Template Numerical Library: TNL::Solvers::IterativeSolverMonitor< Real, Index

Object for monitoring convergence of iterative solvers. More...

#include <TNL/Solvers/IterativeSolverMonitor.h>

Inheritance diagram for TNL::Solvers::IterativeSolverMonitor< Real, Index >:

Collaboration diagram for TNL::Solvers::IterativeSolverMonitor< Real, Index >:

[legend]

Public Types
using	IndexType = Index
	A type for indexing.

using	RealType = Real
	A type of the floating-point arithmetics.

Public Member Functions
	IterativeSolverMonitor ()=default
	Construct with no parameters.

void	refresh () override
	Causes that the monitor prints out the status of the solver. More...

void	setIterations (const IndexType &iterations)
	Set number of the current iteration. More...

void	setNodesPerIteration (const IndexType &nodes)
	Set the number of nodes of the numerical mesh or lattice. More...

void	setResidue (const RealType &residue)
	Set residue of the current approximation of the solution. More...

void	setStage (const std::string &stage)
	This method can be used for naming a stage of the monitored solver. More...

void	setTime (const RealType &time)
	Set the time of the simulated evolution if it is time dependent. More...

void	setTimeStep (const RealType &timeStep)
	Set the time step for time dependent iterative solvers. More...

void	setVerbose (const IndexType &verbose)
	Set up the verbosity of the monitor. More...

Public Member Functions inherited from TNL::Solvers::SolverMonitor
	SolverMonitor ()=default
	Basic construct with no arguments.

bool	isStopped () const
	Checks whether the main loop was stopped. More...

virtual void	refresh ()=0
	This abstract method is responsible for printing or visualizing the status of the solver. More...

void	runMainLoop ()
	Starts the main loop from which the method SolverMonitor::refresh is called in given time periods.

void	setRefreshRate (const int &refreshRate)
	Set the time interval between two consecutive calls of SolverMonitor::refresh. More...

void	setTimer (Timer &timer)
	Set a timer object for the solver monitor. More...

void	stopMainLoop ()
	Stops the main loop of the monitor. See runMainLoop.

Protected Member Functions
int	getLineWidth ()

Protected Member Functions inherited from TNL::Solvers::SolverMonitor
double	getElapsedTime ()

Protected Attributes
std::atomic_bool	attributes_changed { false }

RealType	elapsed_time_before_refresh = 0

IndexType	iterations = 0

IndexType	iterations_before_refresh = 0

RealType	last_mlups = 0

IndexType	nodesPerIteration = 0

RealType	residue = 0

std::atomic_bool	saved { false }

IndexType	saved_iterations = 0

RealType	saved_residue = 0

std::string	saved_stage

RealType	saved_time = 0

RealType	saved_timeStep = 0

std::string	stage

RealType	time = 0

RealType	timeStep = 0

IndexType	verbose = 2

Protected Attributes inherited from TNL::Solvers::SolverMonitor
std::atomic_bool	started { false }

std::atomic_bool	stopped { false }

std::atomic_int	timeout_milliseconds { 500 }

Timer *	timer = nullptr

Detailed Description

template<typename Real = double, typename Index = int>
class TNL::Solvers::IterativeSolverMonitor< Real, Index >

Object for monitoring convergence of iterative solvers.

Template Parameters

Real	is a type of the floating-point arithmetics.
Index	is an indexing type.

The following example shows how to use the iterative solver monitor for monitoring convergence of linear iterative solver:

