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 >:

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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:   11071 RES:     0.13186
  Jacobi stage: ITER:   22231 RES:     0.02376
  Jacobi stage: ITER:   33309 RES:   0.0043323
  Jacobi stage: ITER:   44471 RES:  0.00078028
  Jacobi stage: ITER:   55631 RES:  0.00014054
  Jacobi stage: ITER:   66793 RES:  2.5296e-05
  Jacobi stage: ITER:   77995 RES:  4.5282e-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:    3439 RES:     0.44102
  Jacobi stage: ITER:    6905 RES:     0.25088
  Jacobi stage: ITER:   10105 RES:     0.15303
  Jacobi stage: ITER:   13673 RES:    0.088433
  Jacobi stage: ITER:   17095 RES:    0.052295
  Jacobi stage: ITER:   20291 RES:    0.032008
  Jacobi stage: ITER:   23755 RES:    0.018801
  Jacobi stage: ITER:   27215 RES:     0.01105
  Jacobi stage: ITER:   30685 RES:   0.0064828
  Jacobi stage: ITER:   34183 RES:   0.0037892
  Jacobi stage: ITER:   37689 RES:   0.0022107
  Jacobi stage: ITER:   41155 RES:   0.0012985
  Jacobi stage: ITER:   44621 RES:  0.00076228
  Jacobi stage: ITER:   48087 RES:  0.00044775
  Jacobi stage: ITER:   51563 RES:  0.00026252
  Jacobi stage: ITER:   55035 RES:  0.00015401
  Jacobi stage: ITER:   58511 RES:  9.0296e-05
  Jacobi stage: ITER:   60483 RES:  6.6699e-05
  Jacobi stage: ITER:   61279 RES:  5.9023e-05
  Jacobi stage: ITER:   62095 RES:   5.207e-05
  Jacobi stage: ITER:   62911 RES:  4.5936e-05
  Jacobi stage: ITER:   63727 RES:  4.0524e-05
  Jacobi stage: ITER:   64545 RES:  3.5729e-05
  Jacobi stage: ITER:   65363 RES:   3.152e-05
  Jacobi stage: ITER:   66181 RES:   2.779e-05
  Jacobi stage: ITER:   66999 RES:  2.4516e-05
  Jacobi stage: ITER:   67817 RES:  2.1615e-05
  Jacobi stage: ITER:   68653 RES:   1.901e-05
  Jacobi stage: ITER:   69471 RES:   1.677e-05
  Jacobi stage: ITER:   70289 RES:  1.4786e-05
  Jacobi stage: ITER:   71107 RES:  1.3044e-05
  Jacobi stage: ITER:   71923 RES:  1.1507e-05
  Jacobi stage: ITER:   72741 RES:  1.0146e-05
  Jacobi stage: ITER:   73559 RES:  8.9504e-06
  Jacobi stage: ITER:   74377 RES:  7.8911e-06
  Jacobi stage: ITER:   75195 RES:  6.9616e-06
  Jacobi stage: ITER:   75983 RES:  6.1679e-06
  Jacobi stage: ITER:   76799 RES:  5.4413e-06
  Jacobi stage: ITER:   77615 RES:  4.8003e-06
  Jacobi stage: ITER:   78433 RES:  4.2322e-06
  Jacobi stage: ITER:   79251 RES:  3.7337e-06
  Jacobi stage: ITER:   80165 RES:  3.2436e-06
  Jacobi stage: ITER:   80987 RES:  2.8598e-06
  Jacobi stage: ITER:   81807 RES:  2.5213e-06
  Jacobi stage: ITER:   82623 RES:  2.2243e-06
  Jacobi stage: ITER:   83443 RES:  1.9611e-06
  Jacobi stage: ITER:   84267 RES:  1.7279e-06
  Jacobi stage: ITER:   85087 RES:  1.5234e-06
  Jacobi stage: ITER:   85905 RES:  1.3432e-06
  Jacobi stage: ITER:   86719 RES:  1.1857e-06
  Jacobi stage: ITER:   87539 RES:  1.0453e-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
 ELA: 0.10139  Jacobi stage: ITER:    7061 RES:     0.24486
 ELA: 0.20154  Jacobi stage: ITER:   17493 RES:    0.049179
 ELA: 0.30167  Jacobi stage: ITER:   28235 RES:   0.0094478
 ELA:  0.4018  Jacobi stage: ITER:   39079 RES:   0.0017852
 ELA: 0.50193  Jacobi stage: ITER:   49917 RES:  0.00033793
 ELA: 0.60205  Jacobi stage: ITER:   60709 RES:  6.4404e-05
