMatrixOffd(A_array[level]);   
         A_offd_data = hypre_CSRMatrixData(A_offd);
         A_offd_i = hypre_CSRMatrixI(A_offd);
         
         row_starts = hypre_ParCSRMatrixRowStarts(A_array[level]);
         
         fine_size = hypre_ParCSRMatrixGlobalNumRows(A_array[level]);
         global_nonzeros = hypre_ParCSRMatrixDNumNonzeros(A_array[level]);
         num_coeffs[level] = global_nonzeros;
         num_variables[level] = (double) fine_size;
         
         sparse = global_nonzeros /((double) fine_size * (double) fine_size);

         min_entries = 0;
         max_entries = 0;
         min_rowsum = 0.0;
         max_rowsum = 0.0;
         
         if (hypre_CSRMatrixNumRows(A_diag))
         {
            min_entries = (A_diag_i[1]-A_diag_i[0])+(A_offd_i[1]-A_offd_i[0]);
            for (j = A_diag_i[0]; j < A_diag_i[1]; j++)
               min_rowsum += A_diag_data[j];
            for (j = A_offd_i[0]; j < A_offd_i[1]; j++)
               min_rowsum += A_offd_data[j];
            
            max_rowsum = min_rowsum;
            
            for (j = 0; j < hypre_CSRMatrixNumRows(A_diag); j++)
            {
               entries = (A_diag_i[j+1]-A_diag_i[j])+(A_offd_i[j+1]-A_offd_i[j]);
               min_entries = hypre_min(entries, min_entries);
               max_entries = hypre_max(entries, max_entries);
               
               rowsum = 0.0;
               for (i = A_diag_i[j]; i < A_diag_i[j+1]; i++)
                  rowsum += A_diag_data[i];
               
               for (i = A_offd_i[j]; i < A_offd_i[j+1]; i++)
                  rowsum += A_offd_data[i];
               
               min_rowsum = hypre_min(rowsum, min_rowsum);
               max_rowsum = hypre_max(rowsum, max_rowsum);
            }
         }
         avg_entries = global_nonzeros / ((double) fine_size);
      }
      
#ifdef HYPRE_NO_GLOBAL_PARTITION       

       numrows = (int)(row_starts[1]-row_starts[0]);
       if (!numrows) /* if we don't have any rows, then don't have this count toward
                         min row sum or min num entries */
       {
          min_entries = 1000000;
          min_rowsum =  1.0e7;
       }
       
       send_buff[0] = - (double) min_entries;
       send_buff[1] = (double) max_entries;
       send_buff[2] = - min_rowsum;
       send_buff[3] = max_rowsum;

       MPI_Reduce(send_buff, gather_buff, 4, MPI_DOUBLE, MPI_MAX, 0, comm);
       
       if (my_id ==0)
       {
          global_min_e = - gather_buff[0];
          global_max_e = gather_buff[1];
          global_min_rsum = - gather_buff[2];
          global_max_rsum = gather_buff[3];
#ifdef HYPRE_LONG_LONG
          printf( "%2d %12lld %8.0f  %0.3f  %4d %4d",
                  level, fine_size, global_nonzeros, sparse, global_min_e, 
                  global_max_e);
#else          
          printf( "%2d %7d %8.0f  %0.3f  %4d %4d",
                  level, fine_size, global_nonzeros, sparse, global_min_e, 
                  global_max_e);
#endif          
          printf("  %4.1f  %10.3e  %10.3e\n", avg_entries,
                 global_min_rsum, global_max_rsum);
       }
       
#else

       send_buff[0] = (double) min_entries;
       send_buff[1] = (double) max_entries;
       send_buff[2] = min_rowsum;
       send_buff[3] = max_rowsum;
       
       MPI_Gather(send_buff,4,MPI_DOUBLE,gather_buff,4,MPI_DOUBLE,0,comm);

       if (my_id == 0)
       {
          global_min_e = 1000000;
          global_max_e = 0;
          global_min_rsum = 1.0e7;
          global_max_rsum = 0.0;
          for (j = 0; j < num_procs; j++)
          {
             numrows = row_starts[j+1]-row_starts[j];
             if (numrows)
             {
                global_min_e = hypre_min(global_min_e, (int) gather_buff[j*4]);
                global_min_rsum = hypre_min(global_min_rsum, gather_buff[j*4 +2]);
             }
             global_max_e = hypre_max(global_max_e, (int) gather_buff[j*4 +1]);
             global_max_rsum = hypre_max(global_max_rsum, gather_buff[j*4 +3]);
          }

#ifdef HYPRE_LONG_LONG
          printf( "%2d %12lld %8.0f  %0.3f  %4d %4d",
                  level, fine_size, global_nonzeros, sparse, global_min_e, 
                  global_max_e);
#else          
          printf( "%2d %7d %8.0f  %0.3f  %4d %4d",
                  level, fine_size, global_nonzeros, sparse, global_min_e, 
                  global_max_e);
#endif          
          printf("  %4.1f  %10.3e  %10.3e\n", avg_entries,
                 global_min_rsum, global_max_rsum);
       }

#endif

        
   }

       
   if (my_id == 0)
   {
      {
         printf( "\n\nInterpolation Matrix Information:\n\n");
      }
#if HYPRE_LONG_LONG
      printf("                             entries/row    min     max");
      printf("         row sums\n");
      printf("lev        rows x cols          min max  ");
      printf("   weight   weight     min       max \n");
      printf("=======================================");
      printf("======================================\n");
#else      
      printf("                 entries/row    min     max");
      printf("         row sums\n");
      printf("lev  rows cols    min max  ");
      printf("   weight   weight     min       max \n");
      printf("=======================================");
      printf("==========================\n");
#endif
   }
  