#include <iostream>
#include <memory>
#include <chrono>
#include <thread>
#include <TNL/Algorithms/ParallelFor.h>
#include <TNL/Matrices/SparseMatrix.h>
#include <TNL/Devices/Sequential.h>
#include <TNL/Devices/Cuda.h>
#include <TNL/Solvers/Linear/Jacobi.h>
 
template< typename Device >
void iterativeLinearSolverExample()
{
   /***
    * Set the following matrix (dots represent zero matrix elements):
    *
    *   /  2.5 -1    .    .    .   \
    *   | -1    2.5 -1    .    .   |
    *   |  .   -1    2.5 -1.   .   |
    *   |  .    .   -1    2.5 -1   |
    *   \  .    .    .   -1    2.5 /
    */
   using MatrixType = TNL::Matrices::SparseMatrix< double, Device >;
   using Vector = TNL::Containers::Vector< double, Device >;
   const int size( 5 );
   auto matrix_ptr = std::make_shared< MatrixType >();
   matrix_ptr->setDimensions( size, size );
   matrix_ptr->setRowCapacities( Vector( { 2, 3, 3, 3, 2 } ) );
 
   auto f = [=] __cuda_callable__ ( typename MatrixType::RowView& row ) mutable {
      const int rowIdx = row.getRowIndex();
      if( rowIdx == 0 )
      {
         row.setElement( 0, rowIdx,    2.5 );    // diagonal element
         row.setElement( 1, rowIdx+1, -1 );      // element above the diagonal
      }
      else if( rowIdx == size - 1 )
      {
         row.setElement( 0, rowIdx-1, -1.0 );    // element below the diagonal
         row.setElement( 1, rowIdx,    2.5 );    // diagonal element
      }
      else
      {
         row.setElement( 0, rowIdx-1, -1.0 );    // element below the diagonal
         row.setElement( 1, rowIdx,    2.5 );    // diagonal element
         row.setElement( 2, rowIdx+1, -1.0 );    // element above the diagonal
      }
   };
 
   /***
    * Set the matrix elements.
    */
   matrix_ptr->forAllRows( f );
   std::cout << *matrix_ptr << std::endl;
 
   /***
    * Set the right-hand side vector.
    */
   Vector x( size, 1.0 );
   Vector b( size );
   matrix_ptr->vectorProduct( x, b );
   x = 0.0;
   std::cout << "Vector b = " << b << std::endl;
 
   /***
    * Setup solver of the linear system.
    */
   using LinearSolver = TNL::Solvers::Linear::Jacobi< MatrixType >;
   LinearSolver solver;
   solver.setMatrix( matrix_ptr );
   solver.setOmega( 0.0005 );
 
   /***
    * Setup monitor of the iterative solver.
    */
   using IterativeSolverMonitorType = TNL::Solvers::IterativeSolverMonitor< double, int >;
   IterativeSolverMonitorType monitor;
   TNL::Solvers::SolverMonitorThread monitorThread(monitor);
   monitor.setRefreshRate(10);  // refresh rate in milliseconds
   monitor.setVerbose(1);
   monitor.setStage( "Jacobi stage:" );
   solver.setSolverMonitor(monitor);
   solver.setConvergenceResidue( 1.0e-6 );
   solver.solve( b, x );
   monitor.stopMainLoop();
   std::cout << "Vector x = " << x << std::endl;
}
 
int main( int argc, char* argv[] )
{
   std::cout << "Solving linear system on host: " << std::endl;
   iterativeLinearSolverExample< TNL::Devices::Sequential >();
 
#ifdef __CUDACC__
   std::cout << "Solving linear system on CUDA device: " << std::endl;
   iterativeLinearSolverExample< TNL::Devices::Cuda >();
#endif
}

The result looks as follows:

Solving linear system on host: 
Row: 0 ->     0:2.5     1:-1  
Row: 1 ->     0:-1      1:2.5     2:-1  
Row: 2 ->     1:-1      2:2.5     3:-1  
Row: 3 ->     2:-1      3:2.5     4:-1  
Row: 4 ->     3:-1      4:2.5 
 
Vector b = [ 1.5, 0.5, 0.5, 0.5, 1.5 ]
 
  Jacobi stage: ITER:   26601 RES:    0.012139
  Jacobi stage: ITER:   51475 RES:  0.00026609
  Jacobi stage: ITER:   75975 RES:  6.1755e-06
Vector x = [ 0.999999, 0.999999, 0.999998, 0.999999, 0.999999 ]
Solving linear system on CUDA device: 
Row: 0 ->     0:2.5     1:-1  
Row: 1 ->     0:-1      1:2.5     2:-1  
Row: 2 ->     1:-1      2:2.5     3:-1  
Row: 3 ->     2:-1      3:2.5     4:-1  
Row: 4 ->     3:-1      4:2.5 
 