 ELA: 0.70218  Jacobi stage: ITER:   71559 RES:  1.2169e-05
 ELA: 0.80231  Jacobi stage: ITER:   82295 RES:  2.3393e-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:1.6994e-
 ELA: 0.10012  Jacobi stage: ITER:     753 RES:     0.78983
 ELA: 0.20213  Jacobi stage: ITER:    1589 RES:      0.6378
 ELA: 0.30226  Jacobi stage: ITER:    2407 RES:     0.53519
 ELA: 0.40239  Jacobi stage: ITER:    3223 RES:     0.45841
 ELA: 0.50255  Jacobi stage: ITER:    4039 RES:     0.39753
 ELA: 0.60269  Jacobi stage: ITER:    4857 RES:     0.34704
 ELA: 0.70283  Jacobi stage: ITER:    5675 RES:     0.30444
 ELA: 0.80294  Jacobi stage: ITER:    6493 RES:     0.26755
 ELA: 0.90305  Jacobi stage: ITER:    7311 RES:      0.2356
 ELA:  1.0032  Jacobi stage: ITER:    8123 RES:     0.20776
 ELA:  1.1033  Jacobi stage: ITER:    8941 RES:     0.18306
 ELA:  1.2034  Jacobi stage: ITER:    9759 RES:     0.16144
 ELA:  1.3035  Jacobi stage: ITER:   10575 RES:      0.1424
 ELA:  1.4036  Jacobi stage: ITER:   11393 RES:     0.12553
 ELA:  1.5037  Jacobi stage: ITER:   12211 RES:     0.11074
 ELA:  1.6039  Jacobi stage: ITER:   13027 RES:     0.09769
 ELA:   1.704  Jacobi stage: ITER:   13847 RES:    0.086127
 ELA:  1.8041  Jacobi stage: ITER:   14663 RES:     0.07598
 ELA:  1.9043  Jacobi stage: ITER:   15479 RES:    0.067029
 ELA:  2.0044  Jacobi stage: ITER:   16421 RES:    0.057982
 ELA:  2.1045  Jacobi stage: ITER:   17243 RES:     0.05112
 ELA:  2.2046  Jacobi stage: ITER:   18059 RES:    0.045098
 ELA:  2.3055  Jacobi stage: ITER:   18883 RES:    0.039736
 ELA:  2.4056  Jacobi stage: ITER:   19671 RES:    0.035206
 ELA:  2.5057  Jacobi stage: ITER:   20487 RES:    0.031059
 ELA:  2.6059  Jacobi stage: ITER:   21307 RES:    0.027383
 ELA:   2.706  Jacobi stage: ITER:   22125 RES:    0.024143
 ELA:  2.8061  Jacobi stage: ITER:   22943 RES:    0.021299
 ELA:  2.9062  Jacobi stage: ITER:   23759 RES:     0.01879
 ELA:  3.0064  Jacobi stage: ITER:   24579 RES:    0.016566
 ELA:  3.1065  Jacobi stage: ITER:   25399 RES:    0.014605
 ELA:  3.2066  Jacobi stage: ITER:   26215 RES:    0.012885
 ELA:  3.3068  Jacobi stage: ITER:   27041 RES:    0.011346
 ELA:  3.4069  Jacobi stage: ITER:   28197 RES:   0.0095002
 ELA:   3.507  Jacobi stage: ITER:   31191 RES:   0.0059998
 ELA:  3.6071  Jacobi stage: ITER:   34191 RES:   0.0037846
 ELA:  3.7072  Jacobi stage: ITER:   37375 RES:   0.0023207
 ELA:  3.8074  Jacobi stage: ITER:   40521 RES:   0.0014309
 ELA:  3.9075  Jacobi stage: ITER:   43539 RES:  0.00090038
 ELA:  4.0076  Jacobi stage: ITER:   46903 RES:  0.00053705
 ELA:  4.1077  Jacobi stage: ITER:   50595 RES:   0.0003046
 ELA:  4.2079  Jacobi stage: ITER:   54267 RES:  0.00017329
 ELA:   4.308  Jacobi stage: ITER:   57945 RES:  9.8467e-05
 ELA:  4.4081  Jacobi stage: ITER:   61623 RES:  5.5985e-05
 ELA:  4.5082  Jacobi stage: ITER:   65307 RES:  3.1792e-05
 ELA:  4.6083  Jacobi stage: ITER:   68989 RES:  1.8054e-05
 ELA:  4.7085  Jacobi stage: ITER:   72673 RES:  1.0252e-05
 ELA:  4.8086  Jacobi stage: ITER:   76355 RES:  5.8254e-06
 ELA:  4.9087  Jacobi stage: ITER:   80017 RES:  3.3182e-06
 ELA:  5.0088  Jacobi stage: ITER:   83675 RES:  1.8924e-06
 ELA:  5.1089  Jacobi stage: ITER:   87171 RES:  1.1061e-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()