   /*-----------------------------------------------------
    *  Enter Statistics Loop
    *-----------------------------------------------------*/


   for (level = 0; level < num_levels-1; level++)
   {
    
      {
         P_diag = hypre_ParCSRMatrixDiag(P_array[level]);
         P_diag_data = hypre_CSRMatrixData(P_diag);
         P_diag_i = hypre_CSRMatrixI(P_diag);
         
         P_offd = hypre_ParCSRMatrixOffd(P_array[level]);   
         P_offd_data = hypre_CSRMatrixData(P_offd);
         P_offd_i = hypre_CSRMatrixI(P_offd);
         
         row_starts = hypre_ParCSRMatrixRowStarts(P_array[level]);
         
         fine_size = hypre_ParCSRMatrixGlobalNumRows(P_array[level]);
         coarse_size = hypre_ParCSRMatrixGlobalNumCols(P_array[level]);
         global_nonzeros = hypre_ParCSRMatrixNumNonzeros(P_array[level]);
         
         min_weight = 1.0;
         max_weight = 0.0;
         max_rowsum = 0.0;
         min_rowsum = 0.0;
         min_entries = 0;
         max_entries = 0;
         
         if (hypre_CSRMatrixNumRows(P_diag))
         {
            if (hypre_CSRMatrixNumCols(P_diag)) min_weight = P_diag_data[0];
            for (j = P_diag_i[0]; j < P_diag_i[1]; j++)
            {
               min_weight = hypre_min(min_weight, P_diag_data[j]);
               if (P_diag_data[j] != 1.0)
                  max_weight = hypre_max(max_weight, P_diag_data[j]);
               min_rowsum += P_diag_data[j];
            }
            for (j = P_offd_i[0]; j < P_offd_i[1]; j++)
            {        
               min_weight = hypre_min(min_weight, P_offd_data[j]); 
               if (P_offd_data[j] != 1.0)
                  max_weight = hypre_max(max_weight, P_offd_data[j]);     
               min_rowsum += P_offd_data[j];
            }
            
            max_rowsum = min_rowsum;
            
            min_entries = (P_diag_i[1]-P_diag_i[0])+(P_offd_i[1]-P_offd_i[0]); 
            max_entries = 0;
            
            for (j = 0; j < hypre_CSRMatrixNumRows(P_diag); j++)
            {
               entries = (P_diag_i[j+1]-P_diag_i[j])+(P_offd_i[j+1]-P_offd_i[j]);
               min_entries = hypre_min(entries, min_entries);
               max_entries = hypre_max(entries, max_entries);
               
               rowsum = 0.0;
               for (i = P_diag_i[j]; i < P_diag_i[j+1]; i++)
               {
                  min_weight = hypre_min(min_weight, P_diag_data[i]);
                  if (P_diag_data[i] != 1.0)
                     max_weight = hypre_max(max_weight, P_diag_data[i]);
                  rowsum += P_diag_data[i];
               }
               
               for (i = P_offd_i[j]; i < P_offd_i[j+1]; i++)
               {
                  min_weight = hypre_min(min_weight, P_offd_data[i]);
                  if (P_offd_data[i] != 1.0) 
                     max_weight = hypre_max(max_weight, P_offd_data[i]);
                  rowsum += P_offd_data[i];
               }
               
               min_rowsum = hypre_min(rowsum, min_rowsum);
               max_rowsum = hypre_max(rowsum, max_rowsum);
            }
         
         }
         avg_entries = ((double) global_nonzeros) / ((double) fine_size);
      }

#ifdef HYPRE_NO_GLOBAL_PARTITION

      numrows = (int)(row_starts[1]-row_starts[0]);
      if (!numrows) /* if we don't have any rows, then don't have this count toward
                       min row sum or min num entries */
      {
         min_entries = 1000000;
         min_rowsum =  1.0e7;
         min_weight = 1.0e7;
       }
       
      send_buff[0] = - (double) min_entries;
      send_buff[1] = (double) max_entries;
      send_buff[2] = - min_rowsum;
      send_buff[3] = max_rowsum;
      send_buff[4] = - min_weight;
      send_buff[5] = max_weight;

      MPI_Reduce(send_buff, gather_buff, 6, MPI_DOUBLE, MPI_MAX, 0, comm);

      if (my_id == 0)
      {
         global_min_e = - gather_buff[0];
         global_max_e = gather_buff[1];
         global_min_rsum = -gather_buff[2];
         global_max_rsum = gather_buff[3];
         global_min_wt = -gather_buff[4];
         global_max_wt = gather_buff[5];

#ifdef HYPRE_LONG_LONG
          printf( "%2d %12lld x %-12lld %3d %3d",
                 level, fine_size, coarse_size,  global_min_e, global_max_e);
#else          
          printf( "%2d %5d x %-5d %3d %3d",
                 level, fine_size, coarse_size,  global_min_e, global_max_e);
#endif          
         printf("  %10.3e %9.3e %9.3e %9.3e\n",
                global_min_wt, global_max_wt, 
                global_min_rsum, global_max_rsum);
      }


#else
      
      send_buff[0] = (double) min_entries;
      send_buff[1] = (double) max_entries;
      send_buff[2] = min_rowsum;
      send_buff[3] = max_rowsum;
      send_buff[4] = min_weight;
      send_buff[5] = max_weight;
      
