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// ************************************************************************
//
// Belos: Block Linear Solvers Package
// Copyright 2004 Sandia Corporation
//
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//@HEADER
#ifndef BELOS_PSEUDO_BLOCK_TFQMR_SOLMGR_HPP
#define BELOS_PSEUDO_BLOCK_TFQMR_SOLMGR_HPP
/*! \file BelosPseudoBlockTFQMRSolMgr.hpp
* \brief The Belos::PseudoBlockTFQMRSolMgr provides a solver manager for the pseudo-block TFQMR linear solver.
*/
#include "BelosConfigDefs.hpp"
#include "BelosTypes.hpp"
#include "BelosLinearProblem.hpp"
#include "BelosSolverManager.hpp"
#include "BelosPseudoBlockTFQMRIter.hpp"
#include "BelosStatusTestMaxIters.hpp"
#include "BelosStatusTestGenResNorm.hpp"
#include "BelosStatusTestCombo.hpp"
#include "BelosStatusTestOutputFactory.hpp"
#include "BelosOutputManager.hpp"
#ifdef BELOS_TEUCHOS_TIME_MONITOR
#include "Teuchos_TimeMonitor.hpp"
#endif
/** \example TFQMR/PseudoBlockTFQMREpetraExFile.cpp
This is an example of how to use the Belos::PseudoBlockTFQMRSolMgr solver manager.
*/
/*! \class Belos::PseudoBlockTFQMRSolMgr
*
* \brief The Belos::PseudoBlockTFQMRSolMgr provides a powerful and fully-featured solver manager over the pseudo-block TFQMR linear solver.
\ingroup belos_solver_framework
\author Heidi Thornquist
*/
namespace Belos {
//! @name PseudoBlockTFQMRSolMgr Exceptions
//@{
/** \brief PseudoBlockTFQMRSolMgrLinearProblemFailure is thrown when the linear problem is
* not setup (i.e. setProblem() was not called) when solve() is called.
*
* This std::exception is thrown from the PseudoBlockTFQMRSolMgr::solve() method.
*
*/
class PseudoBlockTFQMRSolMgrLinearProblemFailure : public BelosError {public:
PseudoBlockTFQMRSolMgrLinearProblemFailure(const std::string& what_arg) : BelosError(what_arg)
{}};
/** \brief PseudoBlockTFQMRSolMgrOrthoFailure is thrown when the orthogonalization manager is
* unable to generate orthonormal columns from the initial basis vectors.
*
* This std::exception is thrown from the PseudoBlockTFQMRSolMgr::solve() method.
*
*/
class PseudoBlockTFQMRSolMgrOrthoFailure : public BelosError {public:
PseudoBlockTFQMRSolMgrOrthoFailure(const std::string& what_arg) : BelosError(what_arg)
{}};
template<class ScalarType, class MV, class OP>
class PseudoBlockTFQMRSolMgr : public SolverManager<ScalarType,MV,OP> {
private:
typedef MultiVecTraits<ScalarType,MV> MVT;
typedef OperatorTraits<ScalarType,MV,OP> OPT;
typedef Teuchos::ScalarTraits<ScalarType> SCT;
typedef typename Teuchos::ScalarTraits<ScalarType>::magnitudeType MagnitudeType;
typedef Teuchos::ScalarTraits<MagnitudeType> MT;
public:
//! @name Constructors/Destructor
//@{
/*! \brief Empty constructor for PseudoBlockTFQMRSolMgr.
* This constructor takes no arguments and sets the default values for the solver.
* The linear problem must be passed in using setProblem() before solve() is called on this object.
* The solver values can be changed using setParameters().
*/
PseudoBlockTFQMRSolMgr();
/*! \brief Basic constructor for PseudoBlockTFQMRSolMgr.
*
* This constructor accepts the LinearProblem to be solved in addition
* to a parameter list of options for the solver manager. These options include the following:
* - "Maximum Iterations" - an \c int specifying the maximum number of iterations the
* underlying solver is allowed to perform. Default: 1000
* - "Convergence Tolerance" - a \c MagnitudeType specifying the level that residual norms
* must reach to decide convergence. Default: 1e-8.