Vector b = [ 1.5, 0.5, 0.5, 0.5, 1.5 ]
 
  Jacobi stage: ITER:     723 RES:     0.79705
  Jacobi stage: ITER:    1519 RES:     0.64863
  Jacobi stage: ITER:    2355 RES:     0.54081
  Jacobi stage: ITER:    3359 RES:     0.44734
  Jacobi stage: ITER:    4297 RES:     0.38054
  Jacobi stage: ITER:    5235 RES:     0.32659
  Jacobi stage: ITER:    6023 RES:     0.28814
  Jacobi stage: ITER:    6911 RES:     0.25072
  Jacobi stage: ITER:    7823 RES:     0.21763
  Jacobi stage: ITER:    8731 RES:     0.18915
  Jacobi stage: ITER:    9643 RES:     0.16435
  Jacobi stage: ITER:   10551 RES:     0.14293
  Jacobi stage: ITER:   11463 RES:     0.12423
  Jacobi stage: ITER:   12373 RES:     0.10798
  Jacobi stage: ITER:   13283 RES:    0.093922
  Jacobi stage: ITER:   14193 RES:    0.081644
  Jacobi stage: ITER:   15103 RES:    0.071015
  Jacobi stage: ITER:   16015 RES:    0.061732
  Jacobi stage: ITER:   16927 RES:    0.053662
  Jacobi stage: ITER:   17837 RES:    0.046648
  Jacobi stage: ITER:   18747 RES:    0.040575
  Jacobi stage: ITER:   19657 RES:    0.035271
  Jacobi stage: ITER:   20565 RES:     0.03068
  Jacobi stage: ITER:   21475 RES:    0.026686
  Jacobi stage: ITER:   22385 RES:    0.023197
  Jacobi stage: ITER:   23287 RES:    0.020202
  Jacobi stage: ITER:   24199 RES:    0.017562
  Jacobi stage: ITER:   25109 RES:    0.015266
  Jacobi stage: ITER:   26019 RES:    0.013279
  Jacobi stage: ITER:   26929 RES:    0.011543
  Jacobi stage: ITER:   27839 RES:     0.01004
  Jacobi stage: ITER:   28747 RES:   0.0087332
  Jacobi stage: ITER:   29659 RES:   0.0075917
  Jacobi stage: ITER:   30569 RES:   0.0065993
  Jacobi stage: ITER:   31479 RES:   0.0057402
  Jacobi stage: ITER:   32391 RES:   0.0049899
  Jacobi stage: ITER:   33303 RES:   0.0043376
  Jacobi stage: ITER:   34215 RES:   0.0037706
  Jacobi stage: ITER:   35125 RES:   0.0032778
  Jacobi stage: ITER:   36031 RES:   0.0028528
  Jacobi stage: ITER:   36931 RES:   0.0024845
  Jacobi stage: ITER:   37885 RES:   0.0021452
  Jacobi stage: ITER:   38827 RES:   0.0018568
  Jacobi stage: ITER:   39727 RES:    0.001617
  Jacobi stage: ITER:   40627 RES:   0.0014083
  Jacobi stage: ITER:   41527 RES:   0.0012264
  Jacobi stage: ITER:   42455 RES:   0.0010635
  Jacobi stage: ITER:   43359 RES:  0.00092562
  Jacobi stage: ITER:   44259 RES:  0.00080611