      MPI_Gather(send_buff,6,MPI_DOUBLE,gather_buff,6,MPI_DOUBLE,0,comm);
      
      if (my_id == 0)
      {
         global_min_e = 1000000;
         global_max_e = 0;
         global_min_rsum = 1.0e7;
         global_max_rsum = 0.0;
         global_min_wt = 1.0e7;
         global_max_wt = 0.0;
         
         for (j = 0; j < num_procs; j++)
         {
            numrows = row_starts[j+1] - row_starts[j];
            if (numrows)
            {
               global_min_e = hypre_min(global_min_e, (int) gather_buff[j*6]);
               global_min_rsum = hypre_min(global_min_rsum, gather_buff[j*6+2]);
               global_min_wt = hypre_min(global_min_wt, gather_buff[j*6+4]);
            }
            global_max_e = hypre_max(global_max_e, (int) gather_buff[j*6+1]);
            global_max_rsum = hypre_max(global_max_rsum, gather_buff[j*6+3]);
            global_max_wt = hypre_max(global_max_wt, gather_buff[j*6+5]);
         }
         
#ifdef HYPRE_LONG_LONG
         printf( "%2d %12lld x %-12lld %3d %3d",
                 level, fine_size, coarse_size,  global_min_e, global_max_e);
#else          
         printf( "%2d %5d x %-5d %3d %3d",
                 level, fine_size, coarse_size,  global_min_e, global_max_e);
#endif          
         printf("  %10.3e %9.3e %9.3e %9.3e\n",
                global_min_wt, global_max_wt, 
                global_min_rsum, global_max_rsum);
      }

#endif

   }


   total_variables = 0;
   operat_cmplxty = 0;
   for (j=0;j<hypre_ParAMGDataNumLevels(amg_data);j++)
   {
      operat_cmplxty +=  num_coeffs[j] / num_coeffs[0];
      total_variables += num_variables[j];
   }
   if (num_variables[0] != 0)
      grid_cmplxty = total_variables / num_variables[0];
 
   if (my_id == 0 )
   {
      printf("\n\n     Complexity:    grid = %f\n",grid_cmplxty);
      printf("                operator = %f\n",operat_cmplxty);
   }

   if (my_id == 0) printf("\n\n");

   if (my_id == 0)
   { 
      printf("\n\nBoomerAMG SOLVER PARAMETERS:\n\n");
      printf( "  Maximum number of cycles:         %d \n",max_iter);
      printf( "  Stopping Tolerance:               %e \n",tol); 
      printf( "  Cycle type (1 = V, 2 = W, etc.):  %d\n\n", cycle_type);
      printf( "  Relaxation Parameters:\n");
      printf( "   Visiting Grid:                     down   up  coarse\n");
      printf( "            Number of partial sweeps: %4d   %2d  %4d \n",
              num_grid_sweeps[1],
              num_grid_sweeps[2],num_grid_sweeps[3]);
      printf( "   Type 0=Jac, 3=hGS, 6=hSGS, 9=GE:   %4d   %2d  %4d \n",
              grid_relax_type[1],
              grid_relax_type[2],grid_relax_type[3]);
#if 1 /* TO DO: may not want this to print if CG in the coarse grid */
      printf( "   Point types, partial sweeps (1=C, -1=F):\n");
      if (grid_relax_points)
      {
         printf( "                  Pre-CG relaxation (down):");
         for (j = 0; j < num_grid_sweeps[1]; j++)
              printf("  %2d", grid_relax_points[1][j]);
         printf( "\n");
         printf( "                   Post-CG relaxation (up):");
         for (j = 0; j < num_grid_sweeps[2]; j++)
              printf("  %2d", grid_relax_points[2][j]);
         printf( "\n");
         printf( "                             Coarsest grid:");
         for (j = 0; j < num_grid_sweeps[3]; j++)
              printf("  %2d", grid_relax_points[3][j]);
         printf( "\n\n");
      }
      else if (relax_order == 1)
      {
         printf( "                  Pre-CG relaxation (down):");
         for (j = 0; j < num_grid_sweeps[1]; j++)
              printf("  %2d  %2d", one, minus_one);
         printf( "\n");
         printf( "                   Post-CG relaxation (up):");
         for (j = 0; j < num_grid_sweeps[2]; j++)
              printf("  %2d  %2d", minus_one, one);
         printf( "\n");
         printf( "                             Coarsest grid:");
         for (j = 0; j < num_grid_sweeps[3]; j++)
              printf("  %2d", zero);
         printf( "\n\n");
      }
      else 
      {
         printf( "                  Pre-CG relaxation (down):");
         for (j = 0; j < num_grid_sweeps[1]; j++)
              printf("  %2d", zero);
         printf( "\n");
         printf( "                   Post-CG relaxation (up):");
         for (j = 0; j < num_grid_sweeps[2]; j++)
              printf("  %2d", zero);
         printf( "\n");
         printf( "                             Coarsest grid:");
         for (j = 0; j < num_grid_sweeps[3]; j++)
              printf("  %2d", zero);
         printf( "\n\n");
      }
#endif
      if (smooth_type == 6)
         for (j=0; j < smooth_num_levels; j++)
            printf( " Schwarz Relaxation Weight %f level %d\n",
			hypre_ParAMGDataSchwarzRlxWeight(amg_data),j);
      for (j=0; j < num_levels; j++)
         if (relax_weight[j] != 1)
	       printf( " Relaxation Weight %f level %d\n",relax_weight[j],j);
      for (j=0; j < num_levels; j++)
         if (omega[j] != 1)
               printf( " Outer relaxation weight %f level %d\n",omega[j],j);
   }


   /*if (seq_cg) 
   {
      hypre_seqAMGSetupStats(amg_data,num_coeffs[0],num_variables[0], 
                             operat_cmplxty, grid_cmplxty );
   }*/
   




   hypre_TFree(num_coeffs);
   hypre_TFree(num_variables);
   hypre_TFree(send_buff);
   hypre_TFree(gather_buff);
   
   return(0);
}  
Пример #3
0
int    hypre_BoomerAMGWriteSolverParams(void* data)
{ 
   hypre_ParAMGData  *amg_data = (hypre_ParAMGData*)data;
 
