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#define MLAPI_MULTILEVELADAPTIVESA_H
/*!
\file MLAPI_MultiLevelAdaptiveSA.h
\brief Adaptive smoothed aggregation preconditioner.
\author Marzio Sala, Ray Tuminaro, Jonathan Hu, Michael Gee, Marian Brezina.
\date Last updated on Feb-05.
*/
/* ******************************************************************** */
/* See the file COPYRIGHT for a complete copyright notice, contact */
/* person and disclaimer. */
/* ******************************************************************** */
#include "ml_common.h"
#include "ml_agg_genP.h"
#include "MLAPI_Error.h"
#include "MLAPI_CompObject.h"
#include "MLAPI_TimeObject.h"
#include "MLAPI_Operator.h"
#include "MLAPI_Operator_Utils.h"
#include "MLAPI_MultiVector.h"
#include "MLAPI_MultiVector_Utils.h"
#include "MLAPI_InverseOperator.h"
#include "MLAPI_Expressions.h"
#include "MLAPI_BaseOperator.h"
#include "MLAPI_Workspace.h"
#include "MLAPI_Aggregation.h"
#include "MLAPI_Eig.h"
#include <vector>
namespace MLAPI {
/*!
\class MultiLevelAdaptiveSA
\brief Black-box multilevel adaptive smoothed aggregation preconditioner.
This class implements an adaptive smoothed aggregation preconditioner.
An example of usage is reported in file \ref ml_adaptivesa.
We note that the usage of this class is slightly different from that of
MultiLevelSA.
An instance of this class can be created as follows:
\code
int NumPDEEqns = 1;
int MaxLevels = 10;
MultiLevelAdaptiveSA Prec(FineMatrix, List, NumPDEEqns, MaxLevels);
\endcode
Important methods of this class:
- The number of PDE equations on the finest level can be queried using
GetInputNumPDEEqns().
- GetNumPDEEqns() returns the number of PDE equations on the current level.
This value can be set via SetNumPDEEqns().
- GetNullSpace() returns a reference to the internally stored null space;
the null space is set using SetNullSpace().
- GetMaxLevels() returns the number of levels. If called before Compute(),
GetMaxLevels() returns the maximum number of levels used in the
constructor, otherwise returns the actual number of levels.
- GetSmootherType() and GetCoarseType() return the smoother and coarse type.
- The number of application of the cycle in IncrementNullSpace() is given
by GetNumItersCoarse() and GetNumItersFine().
- Methods \c A(level), \c P(level), \c R(level) and \c S(level) return a
reference to the internally stored operators.
- Method SetList() can be used at any time to reset the internally stored
list.
The general usage is:
- Specify the null space using SetNullSpace(NS), where NS is a MultiVector,
then compute the hierarchy using Compute(), or
- Compute the first component of the null space using SetupInitialNullSpace().
This will define a single-vector null space, and store it using
SetNullSpace(NS).
- When a non-empty null space is provided, the user can increment by one
the dimension of the null space by calling IncrementNullSpace().
- Method AdaptCompute() performs all these operations.
\author Marzio Sala, Ray Tuminaro, Jonathan Hu, Michael Gee, Marian Brezina.
\date Last updated on Mar-05.
\todo store the structure of the aggregates for all phases.
\todo Current implementation supposes zero threshold.
*/
class MultiLevelAdaptiveSA : public BaseOperator, public CompObject, public TimeObject {
public:
// @{ \name Constructors and destructors
//! Constructs the hierarchy for given Operator and parameters.
