TNL::Solvers::IterativeSolverMonitor< Real, Index > Class Template Reference

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 >:

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.
void	setIterations (const IndexType &iterations)
	Set number of the current iteration.
void	setNodesPerIteration (const IndexType &nodes)
	Set the number of nodes of the numerical mesh or lattice.
void	setResidue (const RealType &residue)
	Set residue of the current approximation of the solution.
void	setStage (const std::string &stage)
	This method can be used for naming a stage of the monitored solver.
void	setTime (const RealType &time)
	Set the time of the simulated evolution if it is time dependent.
void	setTimeStep (const RealType &timeStep)
	Set the time step for time dependent iterative solvers.
void	setVerbose (const IndexType &verbose)
	Set up the verbosity of the monitor.
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.
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.
void	setTimer (Timer &timer)
	Set a timer object for the solver monitor.
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/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:   16779 RES:    0.054896
  Jacobi stage: ITER:   34955 RES:   0.0033634
  Jacobi stage: ITER:   52197 RES:  0.00023808
  Jacobi stage: ITER:   69553 RES:  1.6555e-05
  Jacobi stage: ITER:   86681 RES:  1.1922e-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:    5793 RES:      0.2987
  Jacobi stage: ITER:   10651 RES:     0.14074
  Jacobi stage: ITER:   15567 RES:    0.066129
  Jacobi stage: ITER:   20319 RES:    0.031871
  Jacobi stage: ITER:   23377 RES:    0.019919
  Jacobi stage: ITER:   23835 RES:    0.018571
  Jacobi stage: ITER:   24307 RES:    0.017273
  Jacobi stage: ITER:   24801 RES:    0.016006
  Jacobi stage: ITER:   25315 RES:    0.014795
  Jacobi stage: ITER:   25809 RES:     0.01371
  Jacobi stage: ITER:   26303 RES:    0.012712
  Jacobi stage: ITER:   26797 RES:    0.011779
  Jacobi stage: ITER:   27291 RES:    0.010922
  Jacobi stage: ITER:   27807 RES:     0.01009
  Jacobi stage: ITER:   28311 RES:   0.0093381
  Jacobi stage: ITER:   28823 RES:   0.0086319
  Jacobi stage: ITER:   29339 RES:   0.0079741
  Jacobi stage: ITER:   29853 RES:   0.0073665
  Jacobi stage: ITER:   30405 RES:   0.0067677
  Jacobi stage: ITER:   30917 RES:   0.0062558
  Jacobi stage: ITER:   31427 RES:   0.0057862
  Jacobi stage: ITER:   31935 RES:   0.0053519
  Jacobi stage: ITER:   32451 RES:   0.0049441
  Jacobi stage: ITER:   32947 RES:   0.0045814
  Jacobi stage: ITER:   33443 RES:   0.0042453
  Jacobi stage: ITER:   33937 RES:   0.0039339
  Jacobi stage: ITER:   34431 RES:   0.0036476
  Jacobi stage: ITER:   34931 RES:   0.0033779
  Jacobi stage: ITER:   35425 RES:   0.0031301
  Jacobi stage: ITER:   35919 RES:   0.0029023
  Jacobi stage: ITER:   36413 RES:   0.0026894
  Jacobi stage: ITER:   36907 RES:   0.0024936
  Jacobi stage: ITER:   37415 RES:   0.0023065
  Jacobi stage: ITER:   37909 RES:   0.0021373
  Jacobi stage: ITER:   38403 RES:   0.0019817
  Jacobi stage: ITER:   38897 RES:   0.0018363
  Jacobi stage: ITER:   39391 RES:   0.0017027
  Jacobi stage: ITER:   39903 RES:   0.0015739