   /* amg solve params */
   int      num_levels; 
   int      max_iter;
   int      cycle_type;    
   int     *num_grid_sweeps;  
   int     *grid_relax_type;   
   int    **grid_relax_points; 
   int      relax_order;
   double  *relax_weight;
   double  *omega;
   double   tol;
   int      smooth_type; 
   int      smooth_num_levels; 
   /* amg output params */
   int      amg_print_level;
 
   int      j;
   int      one = 1;
   int      minus_one = -1;
   int      zero = 0;
 
 
   /*----------------------------------------------------------
    * Get the amg_data data
    *----------------------------------------------------------*/

   num_levels = hypre_ParAMGDataNumLevels(amg_data);
   max_iter   = hypre_ParAMGDataMaxIter(amg_data);
   cycle_type = hypre_ParAMGDataCycleType(amg_data);    
   num_grid_sweeps = hypre_ParAMGDataNumGridSweeps(amg_data);  
   grid_relax_type = hypre_ParAMGDataGridRelaxType(amg_data);
   grid_relax_points = hypre_ParAMGDataGridRelaxPoints(amg_data);
   relax_order = hypre_ParAMGDataRelaxOrder(amg_data);
   relax_weight = hypre_ParAMGDataRelaxWeight(amg_data); 
   omega = hypre_ParAMGDataOmega(amg_data); 
   smooth_type = hypre_ParAMGDataSmoothType(amg_data); 
   smooth_num_levels = hypre_ParAMGDataSmoothNumLevels(amg_data); 
   tol = hypre_ParAMGDataTol(amg_data);
 
   amg_print_level = hypre_ParAMGDataPrintLevel(amg_data);
 
   /*----------------------------------------------------------
    * AMG info
    *----------------------------------------------------------*/
 
   if (amg_print_level == 1 || amg_print_level == 3)
   { 
      printf("\n\nBoomerAMG SOLVER PARAMETERS:\n\n");
      printf( "  Maximum number of cycles:         %d \n",max_iter);
      printf( "  Stopping Tolerance:               %e \n",tol); 
      printf( "  Cycle type (1 = V, 2 = W, etc.):  %d\n\n", cycle_type);
      printf( "  Relaxation Parameters:\n");
      printf( "   Visiting Grid:                     down   up  coarse\n");
      printf( "   Visiting Grid:                     down   up  coarse\n");
      printf( "            Number of partial sweeps: %4d   %2d  %4d \n",
              num_grid_sweeps[1],
              num_grid_sweeps[2],num_grid_sweeps[3]);
      printf( "   Type 0=Jac, 3=hGS, 6=hSGS, 9=GE:   %4d   %2d  %4d \n",
              grid_relax_type[1],
              grid_relax_type[2],grid_relax_type[3]);
      printf( "   Point types, partial sweeps (1=C, -1=F):\n");
      if (grid_relax_points)
      {
         printf( "                  Pre-CG relaxation (down):");
         for (j = 0; j < num_grid_sweeps[1]; j++)
              printf("  %2d", grid_relax_points[1][j]);
         printf( "\n");
         printf( "                   Post-CG relaxation (up):");
         for (j = 0; j < num_grid_sweeps[2]; j++)
              printf("  %2d", grid_relax_points[2][j]);
         printf( "\n");
         printf( "                             Coarsest grid:");
         for (j = 0; j < num_grid_sweeps[3]; j++)
              printf("  %2d", grid_relax_points[3][j]);
         printf( "\n\n");
      }
      else if (relax_order == 1)
      {
         printf( "                  Pre-CG relaxation (down):");
         for (j = 0; j < num_grid_sweeps[1]; j++)
              printf("  %2d  %2d", one, minus_one);
         printf( "\n");
         printf( "                   Post-CG relaxation (up):");
         for (j = 0; j < num_grid_sweeps[2]; j++)
              printf("  %2d  %2d", minus_one, one);
         printf( "\n");
         printf( "                             Coarsest grid:");
         for (j = 0; j < num_grid_sweeps[3]; j++)
              printf("  %2d", zero);
         printf( "\n\n");
      }
      else 
      {
         printf( "                  Pre-CG relaxation (down):");
         for (j = 0; j < num_grid_sweeps[1]; j++)
              printf("  %2d", zero);
         printf( "\n");
         printf( "                   Post-CG relaxation (up):");
         for (j = 0; j < num_grid_sweeps[2]; j++)
              printf("  %2d", zero);
         printf( "\n");
         printf( "                             Coarsest grid:");
         for (j = 0; j < num_grid_sweeps[3]; j++)
              printf("  %2d", zero);
         printf( "\n\n");
      }
      if (smooth_type == 6)
         for (j=0; j < smooth_num_levels; j++)
            printf( " Schwarz Relaxation Weight %f level %d\n",
			hypre_ParAMGDataSchwarzRlxWeight(amg_data),j);
      for (j=0; j < num_levels; j++)
         if (relax_weight[j] != 1)
	       printf( " Relaxation Weight %f level %d\n",relax_weight[j],j);
      for (j=0; j < num_levels; j++)
         if (omega[j] != 1)
               printf( " Outer relaxation weight %f level %d\n",omega[j],j);

      printf( " Output flag (print_level): %d \n", amg_print_level);
   }
 
   return 0;
}
Пример #4
0
HYPRE_Int
hypre_BoomerAMGCycle( void              *amg_vdata, 
                   hypre_ParVector  **F_array,
                   hypre_ParVector  **U_array   )
{
   hypre_ParAMGData *amg_data = amg_vdata;