* - "Verbosity" - a sum of MsgType specifying the verbosity. Default: Belos::Errors
* - "Output Style" - a OutputType specifying the style of output. Default: Belos::General
* - "Output Stream" - a reference-counted pointer to the output stream where all
* solver output is sent. Default: Teuchos::rcp(&std::cout,false)
* - "Output Frequency" - an \c int specifying how often convergence information should be
* outputted. Default: -1 (never)
* - "Timer Label" - a \c std::string to use as a prefix for the timer labels. Default: "Belos"
*/
PseudoBlockTFQMRSolMgr( const Teuchos::RCP<LinearProblem<ScalarType,MV,OP> > &problem,
const Teuchos::RCP<Teuchos::ParameterList> &pl );
//! Destructor.
virtual ~PseudoBlockTFQMRSolMgr() {};
//@}
//! @name Accessor methods
//@{
const LinearProblem<ScalarType,MV,OP>& getProblem() const {
return *problem_;
}
/*! \brief Get a parameter list containing the valid parameters for this object.
*/
Teuchos::RCP<const Teuchos::ParameterList> getValidParameters() const;
/*! \brief Get a parameter list containing the current parameters for this object.
*/
Teuchos::RCP<const Teuchos::ParameterList> getCurrentParameters() const { return params_; }
/*! \brief Return the timers for this object.
*
* The timers are ordered as follows:
* - time spent in solve() routine
*/
Teuchos::Array<Teuchos::RCP<Teuchos::Time> > getTimers() const {
return Teuchos::tuple(timerSolve_);
}
/// \brief Tolerance achieved by the last \c solve() invocation.
///
/// This is the maximum over all right-hand sides' achieved
/// convergence tolerances, and is set whether or not the solve
/// actually managed to achieve the desired convergence tolerance.
MagnitudeType achievedTol() const {
return achievedTol_;
}
//! Get the iteration count for the most recent call to \c solve().
int getNumIters() const {
return numIters_;
}
/// \brief Whether loss of accuracy was detected during the last \c solve() invocation.
///
/// In solvers that can detect a loss of accuracy, this method
/// would say whether the solver detected it in the most recent \c
/// solve() invocation. However, our TFQMR implementation does
/// not currently detect a loss of accuracy, so this method always
/// returns false.
bool isLOADetected() const { return false; }
//@}
//! @name Set methods
//@{
//! Set the linear problem that needs to be solved.
void setProblem( const Teuchos::RCP<LinearProblem<ScalarType,MV,OP> > &problem ) { problem_ = problem; }
//! Set the parameters the solver manager should use to solve the linear problem.
void setParameters( const Teuchos::RCP<Teuchos::ParameterList> ¶ms );
//@}
//! @name Reset methods
//@{
/*! \brief Performs a reset of the solver manager specified by the \c ResetType. This informs the
* solver manager that the solver should prepare for the next call to solve by resetting certain elements
* of the iterative solver strategy.
*/
void reset( const ResetType type ) { if ((type & Belos::Problem) && !Teuchos::is_null(problem_)) problem_->setProblem(); }
//@}
//! @name Solver application methods
//@{
/*! \brief This method performs possibly repeated calls to the underlying linear solver's
* iterate() routine until the problem has been solved (as decided by the solver manager)
* or the solver manager decides to quit.
*
* This method calls PseudoBlockTFQMRIter::iterate(), which will return either because a
* specially constructed status test evaluates to ::Passed or an std::exception is thrown.
*
* A return from PseudoBlockTFQMRIter::iterate() signifies one of the following scenarios:
* - the maximum number of iterations has been exceeded. In this scenario, the current solutions
* to the linear system will be placed in the linear problem and return ::Unconverged.
* - global convergence has been met. In this case, the current solutions to the linear system
* will be placed in the linear problem and the solver manager will return ::Converged
*
* \returns ::ReturnType specifying:
* - ::Converged: the linear problem was solved to the specification required by the solver manager.
* - ::Unconverged: the linear problem was not solved to the specification desired by the solver manager.
*/
ReturnType solve();
//@}
/** \name Overridden from Teuchos::Describable */
//@{
/** \brief Method to return description of the pseudo-block TFQMR solver manager */
std::string description() const;
//@}
private:
// Method for checking current status test against defined linear problem.
bool checkStatusTest();
// Linear problem.
Teuchos::RCP<LinearProblem<ScalarType,MV,OP> > problem_;
// Output manager.
Teuchos::RCP<OutputManager<ScalarType> > printer_;
Teuchos::RCP<std::ostream> outputStream_;
// Status test.