  Jacobi stage: ITER:   40397 RES:   0.0014584
  Jacobi stage: ITER:   40895 RES:   0.0013515
  Jacobi stage: ITER:   41391 RES:   0.0012523
  Jacobi stage: ITER:   41883 RES:   0.0011612
  Jacobi stage: ITER:   42399 RES:   0.0010727
  Jacobi stage: ITER:   42893 RES:    0.000994
  Jacobi stage: ITER:   43387 RES:  0.00092165
  Jacobi stage: ITER:   43883 RES:  0.00085404
  Jacobi stage: ITER:   44375 RES:  0.00079188
  Jacobi stage: ITER:   44891 RES:  0.00073154
  Jacobi stage: ITER:   45383 RES:  0.00067829
  Jacobi stage: ITER:   45879 RES:  0.00062853
  Jacobi stage: ITER:   46371 RES:  0.00058278
  Jacobi stage: ITER:   46867 RES:  0.00054003
  Jacobi stage: ITER:   47379 RES:  0.00049919
  Jacobi stage: ITER:   47871 RES:  0.00046285
  Jacobi stage: ITER:   48369 RES:  0.00042864
  Jacobi stage: ITER:   48863 RES:  0.00039744
  Jacobi stage: ITER:   49355 RES:  0.00036851
  Jacobi stage: ITER:   49879 RES:  0.00033897
  Jacobi stage: ITER:   50407 RES:  0.00031353
  Jacobi stage: ITER:   51211 RES:   0.0002771
  Jacobi stage: ITER:   51705 RES:  0.00025677
  Jacobi stage: ITER:   52199 RES:  0.00023808
  Jacobi stage: ITER:   52695 RES:  0.00022062
  Jacobi stage: ITER:   53187 RES:  0.00020456
  Jacobi stage: ITER:   53681 RES:  0.00018956
  Jacobi stage: ITER:   54175 RES:  0.00017576
  Jacobi stage: ITER:   54671 RES:  0.00016287
  Jacobi stage: ITER:   55163 RES:  0.00015101
  Jacobi stage: ITER:   55657 RES:  0.00013993
  Jacobi stage: ITER:   56151 RES:  0.00012975
  Jacobi stage: ITER:   56647 RES:  0.00012023
  Jacobi stage: ITER:   57141 RES:  0.00011141
  Jacobi stage: ITER:   57635 RES:   0.0001033
  Jacobi stage: ITER:   58127 RES:  9.5782e-05
  Jacobi stage: ITER:   58621 RES:  8.8756e-05
  Jacobi stage: ITER:   59115 RES:  8.2296e-05
  Jacobi stage: ITER:   59579 RES:  7.6634e-05
  Jacobi stage: ITER:   60073 RES:  7.1013e-05
  Jacobi stage: ITER:   60567 RES:  6.5844e-05
  Jacobi stage: ITER:   61053 RES:  6.1089e-05
  Jacobi stage: ITER:   61547 RES:  5.6642e-05
  Jacobi stage: ITER:   62041 RES:  5.2487e-05
  Jacobi stage: ITER:   62535 RES:  4.8667e-05
  Jacobi stage: ITER:   63029 RES:  4.5097e-05
  Jacobi stage: ITER:   63523 RES:  4.1814e-05
  Jacobi stage: ITER:   64021 RES:  3.8723e-05
  Jacobi stage: ITER:   64515 RES:  3.5905e-05
  Jacobi stage: ITER:   65007 RES:  3.3291e-05
  Jacobi stage: ITER:   65503 RES:  3.0849e-05
  Jacobi stage: ITER:   65997 RES:  2.8586e-05
  Jacobi stage: ITER:   66489 RES:  2.6505e-05
  Jacobi stage: ITER:   66983 RES:  2.4576e-05
  Jacobi stage: ITER:   67477 RES:  2.2773e-05
  Jacobi stage: ITER:   67977 RES:   2.109e-05
  Jacobi stage: ITER:   68471 RES:  1.9555e-05
  Jacobi stage: ITER:   68967 RES:   1.812e-05
  Jacobi stage: ITER:   69459 RES:  1.6801e-05
  Jacobi stage: ITER:   69951 RES:  1.5578e-05
  Jacobi stage: ITER:   70445 RES:  1.4436e-05
  Jacobi stage: ITER:   70939 RES:  1.3385e-05
  Jacobi stage: ITER:   71433 RES:  1.2403e-05
  Jacobi stage: ITER:   71927 RES:    1.15e-05
  Jacobi stage: ITER:   72419 RES:  1.0663e-05
  Jacobi stage: ITER:   72911 RES:  9.8871e-06
  Jacobi stage: ITER:   73347 RES:  9.2466e-06
  Jacobi stage: ITER:   73843 RES:  8.5683e-06
  Jacobi stage: ITER:   74353 RES:  7.9203e-06