  Jacobi stage: ITER:   45159 RES:  0.00070203
  Jacobi stage: ITER:   46059 RES:  0.00061139
  Jacobi stage: ITER:   46961 RES:  0.00053213
  Jacobi stage: ITER:   47861 RES:  0.00046342
  Jacobi stage: ITER:   48761 RES:  0.00040359
  Jacobi stage: ITER:   49659 RES:   0.0003517
  Jacobi stage: ITER:   50559 RES:  0.00030629
  Jacobi stage: ITER:   51459 RES:  0.00026674
  Jacobi stage: ITER:   52359 RES:   0.0002323
  Jacobi stage: ITER:   53259 RES:  0.00020231
  Jacobi stage: ITER:   54159 RES:  0.00017619
  Jacobi stage: ITER:   55059 RES:  0.00015344
  Jacobi stage: ITER:   55959 RES:  0.00013363
  Jacobi stage: ITER:   56859 RES:  0.00011638
  Jacobi stage: ITER:   57761 RES:  0.00010129
  Jacobi stage: ITER:   58661 RES:  8.8212e-05
  Jacobi stage: ITER:   59559 RES:   7.687e-05
  Jacobi stage: ITER:   60461 RES:  6.6904e-05
  Jacobi stage: ITER:   61361 RES:  5.8266e-05
  Jacobi stage: ITER:   62261 RES:  5.0743e-05
  Jacobi stage: ITER:   63159 RES:  4.4219e-05
  Jacobi stage: ITER:   64083 RES:  3.8368e-05
  Jacobi stage: ITER:   65091 RES:  3.2865e-05
  Jacobi stage: ITER:   66003 RES:  2.8569e-05
  Jacobi stage: ITER:   66903 RES:   2.488e-05
  Jacobi stage: ITER:   67803 RES:  2.1668e-05
  Jacobi stage: ITER:   68703 RES:   1.887e-05
  Jacobi stage: ITER:   69603 RES:  1.6434e-05
  Jacobi stage: ITER:   70501 RES:  1.4312e-05
  Jacobi stage: ITER:   71401 RES:  1.2464e-05
  Jacobi stage: ITER:   72301 RES:  1.0855e-05
  Jacobi stage: ITER:   73201 RES:  9.4534e-06
  Jacobi stage: ITER:   74099 RES:  8.2379e-06
  Jacobi stage: ITER:   74999 RES:  7.1743e-06
  Jacobi stage: ITER:   75877 RES:  6.2673e-06
  Jacobi stage: ITER:   76775 RES:  5.4614e-06
  Jacobi stage: ITER:   77675 RES:  4.7563e-06
  Jacobi stage: ITER:   78575 RES:  4.1422e-06
  Jacobi stage: ITER:   79475 RES:  3.6074e-06
  Jacobi stage: ITER:   80375 RES:  3.1416e-06
  Jacobi stage: ITER:   81275 RES:   2.736e-06
  Jacobi stage: ITER:   82175 RES:  2.3828e-06
  Jacobi stage: ITER:   83075 RES:  2.0751e-06
  Jacobi stage: ITER:   83975 RES:  1.8072e-06
  Jacobi stage: ITER:   84875 RES:  1.5739e-06
  Jacobi stage: ITER:   85771 RES:  1.3715e-06
  Jacobi stage: ITER:   86671 RES:  1.1944e-06
  Jacobi stage: ITER:   87569 RES:  1.0402e-06
Vector x = [ 0.999999, 0.999999, 0.999998, 0.999999, 0.999999 ]