Teuchos::RCP<StatusTest<ScalarType,MV,OP> > sTest_;
Teuchos::RCP<StatusTestMaxIters<ScalarType,MV,OP> > maxIterTest_;
Teuchos::RCP<StatusTest<ScalarType,MV,OP> > convTest_;
Teuchos::RCP<StatusTestGenResNorm<ScalarType,MV,OP> > expConvTest_, impConvTest_;
Teuchos::RCP<StatusTestOutput<ScalarType,MV,OP> > outputTest_;
// Current parameter list.
Teuchos::RCP<Teuchos::ParameterList> params_;
// Default solver values.
static const MagnitudeType convtol_default_;
static const int maxIters_default_;
static const bool expResTest_default_;
static const int verbosity_default_;
static const int outputStyle_default_;
static const int outputFreq_default_;
static const int defQuorum_default_;
static const std::string impResScale_default_;
static const std::string expResScale_default_;
static const std::string label_default_;
static const Teuchos::RCP<std::ostream> outputStream_default_;
// Current solver values.
MagnitudeType convtol_, achievedTol_;
int maxIters_, numIters_;
int verbosity_, outputStyle_, outputFreq_, defQuorum_;
bool expResTest_;
std::string impResScale_, expResScale_;
// Timers.
std::string label_;
Teuchos::RCP<Teuchos::Time> timerSolve_;
// Internal state variables.
bool isSet_, isSTSet_;
};
// Default solver values.
template<class ScalarType, class MV, class OP>
const typename PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::MagnitudeType PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::convtol_default_ = 1e-8;
template<class ScalarType, class MV, class OP>
const int PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::maxIters_default_ = 1000;
template<class ScalarType, class MV, class OP>
const bool PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::expResTest_default_ = false;
template<class ScalarType, class MV, class OP>
const int PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::verbosity_default_ = Belos::Errors;
template<class ScalarType, class MV, class OP>
const int PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::outputStyle_default_ = Belos::General;
template<class ScalarType, class MV, class OP>
const int PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::outputFreq_default_ = -1;
template<class ScalarType, class MV, class OP>
const int PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::defQuorum_default_ = 1;
template<class ScalarType, class MV, class OP>
const std::string PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::impResScale_default_ = "Norm of Preconditioned Initial Residual";
template<class ScalarType, class MV, class OP>
const std::string PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::expResScale_default_ = "Norm of Initial Residual";
template<class ScalarType, class MV, class OP>
const std::string PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::label_default_ = "Belos";
template<class ScalarType, class MV, class OP>
const Teuchos::RCP<std::ostream> PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::outputStream_default_ = Teuchos::rcp(&std::cout,false);
// Empty Constructor
template<class ScalarType, class MV, class OP>
PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::PseudoBlockTFQMRSolMgr() :
outputStream_(outputStream_default_),
convtol_(convtol_default_),
achievedTol_(Teuchos::ScalarTraits<typename Teuchos::ScalarTraits<ScalarType>::magnitudeType>::zero()),
maxIters_(maxIters_default_),
numIters_(0),
verbosity_(verbosity_default_),
outputStyle_(outputStyle_default_),
outputFreq_(outputFreq_default_),
defQuorum_(defQuorum_default_),
expResTest_(expResTest_default_),
impResScale_(impResScale_default_),
expResScale_(expResScale_default_),
label_(label_default_),
isSet_(false),
isSTSet_(false)
{}
// Basic Constructor
template<class ScalarType, class MV, class OP>
PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::PseudoBlockTFQMRSolMgr(
const Teuchos::RCP<LinearProblem<ScalarType,MV,OP> > &problem,
const Teuchos::RCP<Teuchos::ParameterList> &pl ) :
problem_(problem),
outputStream_(outputStream_default_),
convtol_(convtol_default_),
achievedTol_(Teuchos::ScalarTraits<typename Teuchos::ScalarTraits<ScalarType>::magnitudeType>::zero()),
maxIters_(maxIters_default_),
numIters_(0),
verbosity_(verbosity_default_),
outputStyle_(outputStyle_default_),
outputFreq_(outputFreq_default_),
defQuorum_(defQuorum_default_),
expResTest_(expResTest_default_),
impResScale_(impResScale_default_),
expResScale_(expResScale_default_),
label_(label_default_),
isSet_(false),
isSTSet_(false)
{
TEUCHOS_TEST_FOR_EXCEPTION(problem_ == Teuchos::null, std::invalid_argument, "Problem not given to solver manager.");
// If the parameter list pointer is null, then set the current parameters to the default parameter list.