  Jacobi stage: ITER:   74859 RES:  7.3303e-06
  Jacobi stage: ITER:   75347 RES:  6.8009e-06
  Jacobi stage: ITER:   75831 RES:  6.3136e-06
  Jacobi stage: ITER:   76301 RES:  5.8721e-06
  Jacobi stage: ITER:   76779 RES:  5.4581e-06
  Jacobi stage: ITER:   77249 RES:  5.0764e-06
  Jacobi stage: ITER:   77723 RES:  4.7214e-06
  Jacobi stage: ITER:   78201 RES:  4.3858e-06
  Jacobi stage: ITER:   78681 RES:  4.0741e-06
  Jacobi stage: ITER:   79153 RES:  3.7891e-06
  Jacobi stage: ITER:   79625 RES:  3.5242e-06
  Jacobi stage: ITER:   80069 RES:  3.2918e-06
  Jacobi stage: ITER:   80573 RES:  3.0466e-06
  Jacobi stage: ITER:   81075 RES:  2.8214e-06
  Jacobi stage: ITER:   81967 RES:  2.4601e-06
  Jacobi stage: ITER:   82503 RES:  2.2657e-06
  Jacobi stage: ITER:   83047 RES:  2.0841e-06
  Jacobi stage: ITER:   83559 RES:  1.9264e-06
  Jacobi stage: ITER:   84069 RES:  1.7807e-06
  Jacobi stage: ITER:   84581 RES:  1.6461e-06
  Jacobi stage: ITER:   85673 RES:  1.3919e-06
  Jacobi stage: ITER:   86185 RES:  1.2866e-06
  Jacobi stage: ITER:   86699 RES:  1.1893e-06
  Jacobi stage: ITER:   87213 RES:  1.0987e-06
  Jacobi stage: ITER:   87725 RES:  1.0156e-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/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:0.007991
 ELA: 0.10813  Jacobi stage: ITER:   20333 RES:    0.031793
 ELA: 0.20825  Jacobi stage: ITER:   38959 RES:   0.0018195
 ELA: 0.30837  Jacobi stage: ITER:   59781 RES:   7.427e-05
 ELA:  0.4085  Jacobi stage: ITER:   79415 RES:  3.6408e-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 ]
 ELA:0.012548
 ELA: 0.11266  Jacobi stage: ITER:     511 RES:      0.8482
 ELA: 0.21278  Jacobi stage: ITER:     973 RES:     0.74346
 ELA: 0.31289  Jacobi stage: ITER:    1471 RES:     0.65605
 ELA: 0.41301  Jacobi stage: ITER:    1971 RES:     0.58588
 ELA: 0.51313  Jacobi stage: ITER:    2465 RES:     0.52882
 ELA: 0.61325  Jacobi stage: ITER:    2963 RES:     0.48079
 ELA: 0.71336  Jacobi stage: ITER:    3455 RES:     0.43977
 ELA: 0.81348  Jacobi stage: ITER:    3951 RES:     0.40352
 ELA:  0.9136  Jacobi stage: ITER:    4441 RES:     0.37154
 ELA:  1.0137  Jacobi stage: ITER:    4935 RES:     0.34278
 ELA:  1.1139  Jacobi stage: ITER:    5429 RES:      0.3165
 ELA:  1.2141  Jacobi stage: ITER:    5923 RES:     0.29272
 ELA:  1.3142  Jacobi stage: ITER:    6417 RES:     0.27075
 ELA:  1.4143  Jacobi stage: ITER:    6909 RES:     0.25072
 ELA:  1.5144  Jacobi stage: ITER:    7403 RES:     0.23226
 ELA:  1.6146  Jacobi stage: ITER:    7895 RES:     0.21522
 ELA:  1.7147  Jacobi stage: ITER:    8391 RES:     0.19933
 ELA:  1.8148  Jacobi stage: ITER:    8885 RES:     0.18465
 ELA:  1.9149  Jacobi stage: ITER:    9375 RES:     0.17128
 ELA:   2.015  Jacobi stage: ITER:    9871 RES:     0.15869
 ELA:  2.1152  Jacobi stage: ITER:   10365 RES:     0.14703
 ELA:  2.2153  Jacobi stage: ITER:   10859 RES:     0.13631
 ELA:  2.3154  Jacobi stage: ITER:   11351 RES:     0.12639
 ELA:  2.4155  Jacobi stage: ITER:   11847 RES:     0.11711
 ELA:  2.5156  Jacobi stage: ITER:   12339 RES:     0.10858
 ELA:  2.6158  Jacobi stage: ITER:   12835 RES:     0.10061
 ELA:  2.7159  Jacobi stage: ITER:   13327 RES:     0.09329