The following example shows how to employ timer (TNL::Timer) to the monitor of iterative solvers:

#include <iostream>
#include <memory>
#include <chrono>
#include <thread>
#include <TNL/Timer.h>
#include <TNL/Algorithms/ParallelFor.h>
#include <TNL/Matrices/SparseMatrix.h>
#include <TNL/Devices/Sequential.h>
#include <TNL/Devices/Cuda.h>
#include <TNL/Solvers/Linear/Jacobi.h>
 
template< typename Device >
void iterativeLinearSolverExample()
{
   /***
    * Set the following matrix (dots represent zero matrix elements):
    *
    *   /  2.5 -1    .    .    .   \
    *   | -1    2.5 -1    .    .   |
    *   |  .   -1    2.5 -1.   .   |
    *   |  .    .   -1    2.5 -1   |
    *   \  .    .    .   -1    2.5 /
    */
   using MatrixType = TNL::Matrices::SparseMatrix< double, Device >;
   using Vector = TNL::Containers::Vector< double, Device >;
   const int size( 5 );
   auto matrix_ptr = std::make_shared< MatrixType >();
   matrix_ptr->setDimensions( size, size );
   matrix_ptr->setRowCapacities( Vector( { 2, 3, 3, 3, 2 } ) );
 
   auto f = [=] __cuda_callable__ ( typename MatrixType::RowView& row ) mutable {
      const int rowIdx = row.getRowIndex();
      if( rowIdx == 0 )
      {
         row.setElement( 0, rowIdx,    2.5 );    // diagonal element
         row.setElement( 1, rowIdx+1, -1 );      // element above the diagonal
      }
      else if( rowIdx == size - 1 )
      {
         row.setElement( 0, rowIdx-1, -1.0 );    // element below the diagonal
         row.setElement( 1, rowIdx,    2.5 );    // diagonal element
      }
      else
      {
         row.setElement( 0, rowIdx-1, -1.0 );    // element below the diagonal
         row.setElement( 1, rowIdx,    2.5 );    // diagonal element
         row.setElement( 2, rowIdx+1, -1.0 );    // element above the diagonal
      }
   };
 
   /***
    * Set the matrix elements.
    */
   matrix_ptr->forAllRows( f );
   std::cout << *matrix_ptr << std::endl;
 
   /***
    * Set the right-hand side vector.
    */
   Vector x( size, 1.0 );
   Vector b( size );
   matrix_ptr->vectorProduct( x, b );
   x = 0.0;
   std::cout << "Vector b = " << b << std::endl;
 
   /***
    * Setup solver of the linear system.
    */
   using LinearSolver = TNL::Solvers::Linear::Jacobi< MatrixType >;
   LinearSolver solver;
   solver.setMatrix( matrix_ptr );
   solver.setOmega( 0.0005 );
 
   /***
    * Setup monitor of the iterative solver.
    */
   using IterativeSolverMonitorType = TNL::Solvers::IterativeSolverMonitor< double, int >;
   IterativeSolverMonitorType monitor;
   TNL::Solvers::SolverMonitorThread mmonitorThread(monitor);
   monitor.setRefreshRate(10);  // refresh rate in milliseconds
   monitor.setVerbose(1);
   monitor.setStage( "Jacobi stage:" );
   TNL::Timer timer;
   monitor.setTimer( timer );
   timer.start();
   solver.setSolverMonitor(monitor);
   solver.setConvergenceResidue( 1.0e-6 );
   solver.solve( b, x );
   monitor.stopMainLoop();
   std::cout << "Vector x = " << x << std::endl;
}
 
int main( int argc, char* argv[] )
{
   std::cout << "Solving linear system on host: " << std::endl;
   iterativeLinearSolverExample< TNL::Devices::Sequential >();
 
#ifdef __CUDACC__
   std::cout << "Solving linear system on CUDA device: " << std::endl;
   iterativeLinearSolverExample< TNL::Devices::Cuda >();
#endif
}

The result looks as follows:

Solving linear system on host: 
Row: 0 ->     0:2.5     1:-1  
Row: 1 ->     0:-1      1:2.5     2:-1  
Row: 2 ->     1:-1      2:2.5     3:-1  
Row: 3 ->     2:-1      3:2.5     4:-1  
Row: 4 ->     3:-1      4:2.5 
 
Vector b = [ 1.5, 0.5, 0.5, 0.5, 1.5 ]
 ELA:3.09e-06
 ELA:  0.1001  Jacobi stage: ITER:   23897 RES:     0.01839
 ELA: 0.20023  Jacobi stage: ITER:   47571 RES:  0.00048468
 ELA: 0.30034  Jacobi stage: ITER:   71167 RES:  1.2924e-05
Vector x = [ 0.999999, 0.999999, 0.999998, 0.999999, 0.999999 ]
Solving linear system on CUDA device: 
Row: 0 ->     0:2.5     1:-1  
Row: 1 ->     0:-1      1:2.5     2:-1  
Row: 2 ->     1:-1      2:2.5     3:-1  
Row: 3 ->     2:-1      3:2.5     4:-1  
Row: 4 ->     3:-1      4:2.5 
 