MultiLevelAdaptiveSA(const Operator & FineMatrix, Teuchos::ParameterList& List,
const int NumPDEEqns, const int MaxLevels = 20) :
IsComputed_(false)
{
FineMatrix_ = FineMatrix;
List_ = List;
MaxLevels_ = MaxLevels;
SetInputNumPDEEqns(NumPDEEqns);
SetNumPDEEqns(NumPDEEqns);
ResizeArrays(MaxLevels);
A(0) = FineMatrix;
}
//! Destructor.
virtual ~MultiLevelAdaptiveSA()
{ }
// @}
// @{ \name Set and Get methods
//! Returns a copy of the internally stored domain space.
const Space GetOperatorDomainSpace() const
{
return(FineMatrix_.GetDomainSpace());
}
//! Returns a copy of the internally stored range space.
const Space GetOperatorRangeSpace() const
{
return(FineMatrix_.GetRangeSpace());
}
//! Returns a copy of the internally stored domain space.
inline const Space GetDomainSpace() const
{
return(FineMatrix_.GetDomainSpace());
}
//! Returns a copy of the internally stored range space.
inline const Space GetRangeSpace() const
{
return(FineMatrix_.GetRangeSpace());
}
//! Returns a reference to the restriction operator of level \c i.
inline Operator& R(const int i)
{
return(R_[i]);
}
//! Returns a reference to the restriction operator of level \c i.
inline const Operator& R(const int i) const
{
return(R_[i]);
}
//! Returns a reference to the operator of level \c i.
inline Operator& A(const int i)
{
return(A_[i]);
}
//! Returns a reference to the operator of level \c i.
inline const Operator& A(const int i) const
{
return(A_[i]);
}
//! Returns a reference to the prolongator operator of level \c i.
inline Operator& P(const int i)
{
return(P_[i]);
}
//! Returns a reference to the prolongator operator of level \c i.
inline const Operator& P(const int i) const
{
return(P_[i]);
}
//! Returns a reference to the inverse operator of level \c i.
inline InverseOperator& S(const int i)
{
return(S_[i]);
}
//! Returns a reference to the inverse operator of level \c i.
inline const InverseOperator& S(const int i) const
{
return(S_[i]);
}
//! Returns the actual number of levels
inline int GetMaxLevels() const
{
return(MaxLevels_);
}
//! Returns the actual number of levels
inline void SetMaxLevels(const int MaxLevels)
{
MaxLevels_ = MaxLevels;
}
//! Gets a reference to the internally stored null space.
inline const MultiVector GetNullSpace() const
{
return(NullSpace_);
}
//! Sets the null space multi-vector to \c NullSpace.
inline void SetNullSpace(MultiVector& NullSpace)
{
NullSpace_ = NullSpace;
}
//! Returns \c true if the hierarchy has been successfully computed.
inline bool IsComputed() const
{
return(IsComputed_);
}
//! Sets the internally stored list to \c List.
inline void SetList(Teuchos::ParameterList& List)
{
List_ = List;
}
//! Returns the smoother solver type.
inline std::string GetSmootherType()
{
return(List_.get("smoother: type", "symmetric Gauss-Seidel"));
}
//! Returns the coarse solver type.
inline std::string GetCoarseType()
{
return(List_.get("coarse: type", "Amesos-KLU"));
}
//! Returns the number of PDE equations on the finest level.
inline void SetInputNumPDEEqns(const int n)
{
NumPDEEqns_ = n;
}
//! Returns the number of PDE equations on the current level.
inline int GetInputNumPDEEqns()
{
return(NumPDEEqns_);
}
//! Sets the number of PDE equations on the current level.
inline int GetNumPDEEqns()
{
return(List_.get("PDE equations", 1));
}
inline void SetNumPDEEqns(const int NumPDEEqns)
{
List_.set("PDE equations", NumPDEEqns);
}
//! Returns the maximum allowed coarse size.
inline int GetMaxCoarseSize()
{
return(List_.get("coarse: max size", 32));
}
//! Returns the maximum allowed reduction.
inline double GetMaxReduction()
{
return(List_.get("adapt: max reduction", 0.1));
}
//! Returns the maximum number of applications on the coarser levels.