 ELA:   2.816  Jacobi stage: ITER:   13821 RES:    0.086445
 ELA:  2.9161  Jacobi stage: ITER:   14313 RES:    0.080153
 ELA:  3.0162  Jacobi stage: ITER:   14807 RES:    0.074318
 ELA:  3.1163  Jacobi stage: ITER:   15301 RES:    0.068866
 ELA:  3.2164  Jacobi stage: ITER:   15795 RES:    0.063853
 ELA:  3.3165  Jacobi stage: ITER:   16287 RES:    0.059206
 ELA:  3.4167  Jacobi stage: ITER:   16779 RES:    0.054896
 ELA:  3.5168  Jacobi stage: ITER:   17271 RES:      0.0509
 ELA:  3.6169  Jacobi stage: ITER:   17765 RES:    0.047166
 ELA:   3.717  Jacobi stage: ITER:   18259 RES:    0.043733
 ELA:  3.8171  Jacobi stage: ITER:   18751 RES:     0.04055
 ELA:  3.9173  Jacobi stage: ITER:   19243 RES:    0.037599
 ELA:  4.0174  Jacobi stage: ITER:   19737 RES:     0.03484
 ELA:  4.1175  Jacobi stage: ITER:   20231 RES:    0.032305
 ELA:  4.2176  Jacobi stage: ITER:   20723 RES:    0.029953
 ELA:  4.3177  Jacobi stage: ITER:   21217 RES:    0.027756
 ELA:  4.4178  Jacobi stage: ITER:   21711 RES:    0.025736
 ELA:   4.518  Jacobi stage: ITER:   22203 RES:    0.023862
 ELA:  4.6181  Jacobi stage: ITER:   22699 RES:    0.022112
 ELA:  4.7182  Jacobi stage: ITER:   23193 RES:     0.02049
 ELA:  4.8183  Jacobi stage: ITER:   23687 RES:    0.018999
 ELA:  4.9184  Jacobi stage: ITER:   24179 RES:    0.017616
 ELA:  5.0185  Jacobi stage: ITER:   24671 RES:    0.016333
 ELA:  5.1186  Jacobi stage: ITER:   25165 RES:    0.015135
 ELA:  5.2188  Jacobi stage: ITER:   25659 RES:    0.014034
 ELA:  5.3189  Jacobi stage: ITER:   26153 RES:    0.013004
 ELA:   5.419  Jacobi stage: ITER:   26645 RES:    0.012058
 ELA:  5.5385  Jacobi stage: ITER:   27411 RES:    0.010723
 ELA:  5.6394  Jacobi stage: ITER:   28031 RES:   0.0097485
 ELA:  5.7395  Jacobi stage: ITER:   28527 RES:   0.0090334
 ELA:  5.8396  Jacobi stage: ITER:   29019 RES:   0.0083759
 ELA:  5.9397  Jacobi stage: ITER:   29513 RES:   0.0077615
 ELA:  6.0398  Jacobi stage: ITER:   30007 RES:   0.0071965
 ELA:  6.1399  Jacobi stage: ITER:   30499 RES:   0.0066727
 ELA:  6.2401  Jacobi stage: ITER:   30995 RES:   0.0061832
 ELA:  6.3402  Jacobi stage: ITER:   31487 RES:   0.0057332
 ELA:  6.4403  Jacobi stage: ITER:   31981 RES:   0.0053126
 ELA:  6.5404  Jacobi stage: ITER:   32475 RES:   0.0049259
 ELA:  6.6405  Jacobi stage: ITER:   32967 RES:   0.0045674
 ELA:  6.7406  Jacobi stage: ITER:   33461 RES:   0.0042323
 ELA:  6.8408  Jacobi stage: ITER:   33955 RES:   0.0039243
 ELA:  6.9409  Jacobi stage: ITER:   34451 RES:   0.0036364
 ELA:   7.041  Jacobi stage: ITER:   34945 RES:   0.0033696
 ELA:  7.1411  Jacobi stage: ITER:   35441 RES:   0.0031225
 ELA:  7.2412  Jacobi stage: ITER:   35939 RES:   0.0028934
 ELA:  7.3414  Jacobi stage: ITER:   36685 RES:   0.0025794
 ELA:  7.4415  Jacobi stage: ITER:   37179 RES:   0.0023916
 ELA:  7.5416  Jacobi stage: ITER:   37725 RES:   0.0021985
 ELA:  7.6417  Jacobi stage: ITER:   38219 RES:   0.0020385
 ELA:  7.7418  Jacobi stage: ITER:   38715 RES:    0.001889
 ELA:  7.8419  Jacobi stage: ITER:   39207 RES:   0.0017515
 ELA:  7.9421  Jacobi stage: ITER:   39701 RES:    0.001623
 ELA:  8.0422  Jacobi stage: ITER:   40195 RES:   0.0015049