if ( !is_null(pl) ) {
setParameters( pl );
}
}
template<class ScalarType, class MV, class OP>
void PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::setParameters( const Teuchos::RCP<Teuchos::ParameterList> ¶ms )
{
// Create the internal parameter list if ones doesn't already exist.
if (params_ == Teuchos::null) {
params_ = Teuchos::rcp( new Teuchos::ParameterList(*getValidParameters()) );
}
else {
params->validateParameters(*getValidParameters());
}
// Check for maximum number of iterations
if (params->isParameter("Maximum Iterations")) {
maxIters_ = params->get("Maximum Iterations",maxIters_default_);
// Update parameter in our list and in status test.
params_->set("Maximum Iterations", maxIters_);
if (maxIterTest_!=Teuchos::null)
maxIterTest_->setMaxIters( maxIters_ );
}
// Check to see if the timer label changed.
if (params->isParameter("Timer Label")) {
std::string tempLabel = params->get("Timer Label", label_default_);
// Update parameter in our list and solver timer
if (tempLabel != label_) {
label_ = tempLabel;
params_->set("Timer Label", label_);
std::string solveLabel = label_ + ": PseudoBlockTFQMRSolMgr total solve time";
#ifdef BELOS_TEUCHOS_TIME_MONITOR
timerSolve_ = Teuchos::TimeMonitor::getNewCounter(solveLabel);
#endif
}
}
// Check for a change in verbosity level
if (params->isParameter("Verbosity")) {
if (Teuchos::isParameterType<int>(*params,"Verbosity")) {
verbosity_ = params->get("Verbosity", verbosity_default_);
} else {
verbosity_ = (int)Teuchos::getParameter<Belos::MsgType>(*params,"Verbosity");
}
// Update parameter in our list.
params_->set("Verbosity", verbosity_);
if (printer_ != Teuchos::null)
printer_->setVerbosity(verbosity_);
}
// Check for a change in output style
if (params->isParameter("Output Style")) {
if (Teuchos::isParameterType<int>(*params,"Output Style")) {
outputStyle_ = params->get("Output Style", outputStyle_default_);
} else {
outputStyle_ = (int)Teuchos::getParameter<Belos::OutputType>(*params,"Output Style");
}
// Reconstruct the convergence test if the explicit residual test is not being used.
params_->set("Output Style", outputStyle_);
isSTSet_ = false;
}
// output stream
if (params->isParameter("Output Stream")) {
outputStream_ = Teuchos::getParameter<Teuchos::RCP<std::ostream> >(*params,"Output Stream");
// Update parameter in our list.
params_->set("Output Stream", outputStream_);
if (printer_ != Teuchos::null)
printer_->setOStream( outputStream_ );
}
// frequency level
if (verbosity_ & Belos::StatusTestDetails) {
if (params->isParameter("Output Frequency")) {
outputFreq_ = params->get("Output Frequency", outputFreq_default_);
}
// Update parameter in out list and output status test.
params_->set("Output Frequency", outputFreq_);
if (outputTest_ != Teuchos::null)
outputTest_->setOutputFrequency( outputFreq_ );
}
// Create output manager if we need to.
if (printer_ == Teuchos::null) {
printer_ = Teuchos::rcp( new OutputManager<ScalarType>(verbosity_, outputStream_) );
}
// Check for convergence tolerance
if (params->isParameter("Convergence Tolerance")) {
convtol_ = params->get("Convergence Tolerance",convtol_default_);
// Update parameter in our list and residual tests.
params_->set("Convergence Tolerance", convtol_);
if (impConvTest_ != Teuchos::null)
impConvTest_->setTolerance( convtol_ );
if (expConvTest_ != Teuchos::null)
expConvTest_->setTolerance( convtol_ );
}
// Check for a change in scaling, if so we need to build new residual tests.
if (params->isParameter("Implicit Residual Scaling")) {
std::string tempImpResScale = Teuchos::getParameter<std::string>( *params, "Implicit Residual Scaling" );
// Only update the scaling if it's different.
if (impResScale_ != tempImpResScale) {
Belos::ScaleType impResScaleType = convertStringToScaleType( tempImpResScale );
impResScale_ = tempImpResScale;
// Update parameter in our list and residual tests
params_->set("Implicit Residual Scaling", impResScale_);
if (impConvTest_ != Teuchos::null) {
try {
impConvTest_->defineScaleForm( impResScaleType, Belos::TwoNorm );
}
catch (std::exception& e) {
// Make sure the convergence test gets constructed again.