inline int GetNumItersCoarse()
{
return(List_.get("adapt: iters coarse", 5));
}
//! Returns the maximum number of applications on the finest level.
inline int GetNumItersFine()
{
return(List_.get("adapt: iters fine", 15));
}
//! Returns the multigrid preconditioner operator complexity.
double GetComplexity()
{
double nnzFine = A_[0].GetNumGlobalNonzeros();
double nnzTotal = nnzFine;
for (int i = 1; i < GetMaxLevels(); i++) {
nnzTotal += A_[i].GetNumGlobalNonzeros();
}
return nnzTotal / nnzFine;
}
// @}
// @{ \name Hierarchy construction methods
// ======================================================================
//! Creates an hierarchy using the provided or default null space.
// ======================================================================
void Compute()
{
ResetTimer();
StackPush();
IsComputed_ = false;
// get parameter from the input list
SetNumPDEEqns(GetInputNumPDEEqns());
// retrive null space
MultiVector ThisNS = GetNullSpace();
if (GetPrintLevel()) {
std::cout << std::endl;
ML_print_line("-", 80);
std::cout << "Computing the hierarchy, input null space dimension = "
<< ThisNS.GetNumVectors() << std::endl;
}
// build up the default null space
if (ThisNS.GetNumVectors() == 0) {
ThisNS.Reshape(FineMatrix_.GetDomainSpace(),GetNumPDEEqns());
ThisNS = 0.0;
for (int i = 0 ; i < ThisNS.GetMyLength() ; ++i)
for (int j = 0 ; j < GetNumPDEEqns() ;++j)
if (i % GetNumPDEEqns() == j)
ThisNS(i,j) = 1.0;
SetNullSpace(ThisNS);
}
MultiVector NextNS; // contains the next-level null space
// work on increasing hierarchies only.
A(0) = FineMatrix_;
int level;
for (level = 0 ; level < GetMaxLevels() - 1 ; ++level) {
if (GetPrintLevel()) ML_print_line("-", 80);
if (level)
SetNumPDEEqns(ThisNS.GetNumVectors());
// load current level into database
List_.set("workspace: current level", level);
GetSmoothedP(A(level), List_, ThisNS, P(level), NextNS);
ThisNS = NextNS;
R(level) = GetTranspose(P(level));
A(level + 1) = GetRAP(R(level),A(level),P(level));
S(level).Reshape(A(level), GetSmootherType(), List_);
// break if coarse matrix is below specified tolerance
if (A(level + 1).GetNumGlobalRows() <= GetMaxCoarseSize()) {
++level;
break;
}
}
// set coarse solver
S(level).Reshape(A(level), GetCoarseType(), List_);
SetMaxLevels(level + 1);
// set the label
SetLabel("SA, L = " + GetString(GetMaxLevels()) +
", smoother = " + GetSmootherType());
if (GetPrintLevel()) ML_print_line("-", 80);
IsComputed_ = true;
StackPop();
// FIXME: update flops!
UpdateTime();
}
// ======================================================================
//! Setup the adaptive multilevel hierarchy.
/* Computes the multilevel hierarchy as specified by the user.
*
* \param UseDefaultOrSpecified - (In) if \c true, the first call to Compute()
* uses either the default null space or the null space
* that has been set using SetNullSpace().
* If \c false, then one null space component is
* computed using SetupInitialNullSpace().
*
* \param AdditionalCandidates - (In) Number of candidates, that is the
* number of null space components that will be
* computed using IncrementNullSpace(). If
* \c "UseDefaultOrSpecified == false", the code computes
* one additional candidate using
* SetupInitialNullSpace(), and the remaining using
* IncrementNullSpace().
*/
// time is tracked within each method.