   HYPRE_Solver *smoother;
   /* Data Structure variables */

   hypre_ParCSRMatrix    **A_array;
   hypre_ParCSRMatrix    **P_array;
   hypre_ParCSRMatrix    **R_array;
   hypre_ParVector    *Utemp;
   hypre_ParVector    *Vtemp;
   hypre_ParVector    *Rtemp;
   hypre_ParVector    *Ptemp;
   hypre_ParVector    *Ztemp;
   hypre_ParVector    *Aux_U;
   hypre_ParVector    *Aux_F;

   hypre_ParCSRBlockMatrix    **A_block_array;
   hypre_ParCSRBlockMatrix    **P_block_array;
   hypre_ParCSRBlockMatrix    **R_block_array;

   HYPRE_Real   *Ztemp_data;
   HYPRE_Real   *Ptemp_data;
   HYPRE_Int     **CF_marker_array;
   /* HYPRE_Int     **unknown_map_array;
   HYPRE_Int     **point_map_array;
   HYPRE_Int     **v_at_point_array; */

   HYPRE_Real    cycle_op_count;   
   HYPRE_Int       cycle_type;
   HYPRE_Int       num_levels;
   HYPRE_Int       max_levels;

   HYPRE_Real   *num_coeffs;
   HYPRE_Int      *num_grid_sweeps;   
   HYPRE_Int      *grid_relax_type;   
   HYPRE_Int     **grid_relax_points;  

   HYPRE_Int     block_mode;
   
   HYPRE_Real  *max_eig_est;
   HYPRE_Real  *min_eig_est;
   HYPRE_Int      cheby_order;
   HYPRE_Real   cheby_fraction;

 /* Local variables  */ 
   HYPRE_Int      *lev_counter;
   HYPRE_Int       Solve_err_flag;
   HYPRE_Int       k;
   HYPRE_Int       i, j, jj;
   HYPRE_Int       level;
   HYPRE_Int       cycle_param;
   HYPRE_Int       coarse_grid;
   HYPRE_Int       fine_grid;
   HYPRE_Int       Not_Finished;
   HYPRE_Int       num_sweep;
   HYPRE_Int       cg_num_sweep = 1;
   HYPRE_Int       relax_type;
   HYPRE_Int       relax_points;
   HYPRE_Int       relax_order;
   HYPRE_Int       relax_local;
   HYPRE_Int       old_version = 0;
   HYPRE_Real   *relax_weight;
   HYPRE_Real   *omega;
   HYPRE_Real    alfa, beta, gammaold;
   HYPRE_Real    gamma = 1.0;
   HYPRE_Int       local_size;
/*   HYPRE_Int      *smooth_option; */
   HYPRE_Int       smooth_type;
   HYPRE_Int       smooth_num_levels;
   HYPRE_Int       num_threads, my_id;

   HYPRE_Real    alpha;
   HYPRE_Real  **l1_norms = NULL;
   HYPRE_Real   *l1_norms_level;

   HYPRE_Int seq_cg = 0;

   MPI_Comm comm;

#if 0
   HYPRE_Real   *D_mat;
   HYPRE_Real   *S_vec;
#endif
   
   /* Acquire data and allocate storage */

   num_threads = hypre_NumThreads();

   A_array           = hypre_ParAMGDataAArray(amg_data);
   P_array           = hypre_ParAMGDataPArray(amg_data);
   R_array           = hypre_ParAMGDataRArray(amg_data);
   CF_marker_array   = hypre_ParAMGDataCFMarkerArray(amg_data);
   Vtemp             = hypre_ParAMGDataVtemp(amg_data);
   Rtemp             = hypre_ParAMGDataRtemp(amg_data);
   Ptemp             = hypre_ParAMGDataPtemp(amg_data);
   Ztemp             = hypre_ParAMGDataZtemp(amg_data);
   num_levels        = hypre_ParAMGDataNumLevels(amg_data);
   max_levels        = hypre_ParAMGDataMaxLevels(amg_data);
   cycle_type        = hypre_ParAMGDataCycleType(amg_data);

   A_block_array     = hypre_ParAMGDataABlockArray(amg_data);
   P_block_array     = hypre_ParAMGDataPBlockArray(amg_data);
   R_block_array     = hypre_ParAMGDataRBlockArray(amg_data);
   block_mode        = hypre_ParAMGDataBlockMode(amg_data);

   num_grid_sweeps     = hypre_ParAMGDataNumGridSweeps(amg_data);
   grid_relax_type     = hypre_ParAMGDataGridRelaxType(amg_data);
   grid_relax_points   = hypre_ParAMGDataGridRelaxPoints(amg_data);
   relax_order         = hypre_ParAMGDataRelaxOrder(amg_data);
   relax_weight        = hypre_ParAMGDataRelaxWeight(amg_data); 
   omega               = hypre_ParAMGDataOmega(amg_data); 
   smooth_type         = hypre_ParAMGDataSmoothType(amg_data); 
   smooth_num_levels   = hypre_ParAMGDataSmoothNumLevels(amg_data); 
   l1_norms            = hypre_ParAMGDataL1Norms(amg_data); 
   /* smooth_option       = hypre_ParAMGDataSmoothOption(amg_data); */

   max_eig_est = hypre_ParAMGDataMaxEigEst(amg_data);
   min_eig_est = hypre_ParAMGDataMinEigEst(amg_data);
   cheby_order = hypre_ParAMGDataChebyOrder(amg_data);
   cheby_fraction = hypre_ParAMGDataChebyFraction(amg_data);

   cycle_op_count = hypre_ParAMGDataCycleOpCount(amg_data);

   lev_counter = hypre_CTAlloc(HYPRE_Int, num_levels);

   if (hypre_ParAMGDataParticipate(amg_data)) seq_cg = 1;