isSTSet_ = false;
}
}
}
}
if (params->isParameter("Explicit Residual Scaling")) {
std::string tempExpResScale = Teuchos::getParameter<std::string>( *params, "Explicit Residual Scaling" );
// Only update the scaling if it's different.
if (expResScale_ != tempExpResScale) {
Belos::ScaleType expResScaleType = convertStringToScaleType( tempExpResScale );
expResScale_ = tempExpResScale;
// Update parameter in our list and residual tests
params_->set("Explicit Residual Scaling", expResScale_);
if (expConvTest_ != Teuchos::null) {
try {
expConvTest_->defineScaleForm( expResScaleType, Belos::TwoNorm );
}
catch (std::exception& e) {
// Make sure the convergence test gets constructed again.
isSTSet_ = false;
}
}
}
}
if (params->isParameter("Explicit Residual Test")) {
expResTest_ = Teuchos::getParameter<bool>( *params,"Explicit Residual Test" );
// Reconstruct the convergence test if the explicit residual test is not being used.
params_->set("Explicit Residual Test", expResTest_);
if (expConvTest_ == Teuchos::null) {
isSTSet_ = false;
}
}
// Get the deflation quorum, or number of converged systems before deflation is allowed
if (params->isParameter("Deflation Quorum")) {
defQuorum_ = params->get("Deflation Quorum", defQuorum_);
params_->set ("Deflation Quorum", defQuorum_);
if (! impConvTest_.is_null ()) {
impConvTest_->setQuorum (defQuorum_);
}
if (! expConvTest_.is_null ()) {
expConvTest_->setQuorum (defQuorum_);
}
}
// Create the timer if we need to.
if (timerSolve_ == Teuchos::null) {
std::string solveLabel = label_ + ": PseudoBlockTFQMRSolMgr total solve time";
#ifdef BELOS_TEUCHOS_TIME_MONITOR
timerSolve_ = Teuchos::TimeMonitor::getNewCounter(solveLabel);
#endif
}
// Inform the solver manager that the current parameters were set.
isSet_ = true;
}
// Check the status test versus the defined linear problem
template<class ScalarType, class MV, class OP>
bool PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::checkStatusTest() {
typedef Belos::StatusTestCombo<ScalarType,MV,OP> StatusTestCombo_t;
typedef Belos::StatusTestGenResNorm<ScalarType,MV,OP> StatusTestGenResNorm_t;
// Basic test checks maximum iterations and native residual.
maxIterTest_ = Teuchos::rcp( new StatusTestMaxIters<ScalarType,MV,OP>( maxIters_ ) );
if (expResTest_) {
// Implicit residual test, using the native residual to determine if convergence was achieved.
Teuchos::RCP<StatusTestGenResNorm_t> tmpImpConvTest =
Teuchos::rcp( new StatusTestGenResNorm_t( convtol_, defQuorum_ ) );
tmpImpConvTest->defineScaleForm( convertStringToScaleType(impResScale_), Belos::TwoNorm );
impConvTest_ = tmpImpConvTest;
// Explicit residual test once the native residual is below the tolerance
Teuchos::RCP<StatusTestGenResNorm_t> tmpExpConvTest =
Teuchos::rcp( new StatusTestGenResNorm_t( convtol_, defQuorum_ ) );
tmpExpConvTest->defineResForm( StatusTestGenResNorm_t::Explicit, Belos::TwoNorm );
tmpExpConvTest->defineScaleForm( convertStringToScaleType(expResScale_), Belos::TwoNorm );
expConvTest_ = tmpExpConvTest;
// The convergence test is a combination of the "cheap" implicit test and explicit test.
convTest_ = Teuchos::rcp( new StatusTestCombo_t( StatusTestCombo_t::SEQ, impConvTest_, expConvTest_ ) );
}
else {
// Implicit residual test, using the native residual to determine if convergence was achieved.