// ======================================================================
void AdaptCompute(const bool UseDefaultOrSpecified, int AdditionalCandidates)
{
StackPush();
if (UseDefaultOrSpecified)
Compute();
else {
SetupInitialNullSpace();
Compute();
AdditionalCandidates--;
}
for (int i = 0 ; i < AdditionalCandidates ; ++i) {
IncrementNullSpace();
Compute();
}
StackPop();
}
// ======================================================================
//! Computes the first component of the null space.
// ======================================================================
void SetupInitialNullSpace()
{
ResetTimer();
StackPush();
SetNumPDEEqns(GetInputNumPDEEqns());
if (GetPrintLevel()) {
std::cout << std::endl;
ML_print_line("-", 80);
std::cout << "Computing the first null space component" << std::endl;
}
MultiVector NS(A_[0].GetDomainSpace());
MultiVector NewNS;
for (int v = 0 ; v < NS.GetNumVectors() ; ++v)
NS.Random(v);
NS = (NS + 1.0) / 2.0;
// zero out everything except for first dof on every node
for (int j=0; j < NS.GetMyLength(); ++j)
{
if (j % GetNumPDEEqns() != 0)
NS(j) = 0.;
}
// run pre-smoother
MultiVector F(A(0).GetDomainSpace());
F = 0.0;
S(0).Reshape(A(0), GetSmootherType(), List_);
S(0).Apply(F, NS);
double MyEnergyBefore = sqrt((A(0) * NS) * NS);
if (MyEnergyBefore == 0.0) {
SetNullSpace(NewNS);
return;
}
//compare last two iterates on fine level
int SweepsBefore = List_.get("smoother: sweeps",1);
List_.set("smoother: sweeps",1);
S(0).Reshape(A(0), GetSmootherType(), List_);
S(0).Apply(F, NS);
double MyEnergyAfter = sqrt((A(0) * NS) * NS);
if (MyEnergyAfter/MyEnergyBefore < GetMaxReduction()) {
SetNullSpace(NewNS);
return;
}
List_.set("smoother: sweeps",SweepsBefore);
int level;
for (level = 0 ; level < GetMaxLevels() - 2 ; ++level) {
if (level) SetNumPDEEqns(NS.GetNumVectors());
if (GetPrintLevel()) {
ML_print_line("-", 80);
std::cout << "current working level = " << level << std::endl;
std::cout << "number of global rows = "
<< A(level).GetDomainSpace().GetNumGlobalElements() << std::endl;
std::cout << "number of PDE equations = " << GetNumPDEEqns() << std::endl;
std::cout << "null space dimension = " << NS.GetNumVectors() << std::endl;
}
GetSmoothedP(A(level), List_, NS, P(level), NewNS);
NS = NewNS;
R(level) = GetTranspose(P(level));
A(level + 1) = GetRAP(R(level),A(level),P(level));
S(level + 1).Reshape(A(level + 1),GetSmootherType(),List_);
// break if coarse matrix is below specified size
if (A(level + 1).GetDomainSpace().GetNumGlobalElements() <= GetMaxCoarseSize()) {
++level;
break;
}
MultiVector locF(A(level + 1).GetDomainSpace());
locF = 0.0;
MyEnergyBefore = sqrt((A(level + 1) * NS) * NS);
S(level + 1).Apply(locF, NS);
MyEnergyAfter = sqrt((A(level + 1) * NS) * NS);
if (GetPrintLevel() == 0) {
std::cout << "Energy before smoothing = " << MyEnergyBefore << std::endl;
std::cout << "Energy after smoothing = " << MyEnergyAfter << std::endl;
}
if (pow(MyEnergyAfter/MyEnergyBefore,1.0/SweepsBefore) < GetMaxReduction()) {
++level;
break;
}
}
if (GetPrintLevel())
ML_print_line("-", 80);
// interpolate candidate back to fine level
int MaxLevels = level;
for (int j = MaxLevels ; j > 0 ; --j) {
NS = P(j - 1) * NS;
}
F.Reshape(A(0).GetDomainSpace());
F = 0.0;
S(0).Apply(F, NS);
double norm = NS.NormInf();
NS.Scale(1.0 / norm);
SetNullSpace(NS);
StackPop();
UpdateTime();
}
//! Increments the null space dimension by one.