Vector b = [ 1.5, 0.5, 0.5, 0.5, 1.5 ]
 ELA:1.273e-0
 ELA: 0.10035  Jacobi stage: ITER:     727 RES:     0.79614
 ELA: 0.20049  Jacobi stage: ITER:    1533 RES:      0.6462
 ELA: 0.30061  Jacobi stage: ITER:    2371 RES:     0.53907
 ELA:  0.4081  Jacobi stage: ITER:    3299 RES:     0.45217
 ELA: 0.50826  Jacobi stage: ITER:    4197 RES:     0.38696
 ELA: 0.61164  Jacobi stage: ITER:    5117 RES:     0.33274
 ELA: 0.71178  Jacobi stage: ITER:    5899 RES:     0.29383
 ELA: 0.81191  Jacobi stage: ITER:    6795 RES:      0.2553
 ELA: 0.91204  Jacobi stage: ITER:    7707 RES:     0.22157
 ELA:  1.0122  Jacobi stage: ITER:    8623 RES:     0.19232
 ELA:  1.1123  Jacobi stage: ITER:    9533 RES:     0.16711
 ELA:  1.2124  Jacobi stage: ITER:   10443 RES:     0.14532
 ELA:  1.3126  Jacobi stage: ITER:   11355 RES:     0.12631
 ELA:  1.4128  Jacobi stage: ITER:   12265 RES:     0.10979
 ELA:  1.5129  Jacobi stage: ITER:   13175 RES:    0.095494
 ELA:   1.613  Jacobi stage: ITER:   14085 RES:     0.08301
 ELA:  1.7131  Jacobi stage: ITER:   14995 RES:    0.072203
 ELA:  1.8133  Jacobi stage: ITER:   15907 RES:    0.062764
 ELA:  1.9134  Jacobi stage: ITER:   16819 RES:     0.05456
 ELA:  2.0135  Jacobi stage: ITER:   17727 RES:    0.047457
 ELA:  2.1136  Jacobi stage: ITER:   18639 RES:    0.041254
 ELA:  2.2138  Jacobi stage: ITER:   19555 RES:    0.035839
 ELA:  2.3139  Jacobi stage: ITER:   20479 RES:    0.031097
 ELA:   2.414  Jacobi stage: ITER:   21389 RES:    0.027032
 ELA:  2.5141  Jacobi stage: ITER:   22299 RES:    0.023513
 ELA:  2.6143  Jacobi stage: ITER:   23223 RES:    0.020402
 ELA:  2.7144  Jacobi stage: ITER:   24135 RES:    0.017735
 ELA:  2.8146  Jacobi stage: ITER:   25043 RES:    0.015426
 ELA:  2.9147  Jacobi stage: ITER:   25955 RES:     0.01341
 ELA:  3.0148  Jacobi stage: ITER:   26863 RES:    0.011664
 ELA:  3.1149  Jacobi stage: ITER:   27773 RES:    0.010139
 ELA:   3.215  Jacobi stage: ITER:   28683 RES:   0.0088195
 ELA:  3.3152  Jacobi stage: ITER:   29593 RES:   0.0076667
 ELA:  3.4153  Jacobi stage: ITER:   30503 RES:   0.0066686
 ELA:  3.5154  Jacobi stage: ITER:   31415 RES:   0.0057969
 ELA:  3.6155  Jacobi stage: ITER:   32327 RES:   0.0050392
 ELA:  3.7156  Jacobi stage: ITER:   33239 RES:   0.0043805
 ELA:  3.8157  Jacobi stage: ITER:   34151 RES:   0.0038079
 ELA:  3.9159  Jacobi stage: ITER:   35061 RES:   0.0033101
 ELA:   4.016  Jacobi stage: ITER:   35967 RES:    0.002881
 ELA:  4.1161  Jacobi stage: ITER:   36867 RES:    0.002509
 ELA:  4.2162  Jacobi stage: ITER:   37749 RES:   0.0021904
 ELA:  4.3163  Jacobi stage: ITER:   38643 RES:     0.00191
 ELA:  4.4164  Jacobi stage: ITER:   39543 RES:   0.0016634
 ELA:  4.5166  Jacobi stage: ITER:   40443 RES:   0.0014486
 ELA:  4.6167  Jacobi stage: ITER:   41343 RES:   0.0012616
 ELA:  4.7168  Jacobi stage: ITER:   42235 RES:   0.0011001
 ELA:  4.8169  Jacobi stage: ITER:   43135 RES:  0.00095802
 ELA:   4.917  Jacobi stage: ITER:   44035 RES:  0.00083433