   /* Initialize */

   Solve_err_flag = 0;

   if (grid_relax_points) old_version = 1;

   num_coeffs = hypre_CTAlloc(HYPRE_Real, num_levels);
   num_coeffs[0]    = hypre_ParCSRMatrixDNumNonzeros(A_array[0]);
   comm = hypre_ParCSRMatrixComm(A_array[0]);
   hypre_MPI_Comm_rank(comm,&my_id);

   if (block_mode)
   {
      for (j = 1; j < num_levels; j++)
         num_coeffs[j] = hypre_ParCSRBlockMatrixNumNonzeros(A_block_array[j]);
      
   }
   else 
   {
       for (j = 1; j < num_levels; j++)
         num_coeffs[j] = hypre_ParCSRMatrixDNumNonzeros(A_array[j]);
   }
   
   /*---------------------------------------------------------------------
    *    Initialize cycling control counter
    *
    *     Cycling is controlled using a level counter: lev_counter[k]
    *     
    *     Each time relaxation is performed on level k, the
    *     counter is decremented by 1. If the counter is then
    *     negative, we go to the next finer level. If non-
    *     negative, we go to the next coarser level. The
    *     following actions control cycling:
    *     
    *     a. lev_counter[0] is initialized to 1.
    *     b. lev_counter[k] is initialized to cycle_type for k>0.
    *     
    *     c. During cycling, when going down to level k, lev_counter[k]
    *        is set to the max of (lev_counter[k],cycle_type)
    *---------------------------------------------------------------------*/

   Not_Finished = 1;

   lev_counter[0] = 1;
   for (k = 1; k < num_levels; ++k) 
   {
      lev_counter[k] = cycle_type;
   }

   level = 0;
   cycle_param = 1;

   smoother = hypre_ParAMGDataSmoother(amg_data);

   if (smooth_num_levels > 0)
   {
      if (smooth_type == 7 || smooth_type == 8
          || smooth_type == 17 || smooth_type == 18
          || smooth_type == 9 || smooth_type == 19)
      {
         HYPRE_Int actual_local_size = hypre_ParVectorActualLocalSize(Vtemp);
         Utemp = hypre_ParVectorCreate(comm,hypre_ParVectorGlobalSize(Vtemp),
                        hypre_ParVectorPartitioning(Vtemp));
         hypre_ParVectorOwnsPartitioning(Utemp) = 0;
         local_size 
            = hypre_VectorSize(hypre_ParVectorLocalVector(Vtemp));
         if (local_size < actual_local_size)
         {
            hypre_VectorData(hypre_ParVectorLocalVector(Utemp)) =
	 	hypre_CTAlloc(HYPRE_Complex, actual_local_size);
            hypre_ParVectorActualLocalSize(Utemp) = actual_local_size;
         }
         else
	     hypre_ParVectorInitialize(Utemp);
      }
   }
   
  
   /*---------------------------------------------------------------------
    * Main loop of cycling
    *--------------------------------------------------------------------*/
  
   while (Not_Finished)
   {
      if (num_levels > 1) 
      {
        local_size 
            = hypre_VectorSize(hypre_ParVectorLocalVector(F_array[level]));
        hypre_VectorSize(hypre_ParVectorLocalVector(Vtemp)) = local_size;
        if (smooth_num_levels <= level)
	{
           cg_num_sweep = 1;
           num_sweep = num_grid_sweeps[cycle_param];
           Aux_U = U_array[level];
           Aux_F = F_array[level];
	}
	else if (smooth_type > 9)
	{
           hypre_VectorSize(hypre_ParVectorLocalVector(Ztemp)) = local_size;
           hypre_VectorSize(hypre_ParVectorLocalVector(Rtemp)) = local_size;
           hypre_VectorSize(hypre_ParVectorLocalVector(Ptemp)) = local_size;
           Ztemp_data = hypre_VectorData(hypre_ParVectorLocalVector(Ztemp));
           Ptemp_data = hypre_VectorData(hypre_ParVectorLocalVector(Ptemp));
           hypre_ParVectorSetConstantValues(Ztemp,0);
           alpha = -1.0;
           beta = 1.0;
           hypre_ParCSRMatrixMatvecOutOfPlace(alpha, A_array[level], 
                                U_array[level], beta, F_array[level], Rtemp);
	   cg_num_sweep = hypre_ParAMGDataSmoothNumSweeps(amg_data);
           num_sweep = num_grid_sweeps[cycle_param];
           Aux_U = Ztemp;
           Aux_F = Rtemp;
	}
	else 
	{
           cg_num_sweep = 1;
	   num_sweep = hypre_ParAMGDataSmoothNumSweeps(amg_data);
           Aux_U = U_array[level];
           Aux_F = F_array[level];
	}
        relax_type = grid_relax_type[cycle_param];
      }
      else /* AB: 4/08: removed the max_levels > 1 check - should do this when max-levels = 1 also */
      {
        /* If no coarsening occurred, apply a simple smoother once */
        Aux_U = U_array[level];
        Aux_F = F_array[level];
        num_sweep = 1;
        /* TK: Use the user relax type (instead of 0) to allow for setting a
           convergent smoother (e.g. in the solution of singular problems). */
        relax_type = hypre_ParAMGDataUserRelaxType(amg_data);
      }

      if (l1_norms != NULL)
         l1_norms_level = l1_norms[level];
      else
         l1_norms_level = NULL;

      if (cycle_param == 3 && seq_cg)
      {
         hypre_seqAMGCycle(amg_data, level, F_array, U_array);
      }
      else
      {
         