Teuchos::RCP<StatusTestGenResNorm_t> tmpImpConvTest =
Teuchos::rcp( new StatusTestGenResNorm_t( convtol_, defQuorum_ ) );
tmpImpConvTest->defineScaleForm( convertStringToScaleType(impResScale_), Belos::TwoNorm );
impConvTest_ = tmpImpConvTest;
// Set the explicit and total convergence test to this implicit test that checks for accuracy loss.
expConvTest_ = impConvTest_;
convTest_ = impConvTest_;
}
sTest_ = Teuchos::rcp( new StatusTestCombo_t( StatusTestCombo_t::OR, maxIterTest_, convTest_ ) );
// Create the status test output class.
// This class manages and formats the output from the status test.
StatusTestOutputFactory<ScalarType,MV,OP> stoFactory( outputStyle_ );
outputTest_ = stoFactory.create( printer_, sTest_, outputFreq_, Passed+Failed+Undefined );
// Set the solver string for the output test
std::string solverDesc = " Pseudo Block TFQMR ";
outputTest_->setSolverDesc( solverDesc );
// The status test is now set.
isSTSet_ = true;
return false;
}
template<class ScalarType, class MV, class OP>
Teuchos::RCP<const Teuchos::ParameterList>
PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::getValidParameters() const
{
static Teuchos::RCP<const Teuchos::ParameterList> validPL;
// Set all the valid parameters and their default values.
if(is_null(validPL)) {
Teuchos::RCP<Teuchos::ParameterList> pl = Teuchos::parameterList();
pl->set("Convergence Tolerance", convtol_default_,
"The relative residual tolerance that needs to be achieved by the\n"
"iterative solver in order for the linear system to be declared converged.");
pl->set("Maximum Iterations", maxIters_default_,
"The maximum number of block iterations allowed for each\n"
"set of RHS solved.");
pl->set("Verbosity", verbosity_default_,
"What type(s) of solver information should be outputted\n"
"to the output stream.");
pl->set("Output Style", outputStyle_default_,
"What style is used for the solver information outputted\n"
"to the output stream.");
pl->set("Output Frequency", outputFreq_default_,
"How often convergence information should be outputted\n"
"to the output stream.");
pl->set("Deflation Quorum", defQuorum_default_,
"The number of linear systems that need to converge before they are deflated.");
pl->set("Output Stream", outputStream_default_,
"A reference-counted pointer to the output stream where all\n"
"solver output is sent.");
pl->set("Explicit Residual Test", expResTest_default_,
"Whether the explicitly computed residual should be used in the convergence test.");
pl->set("Implicit Residual Scaling", impResScale_default_,
"The type of scaling used in the implicit residual convergence test.");
pl->set("Explicit Residual Scaling", expResScale_default_,
"The type of scaling used in the explicit residual convergence test.");
pl->set("Timer Label", label_default_,
"The string to use as a prefix for the timer labels.");
// pl->set("Restart Timers", restartTimers_);
validPL = pl;
}
return validPL;
}
// solve()
template<class ScalarType, class MV, class OP>
ReturnType PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::solve() {
// Set the current parameters if they were not set before.
// NOTE: This may occur if the user generated the solver manager with the default constructor and
// then didn't set any parameters using setParameters().
if (!isSet_) {
setParameters(Teuchos::parameterList(*getValidParameters()));
}
TEUCHOS_TEST_FOR_EXCEPTION(problem_ == Teuchos::null,PseudoBlockTFQMRSolMgrLinearProblemFailure,
"Belos::PseudoBlockTFQMRSolMgr::solve(): Linear problem is not a valid object.");
TEUCHOS_TEST_FOR_EXCEPTION(!problem_->isProblemSet(),PseudoBlockTFQMRSolMgrLinearProblemFailure,
"Belos::PseudoBlockTFQMRSolMgr::solve(): Linear problem is not ready, setProblem() has not been called.");
if (!isSTSet_) {
TEUCHOS_TEST_FOR_EXCEPTION( checkStatusTest(),PseudoBlockTFQMRSolMgrLinearProblemFailure,
"Belos::PseudoBlockTFQMRSolMgr::solve(): Linear problem and requested status tests are incompatible.");
}
// Create indices for the linear systems to be solved.
int startPtr = 0;
int numRHS2Solve = MVT::GetNumberVecs( *(problem_->getRHS()) );
int numCurrRHS = numRHS2Solve;
std::vector<int> currIdx( numRHS2Solve ), currIdx2( numRHS2Solve );
for (int i=0; i<numRHS2Solve; ++i) {
currIdx[i] = startPtr+i;
currIdx2[i]=i;
}
// Inform the linear problem of the current linear system to solve.