 ELA:  5.0171  Jacobi stage: ITER:   44937 RES:  0.00072616
 ELA:  5.1172  Jacobi stage: ITER:   45837 RES:  0.00063241
 ELA:  5.2173  Jacobi stage: ITER:   46739 RES:  0.00055076
 ELA:  5.3175  Jacobi stage: ITER:   47639 RES:  0.00047965
 ELA:  5.4176  Jacobi stage: ITER:   48539 RES:  0.00041772
 ELA:  5.5177  Jacobi stage: ITER:   49439 RES:  0.00036379
 ELA:  5.6178  Jacobi stage: ITER:   50339 RES:  0.00031682
 ELA:  5.7179  Jacobi stage: ITER:   51239 RES:  0.00027591
 ELA:   5.818  Jacobi stage: ITER:   52139 RES:  0.00024029
 ELA:  5.9182  Jacobi stage: ITER:   53039 RES:  0.00020926
 ELA:  6.0183  Jacobi stage: ITER:   53941 RES:  0.00018213
 ELA:  6.1184  Jacobi stage: ITER:   54843 RES:  0.00015862
 ELA:  6.2185  Jacobi stage: ITER:   55743 RES:  0.00013814
 ELA:  6.3186  Jacobi stage: ITER:   56643 RES:   0.0001203
 ELA:  6.4187  Jacobi stage: ITER:   57543 RES:  0.00010477
 ELA:  6.5188  Jacobi stage: ITER:   58443 RES:  9.1244e-05
 ELA:   6.619  Jacobi stage: ITER:   59343 RES:  7.9463e-05
 ELA:  6.7191  Jacobi stage: ITER:   60245 RES:  6.9161e-05
 ELA:  6.8192  Jacobi stage: ITER:   61145 RES:  6.0232e-05
 ELA:  6.9193  Jacobi stage: ITER:   62045 RES:  5.2455e-05
 ELA:  7.0194  Jacobi stage: ITER:   62945 RES:  4.5682e-05
 ELA:  7.1195  Jacobi stage: ITER:   63835 RES:  3.9858e-05
 ELA:  7.2197  Jacobi stage: ITER:   64699 RES:  3.4904e-05
 ELA:  7.3198  Jacobi stage: ITER:   65595 RES:  3.0416e-05
 ELA:  9.2586  Jacobi stage: ITER:   66493 RES:  2.6489e-05
 ELA:  9.3587  Jacobi stage: ITER:   67393 RES:  2.3069e-05
 ELA:  9.4588  Jacobi stage: ITER:   68293 RES:  2.0091e-05
 ELA:  9.5589  Jacobi stage: ITER:   69193 RES:  1.7497e-05
 ELA:   9.659  Jacobi stage: ITER:   70091 RES:  1.5247e-05
 ELA:  9.7591  Jacobi stage: ITER:   70991 RES:  1.3278e-05
 ELA:  9.8592  Jacobi stage: ITER:   71891 RES:  1.1564e-05
 ELA:  9.9593  Jacobi stage: ITER:   72791 RES:  1.0071e-05
 ELA:  10.059  Jacobi stage: ITER:   73691 RES:  8.7707e-06
 ELA:   10.16  Jacobi stage: ITER:   74591 RES:  7.6383e-06
 ELA:   10.26  Jacobi stage: ITER:   75463 RES:  6.6808e-06
 ELA:   10.36  Jacobi stage: ITER:   76361 RES:  5.8182e-06
 ELA:   10.46  Jacobi stage: ITER:   77261 RES:   5.067e-06
 ELA:   10.56  Jacobi stage: ITER:   78161 RES:  4.4128e-06
 ELA:   10.66  Jacobi stage: ITER:   79059 RES:  3.8454e-06
 ELA:   10.76  Jacobi stage: ITER:   79959 RES:  3.3489e-06
 ELA:   10.86  Jacobi stage: ITER:   80859 RES:  2.9166e-06
 ELA:   10.96  Jacobi stage: ITER:   81759 RES:    2.54e-06
 ELA:   11.06  Jacobi stage: ITER:   82659 RES:  2.2121e-06
 ELA:  11.161  Jacobi stage: ITER:   83559 RES:  1.9264e-06
 ELA:  11.261  Jacobi stage: ITER:   84459 RES:  1.6777e-06
 ELA:  11.361  Jacobi stage: ITER:   85359 RES:  1.4611e-06
 ELA:  11.461  Jacobi stage: ITER:   86259 RES:  1.2725e-06
 ELA:  11.561  Jacobi stage: ITER:   87159 RES:  1.1082e-06
Vector x = [ 0.999999, 0.999999, 0.999998, 0.999999, 0.999999 ]