        /*------------------------------------------------------------------
         * Do the relaxation num_sweep times
         *-----------------------------------------------------------------*/
         for (jj = 0; jj < cg_num_sweep; jj++)
         {
	   if (smooth_num_levels > level && smooth_type > 9)
              hypre_ParVectorSetConstantValues(Aux_U,0);

           for (j = 0; j < num_sweep; j++)
           {
              if (num_levels == 1 && max_levels > 1)
              {
                 relax_points = 0;
                 relax_local = 0;
              }
              else
              {
                 if (old_version)
		    relax_points = grid_relax_points[cycle_param][j];
                 relax_local = relax_order;
              }

              /*-----------------------------------------------
               * VERY sloppy approximation to cycle complexity
               *-----------------------------------------------*/
              if (old_version && level < num_levels -1)
              {
                 switch (relax_points)
                 {
                    case 1:
                    cycle_op_count += num_coeffs[level+1];
                    break;
  
                    case -1: 
                    cycle_op_count += (num_coeffs[level]-num_coeffs[level+1]); 
                    break;
                 }
              }
	      else
              {
                 cycle_op_count += num_coeffs[level]; 
              }
              /*-----------------------------------------------
                Choose Smoother
                -----------------------------------------------*/

              if (smooth_num_levels > level && 
			(smooth_type == 7 || smooth_type == 8 ||
			smooth_type == 9 || smooth_type == 19 ||
			smooth_type == 17 || smooth_type == 18))
              {
                 hypre_VectorSize(hypre_ParVectorLocalVector(Utemp)) = local_size;
                 alpha = -1.0;
                 beta = 1.0;
                 hypre_ParCSRMatrixMatvecOutOfPlace(alpha, A_array[level], 
                                U_array[level], beta, Aux_F, Vtemp);
                 if (smooth_type == 8 || smooth_type == 18)
                    HYPRE_ParCSRParaSailsSolve(smoother[level],
                                 (HYPRE_ParCSRMatrix) A_array[level],
                                 (HYPRE_ParVector) Vtemp,
                                 (HYPRE_ParVector) Utemp);
                 else if (smooth_type == 7 || smooth_type == 17)
                    HYPRE_ParCSRPilutSolve(smoother[level],
                                 (HYPRE_ParCSRMatrix) A_array[level],
                                 (HYPRE_ParVector) Vtemp,
                                 (HYPRE_ParVector) Utemp);
                 else if (smooth_type == 9 || smooth_type == 19)
                    HYPRE_EuclidSolve(smoother[level],
                                 (HYPRE_ParCSRMatrix) A_array[level],
                                 (HYPRE_ParVector) Vtemp,
                                 (HYPRE_ParVector) Utemp);
                 hypre_ParVectorAxpy(relax_weight[level],Utemp,Aux_U);
	      }
              else if (smooth_num_levels > level &&
			(smooth_type == 6 || smooth_type == 16))
              {
                 HYPRE_SchwarzSolve(smoother[level],
                                 (HYPRE_ParCSRMatrix) A_array[level],
                                 (HYPRE_ParVector) Aux_F,
                                  (HYPRE_ParVector) Aux_U);
              }
              /*else if (relax_type == 99)*/
              else if (relax_type == 9 || relax_type == 99)
              { /* Gaussian elimination */
                 hypre_GaussElimSolve(amg_data, level, relax_type);
              }
              else if (relax_type == 18)
              {   /* L1 - Jacobi*/
                 if (relax_order == 1 && cycle_param < 3)
                 {
                    /* need to do CF - so can't use the AMS one */
                    HYPRE_Int i;
                    HYPRE_Int loc_relax_points[2];
                    if (cycle_type < 2)
                    {
                       loc_relax_points[0] = 1;
                       loc_relax_points[1] = -1;
                    }
                    else
                    {
                       loc_relax_points[0] = -1;
                       loc_relax_points[1] = 1;
                    }
                    for (i=0; i < 2; i++)
                       hypre_ParCSRRelax_L1_Jacobi(A_array[level],
                                                 Aux_F,
                                                 CF_marker_array[level],
                                                 loc_relax_points[i],
                                                 relax_weight[level],
                                                 l1_norms[level],
                                                 Aux_U,
                                                 Vtemp);
                 }
                 else /* not CF - so use through AMS */
                 {
                    if (num_threads == 1)
                       hypre_ParCSRRelax(A_array[level], 
                                       Aux_F,
                                       1,
                                       1,
                                       l1_norms_level,
                                       relax_weight[level],
                                       omega[level],0,0,0,0,
                                       Aux_U,
                                       Vtemp, 
                                       Ztemp);