problem_->setLSIndex( currIdx );
//////////////////////////////////////////////////////////////////////////////////////
// Parameter list
Teuchos::ParameterList plist;
// Reset the status test.
outputTest_->reset();
// Assume convergence is achieved, then let any failed convergence set this to false.
bool isConverged = true;
//////////////////////////////////////////////////////////////////////////////////////
// TFQMR solver
Teuchos::RCP<PseudoBlockTFQMRIter<ScalarType,MV,OP> > block_tfqmr_iter =
Teuchos::rcp( new PseudoBlockTFQMRIter<ScalarType,MV,OP>(problem_,printer_,outputTest_,plist) );
// Enter solve() iterations
{
#ifdef BELOS_TEUCHOS_TIME_MONITOR
Teuchos::TimeMonitor slvtimer(*timerSolve_);
#endif
while ( numRHS2Solve > 0 ) {
//
// Reset the active / converged vectors from this block
std::vector<int> convRHSIdx;
std::vector<int> currRHSIdx( currIdx );
currRHSIdx.resize(numCurrRHS);
// Reset the number of iterations.
block_tfqmr_iter->resetNumIters();
// Reset the number of calls that the status test output knows about.
outputTest_->resetNumCalls();
// Get the current residual for this block of linear systems.
Teuchos::RCP<MV> R_0 = MVT::CloneViewNonConst( *(Teuchos::rcp_const_cast<MV>(problem_->getInitPrecResVec())), currIdx );
// Set the new state and initialize the solver.
PseudoBlockTFQMRIterState<ScalarType,MV> newstate;
newstate.R = R_0;
block_tfqmr_iter->initializeTFQMR(newstate);
while(1) {
// tell block_tfqmr_iter to iterate
try {
block_tfqmr_iter->iterate();
////////////////////////////////////////////////////////////////////////////////////
//
// check convergence first
//
////////////////////////////////////////////////////////////////////////////////////
if ( convTest_->getStatus() == Passed ) {
// Figure out which linear systems converged.
std::vector<int> convIdx = expConvTest_->convIndices();
// If the number of converged linear systems is equal to the
// number of current linear systems, then we are done with this block.
if (convIdx.size() == currRHSIdx.size())
break; // break from while(1){block_tfqmr_iter->iterate()}
// Update the current solution with the update computed by the iteration object.
problem_->updateSolution( block_tfqmr_iter->getCurrentUpdate(), true );
// Inform the linear problem that we are finished with this current linear system.
problem_->setCurrLS();
// Reset currRHSIdx to have the right-hand sides that are left to converge for this block.
int have = 0;
std::vector<int> unconvIdx(currRHSIdx.size());
for (unsigned int i=0; i<currRHSIdx.size(); ++i) {
bool found = false;
for (unsigned int j=0; j<convIdx.size(); ++j) {
if (currRHSIdx[i] == convIdx[j]) {
found = true;
break;
}
}
if (!found) {
currIdx2[have] = currIdx2[i];
currRHSIdx[have++] = currRHSIdx[i];
}
}
currRHSIdx.resize(have);
currIdx2.resize(have);
// Set the remaining indices after deflation.
problem_->setLSIndex( currRHSIdx );
// Get the current residual vector.
// Set the new state and initialize the solver.
R_0 = MVT::Clone( *(problem_->getInitPrecResVec()), currRHSIdx.size() );
problem_->computeCurrPrecResVec( &*R_0 );
// Set the new state and initialize the solver.
PseudoBlockTFQMRIterState<ScalarType,MV> defstate;
defstate.R = R_0;
block_tfqmr_iter->initializeTFQMR(defstate);
}
////////////////////////////////////////////////////////////////////////////////////
//
// check for maximum iterations
//
////////////////////////////////////////////////////////////////////////////////////
else if ( maxIterTest_->getStatus() == Passed ) {
// we don't have convergence
isConverged = false;
break; // break from while(1){block_tfqmr_iter->iterate()}
}
////////////////////////////////////////////////////////////////////////////////////
//
// we returned from iterate(), but none of our status tests Passed.
// something is wrong, and it is probably our fault.