 ELA:  8.1423  Jacobi stage: ITER:   40693 RES:   0.0013936
 ELA:  8.2424  Jacobi stage: ITER:   41189 RES:   0.0012914
 ELA:  8.3425  Jacobi stage: ITER:   41683 RES:   0.0011974
 ELA:  8.4427  Jacobi stage: ITER:   42175 RES:   0.0011102
 ELA:  8.5428  Jacobi stage: ITER:   42671 RES:   0.0010288
 ELA:  8.6429  Jacobi stage: ITER:   43171 RES:  0.00095274
 ELA:   8.743  Jacobi stage: ITER:   43663 RES:  0.00088339
 ELA:  8.8431  Jacobi stage: ITER:   44157 RES:  0.00081859
 ELA:  8.9432  Jacobi stage: ITER:   44651 RES:  0.00075901
 ELA:  9.0434  Jacobi stage: ITER:   45143 RES:  0.00070376
 ELA:  9.1435  Jacobi stage: ITER:   45639 RES:  0.00065214
 ELA:  9.2436  Jacobi stage: ITER:   46135 RES:   0.0006043
 ELA:  9.3437  Jacobi stage: ITER:   46633 RES:  0.00055962
 ELA:  9.4438  Jacobi stage: ITER:   47127 RES:  0.00051889
 ELA:  9.5439  Jacobi stage: ITER:   47621 RES:  0.00048083
 ELA:   9.644  Jacobi stage: ITER:   48117 RES:  0.00044555
 ELA:  9.7442  Jacobi stage: ITER:   48615 RES:  0.00041287
 ELA:  9.8443  Jacobi stage: ITER:   49107 RES:  0.00038282
 ELA:  9.9444  Jacobi stage: ITER:   49607 RES:  0.00035452
 ELA:  10.044  Jacobi stage: ITER:   50959 RES:  0.00028804
 ELA:  10.146  Jacobi stage: ITER:   51519 RES:   0.0002643
 ELA:  10.249  Jacobi stage: ITER:   52039 RES:  0.00024401
 ELA:  10.356  Jacobi stage: ITER:   52591 RES:  0.00022417
 ELA:  10.456  Jacobi stage: ITER:   53091 RES:   0.0002076
 ELA:  10.556  Jacobi stage: ITER:   53565 RES:  0.00019296
 ELA:  10.656  Jacobi stage: ITER:   54035 RES:  0.00017958
 ELA:  10.756  Jacobi stage: ITER:   54521 RES:  0.00016661
 ELA:  10.856  Jacobi stage: ITER:   55003 RES:  0.00015477
 ELA:  10.957  Jacobi stage: ITER:   55475 RES:  0.00014394
 ELA:  11.057  Jacobi stage: ITER:   55951 RES:   0.0001338
 ELA:  11.157  Jacobi stage: ITER:   56415 RES:  0.00012459
 ELA:  11.257  Jacobi stage: ITER:   56887 RES:  0.00011588
 ELA:  11.357  Jacobi stage: ITER:   57387 RES:  0.00010731
 ELA:  11.457  Jacobi stage: ITER:   58157 RES:  9.5312e-05
 ELA:  11.557  Jacobi stage: ITER:   58631 RES:  8.8647e-05
 ELA:  11.657  Jacobi stage: ITER:   59113 RES:  8.2296e-05
 ELA:  11.758  Jacobi stage: ITER:   59591 RES:  7.6493e-05
 ELA:  11.858  Jacobi stage: ITER:   60029 RES:  7.1494e-05
 ELA:  11.958  Jacobi stage: ITER:   60507 RES:  6.6454e-05
 ELA:  12.058  Jacobi stage: ITER:   60999 RES:  6.1617e-05
 ELA:  12.158  Jacobi stage: ITER:   61495 RES:  5.7097e-05
 ELA:  12.258  Jacobi stage: ITER:   61993 RES:  5.2876e-05
 ELA:  12.358  Jacobi stage: ITER:   62507 RES:  4.8877e-05
 ELA:  12.458  Jacobi stage: ITER:   62933 RES:  4.5767e-05
 ELA:  12.559  Jacobi stage: ITER:   63429 RES:  4.2409e-05
 ELA:  12.659  Jacobi stage: ITER:   63923 RES:  3.9323e-05
 ELA:  12.759  Jacobi stage: ITER:   64419 RES:  3.6438e-05
 ELA:  12.859  Jacobi stage: ITER:   64935 RES:  3.3662e-05
 ELA:  12.959  Jacobi stage: ITER:   69107 RES:  1.7735e-05
 ELA:  13.059  Jacobi stage: ITER:   73617 RES:  8.8683e-06
 ELA:  13.159  Jacobi stage: ITER:   78193 RES:  4.3912e-06
 ELA:  13.259  Jacobi stage: ITER:   82763 RES:   2.177e-06
 ELA:   13.36  Jacobi stage: ITER:   86239 RES:  1.2764e-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