                    else
                       hypre_ParCSRRelaxThreads(A_array[level], 
                                              Aux_F,
                                              1,
                                              1,
                                              l1_norms_level,
                                              relax_weight[level],
                                              omega[level],
                                              Aux_U,
                                              Vtemp,
                                              Ztemp);
                 }
              }
              else if (relax_type == 15)
              {  /* CG */
                 if (j ==0) /* do num sweep iterations of CG */
                    hypre_ParCSRRelax_CG( smoother[level],
                                        A_array[level], 
                                        Aux_F,      
                                        Aux_U,
                                        num_sweep);
              }
              else if (relax_type == 16)
              { /* scaled Chebyshev */
                 HYPRE_Int scale = 1;
                 HYPRE_Int variant = 0;
                 hypre_ParCSRRelax_Cheby(A_array[level], 
                                       Aux_F,
                                       max_eig_est[level],     
                                       min_eig_est[level],     
                                       cheby_fraction, cheby_order, scale,
                                       variant, Aux_U, Vtemp, Ztemp );
              }
              else if (relax_type ==17)
              {
                 hypre_BoomerAMGRelax_FCFJacobi(A_array[level], 
                                              Aux_F,
                                              CF_marker_array[level],
                                              relax_weight[level],
                                              Aux_U,
                                              Vtemp);
              }
	      else if (old_version)
	      {
                 Solve_err_flag = hypre_BoomerAMGRelax(A_array[level], 
                                                     Aux_F,
                                                     CF_marker_array[level],
                                                     relax_type, relax_points,
                                                     relax_weight[level],
                                                     omega[level],
                                                     l1_norms_level,
                                                     Aux_U,
                                                     Vtemp, 
                                                     Ztemp);
	      }
	      else 
	      {
                 /* smoother than can have CF ordering */
                 if (block_mode)
                 {
                     Solve_err_flag = hypre_BoomerAMGBlockRelaxIF(A_block_array[level], 
                                                                  Aux_F,
                                                                  CF_marker_array[level],
                                                                  relax_type,
                                                                  relax_local,
                                                                  cycle_param,
                                                                  relax_weight[level],
                                                                  omega[level],
                                                                  Aux_U,
                                                                  Vtemp);
                 }
                 else
                 {
                    Solve_err_flag = hypre_BoomerAMGRelaxIF(A_array[level], 
                                                          Aux_F,
                                                          CF_marker_array[level],
                                                          relax_type,
                                                          relax_local,
                                                          cycle_param,
                                                          relax_weight[level],
                                                          omega[level],
                                                          l1_norms_level,
                                                          Aux_U,
                                                          Vtemp, 
                                                          Ztemp);
                 }
	      }
 
              if (Solve_err_flag != 0)
                 return(Solve_err_flag);
           }
           if  (smooth_num_levels > level && smooth_type > 9)
           {
              gammaold = gamma;
              gamma = hypre_ParVectorInnerProd(Rtemp,Ztemp);
              if (jj == 0)
                 hypre_ParVectorCopy(Ztemp,Ptemp);
              else
              {
                 beta = gamma/gammaold;
                 for (i=0; i < local_size; i++)
		    Ptemp_data[i] = Ztemp_data[i] + beta*Ptemp_data[i];
              }
              hypre_ParCSRMatrixMatvec(1.0,A_array[level],Ptemp,0.0,Vtemp);
              alfa = gamma /hypre_ParVectorInnerProd(Ptemp,Vtemp);
              hypre_ParVectorAxpy(alfa,Ptemp,U_array[level]);
              hypre_ParVectorAxpy(-alfa,Vtemp,Rtemp);
           }
        }
      }

      /*------------------------------------------------------------------
       * Decrement the control counter and determine which grid to visit next
       *-----------------------------------------------------------------*/

      --lev_counter[level];
       
      if (lev_counter[level] >= 0 && level != num_levels-1)
      {
                               
         /*---------------------------------------------------------------
          * Visit coarser level next.  
 	  * Compute residual using hypre_ParCSRMatrixMatvec.
          * Perform restriction using hypre_ParCSRMatrixMatvecT.
          * Reset counters and cycling parameters for coarse level
          *--------------------------------------------------------------*/

         fine_grid = level;
         coarse_grid = level + 1;

         hypre_ParVectorSetConstantValues(U_array[coarse_grid], 0.0); 
          
         alpha = -1.0;
         beta = 1.0;

         if (block_mode)
         {
            hypre_ParVectorCopy(F_array[fine_grid],Vtemp);
            hypre_ParCSRBlockMatrixMatvec(alpha, A_block_array[fine_grid], U_array[fine_grid],
                                          beta, Vtemp);
         }
         else 
         {
            // JSP: avoid unnecessary copy using out-of-place version of SpMV
            hypre_ParCSRMatrixMatvecOutOfPlace(alpha, A_array[fine_grid], U_array[fine_grid],
                                               beta, F_array[fine_grid], Vtemp);
         }

         alpha = 1.0;
         beta = 0.0;

         if (block_mode)
         {
            hypre_ParCSRBlockMatrixMatvecT(alpha,R_block_array[fine_grid],Vtemp,
                                      beta,F_array[coarse_grid]);
         }
         else
         {
            hypre_ParCSRMatrixMatvecT(alpha,R_array[fine_grid],Vtemp,
                                      beta,F_array[coarse_grid]);
         }

         ++level;
         lev_counter[level] = hypre_max(lev_counter[level],cycle_type);
         cycle_param = 1;
         if (level == num_levels-1) cycle_param = 3;
      }

      else if (level != 0)
      {
         /*---------------------------------------------------------------
          * Visit finer level next.
          * Interpolate and add correction using hypre_ParCSRMatrixMatvec.
          * Reset counters and cycling parameters for finer level.
          *--------------------------------------------------------------*/

         fine_grid = level - 1;
         coarse_grid = level;
         alpha = 1.0;
         beta = 1.0;
         if (block_mode)
         {
            hypre_ParCSRBlockMatrixMatvec(alpha, P_block_array[fine_grid], 
                                     U_array[coarse_grid],
                                     beta, U_array[fine_grid]);   
         }
         else 
         {
            hypre_ParCSRMatrixMatvec(alpha, P_array[fine_grid], 
                                     U_array[coarse_grid],
                                     beta, U_array[fine_grid]);            
         }
         
         --level;
         cycle_param = 2;
      }
      else
      {
         Not_Finished = 0;
      }
   }

   hypre_ParAMGDataCycleOpCount(amg_data) = cycle_op_count;

   hypre_TFree(lev_counter);
   hypre_TFree(num_coeffs);
   if (smooth_num_levels > 0)
   {
     if (smooth_type == 7 || smooth_type == 8 || smooth_type == 9 || 
	smooth_type == 17 || smooth_type == 18 || smooth_type == 19 )
        hypre_ParVectorDestroy(Utemp);
   }
   return(Solve_err_flag);
}