//
////////////////////////////////////////////////////////////////////////////////////
else {
TEUCHOS_TEST_FOR_EXCEPTION(true,std::logic_error,
"Belos::PseudoBlockTFQMRSolMgr::solve(): Invalid return from PseudoBlockTFQMRIter::iterate().");
}
}
catch (const std::exception &e) {
printer_->stream(Errors) << "Error! Caught std::exception in PseudoBlockTFQMRIter::iterate() at iteration "
<< block_tfqmr_iter->getNumIters() << std::endl
<< e.what() << std::endl;
throw;
}
}
// Update the current solution with the update computed by the iteration object.
problem_->updateSolution( block_tfqmr_iter->getCurrentUpdate(), true );
// Inform the linear problem that we are finished with this block linear system.
problem_->setCurrLS();
// Update indices for the linear systems to be solved.
startPtr += numCurrRHS;
numRHS2Solve -= numCurrRHS;
if ( numRHS2Solve > 0 ) {
numCurrRHS = numRHS2Solve;
currIdx.resize( numCurrRHS );
currIdx2.resize( numCurrRHS );
for (int i=0; i<numCurrRHS; ++i)
{ currIdx[i] = startPtr+i; currIdx2[i] = i; }
// Adapt the status test quorum if we need to.
if (defQuorum_ > numCurrRHS) {
if (impConvTest_ != Teuchos::null)
impConvTest_->setQuorum( numCurrRHS );
if (expConvTest_ != Teuchos::null)
expConvTest_->setQuorum( numCurrRHS );
}
// Set the next indices.
problem_->setLSIndex( currIdx );
}
else {
currIdx.resize( numRHS2Solve );
}
}// while ( numRHS2Solve > 0 )
}
// print final summary
sTest_->print( printer_->stream(FinalSummary) );
// print timing information
#ifdef BELOS_TEUCHOS_TIME_MONITOR
// Calling summarize() can be expensive, so don't call unless the
// user wants to print out timing details. summarize() will do all
// the work even if it's passed a "black hole" output stream.
if (verbosity_ & TimingDetails)
Teuchos::TimeMonitor::summarize( printer_->stream(TimingDetails) );
#endif
// get iteration information for this solve
numIters_ = maxIterTest_->getNumIters();
// Save the convergence test value ("achieved tolerance") for this
// solve. For this solver, convTest_ may either be a single
// (implicit) residual norm test, or a combination of two residual
// norm tests. In the latter case, the master convergence test
// convTest_ is a SEQ combo of the implicit resp. explicit tests.
// If the implicit test never passes, then the explicit test won't
// ever be executed. This manifests as
// expConvTest_->getTestValue()->size() < 1. We deal with this case
// by using the values returned by impConvTest_->getTestValue().
{
// We'll fetch the vector of residual norms one way or the other.
const std::vector<MagnitudeType>* pTestValues = NULL;
if (expResTest_) {
pTestValues = expConvTest_->getTestValue();
if (pTestValues == NULL || pTestValues->size() < 1) {
pTestValues = impConvTest_->getTestValue();
}
}
else {
// Only the implicit residual norm test is being used.
pTestValues = impConvTest_->getTestValue();
}
TEUCHOS_TEST_FOR_EXCEPTION(pTestValues == NULL, std::logic_error,
"Belos::PseudoBlockTFQMRSolMgr::solve(): The implicit convergence test's "
"getTestValue() method returned NULL. Please report this bug to the "
"Belos developers.");
TEUCHOS_TEST_FOR_EXCEPTION(pTestValues->size() < 1, std::logic_error,
"Belos::TMQMRSolMgr::solve(): The implicit convergence test's "
"getTestValue() method returned a vector of length zero. Please report "
"this bug to the Belos developers.");
// FIXME (mfh 12 Dec 2011) Does pTestValues really contain the
// achieved tolerances for all vectors in the current solve(), or
// just for the vectors from the last deflation?
achievedTol_ = *std::max_element (pTestValues->begin(), pTestValues->end());
}
if (!isConverged) {
return Unconverged; // return from PseudoBlockTFQMRSolMgr::solve()
}
return Converged; // return from PseudoBlockTFQMRSolMgr::solve()
}
// This method requires the solver manager to return a std::string that describes itself.
template<class ScalarType, class MV, class OP>
std::string PseudoBlockTFQMRSolMgr<ScalarType,MV,OP>::description() const
{
std::ostringstream oss;
oss << "Belos::PseudoBlockTFQMRSolMgr<...,"<<Teuchos::ScalarTraits<ScalarType>::name()<<">";
oss << "{}";
return oss.str();
}
} // end Belos namespace
#endif /* BELOS_PSEUDO_BLOCK_TFQMR_SOLMGR_HPP */
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