Member Function Documentation

◆ refresh()

template<typename Real , typename Index >

void TNL::Solvers::IterativeSolverMonitor< Real, Index >::refresh

overridevirtual

Causes that the monitor prints out the status of the solver.

Implements TNL::Solvers::SolverMonitor.

◆ setIterations()

template<typename Real , typename Index >

void TNL::Solvers::IterativeSolverMonitor< Real, Index >::setIterations ( const IndexType & iterations )

Set number of the current iteration.

Parameters

iterations is number of the current iteration.

◆ setNodesPerIteration()

template<typename Real , typename Index >

void TNL::Solvers::IterativeSolverMonitor< Real, Index >::setNodesPerIteration ( const IndexType & nodes )

Set the number of nodes of the numerical mesh or lattice.

This can be used to compute the number of nodes processed per one second.

Parameters

nodes is number of nodes of the numerical mesh or lattice.

◆ setResidue()

template<typename Real = double, typename Index = int>

void TNL::Solvers::IterativeSolverMonitor< Real, Index >::setResidue ( const RealType & residue )

Set residue of the current approximation of the solution.

Parameters

residue is a residue of the current approximation of the solution.

◆ setStage()

template<typename Real , typename Index >

void TNL::Solvers::IterativeSolverMonitor< Real, Index >::setStage ( const std::string & stage )

This method can be used for naming a stage of the monitored solver.

The stage name can be used to differ between various stages of iterative solvers.

Parameters

stage is name of the solver stage.

◆ setTime()

template<typename Real , typename Index >

void TNL::Solvers::IterativeSolverMonitor< Real, Index >::setTime ( const RealType & time )

Set the time of the simulated evolution if it is time dependent.

This can be used for example when solving parabolic or hyperbolic PDEs.

Parameters

time	time of the simulated evolution.

◆ setTimeStep()

template<typename Real , typename Index >

void TNL::Solvers::IterativeSolverMonitor< Real, Index >::setTimeStep ( const RealType & timeStep )

Set the time step for time dependent iterative solvers.

Parameters

timeStep time step of the time dependent iterative solver.

◆ setVerbose()

template<typename Real , typename Index >

void TNL::Solvers::IterativeSolverMonitor< Real, Index >::setVerbose ( const IndexType & verbose )

Set up the verbosity of the monitor.

Parameters

verbose is the new value of the verbosity of the monitor.

The documentation for this class was generated from the following files:

src/TNL/Solvers/IterativeSolverMonitor.h
src/TNL/Solvers/IterativeSolverMonitor.hpp

Public Types

Public Member Functions

Protected Member Functions

Protected Attributes

Detailed Description

Member Function Documentation

◆ refresh()

◆ setIterations()

◆ setNodesPerIteration()

◆ setResidue()

◆ setStage()

◆ setTime()

◆ setTimeStep()

◆ setVerbose()