bool IncrementNullSpace()
{
ResetTimer();
StackPush();
SetNumPDEEqns(GetInputNumPDEEqns());
MultiVector InputNS = GetNullSpace();
if (InputNS.GetNumVectors() == 0)
ML_THROW("Empty null space not allowed", -1);
if (GetPrintLevel()) {
std::cout << std::endl;
ML_print_line("-", 80);
std::cout << "Incrementing the hierarchy, input null space dimension = "
<< InputNS.GetNumVectors() << std::endl;
}
int level;
// =========================================================== //
// InputNS is the currently available (and stored) null space. //
// ExpandedNS is InputNS + AdditionalNS. //
// NCand is dimension of previous nullspace. //
// AdditionalNS is set to random between 0 and 1.0; however, //
// we might need to zero out in the new candidate everybody //
// but the (Ncand+1)'th guy //
// Once the new candidate is set, we run the current V-cycle //
// on it. NOTE: I need the final copy instruction, since the //
// original pointer in AdditionalNS could have been changed //
// under the hood. //
// =========================================================== //
int NCand = InputNS.GetNumVectors();
MultiVector ExpandedNS = InputNS;
ExpandedNS.Append();
MultiVector AdditionalNS = Extract(ExpandedNS, NCand);
AdditionalNS.Random();
AdditionalNS = (AdditionalNS + 1.) / 2.0;
if (NCand+1 <= GetNumPDEEqns())
{
for (int i=0; i< AdditionalNS.GetMyLength(); i++)
if ( (i+1) % (NCand+1) != 0)
AdditionalNS(i) = 0;
}
MultiVector b0(AdditionalNS.GetVectorSpace());
for (int i=0; i< GetNumItersFine() ; i++)
SolveMultiLevelSA(b0,AdditionalNS,0);
double NormFirst = ExpandedNS.NormInf(0);
AdditionalNS.Scale(NormFirst / AdditionalNS.NormInf());
for (int i=0; i<AdditionalNS.GetMyLength(); i++)
ExpandedNS(i,NCand) = AdditionalNS(i);
// ===================== //
// cycle over all levels //
// ===================== //
for (level = 0 ; level < GetMaxLevels() - 2 ; ++level) {
if (GetPrintLevel()) ML_print_line("-", 80);
List_.set("workspace: current level", level);
// ======================================================= //
// Create a new prolongator operator using the newly //
// available null space. NewNS is a temporary variable, //
// set to ExpandedNS for the next-level null space. We //
// also need to setup the smoother at this level (not on //
// the finest, since the finest-level matrix does not //
// change). //
// At this point, we stick the operators in the hierarchy. //
// ======================================================= //
MultiVector NewNS;
GetSmoothedP(A(level), List_, ExpandedNS, P(level), NewNS);
ExpandedNS = NewNS;
R(level) = GetTranspose(P(level));
A(level + 1) = GetRAP(R(level),A(level),P(level));
SetNumPDEEqns(NewNS.GetNumVectors());
if (level != 0)
S(level).Reshape(A(level), GetSmootherType(), List_);
S(level + 1).Reshape(A(level + 1), GetSmootherType(), List_);
// ======================================================= //
// Need to setup the bridge. We need to extract the NCand //
// components of the "old" null space, and set them in a //
// temporary variable, OldNS. NewNS is simply discarded. //
// ======================================================= //
MultiVector OldNS = ExpandedNS;
OldNS.Delete(NCand);
Operator Pbridge;
GetSmoothedP(A(level + 1), List_, OldNS, Pbridge, NewNS);
P(level + 1) = Pbridge;
R(level + 1) = GetTranspose(Pbridge);
AdditionalNS = Duplicate(Extract(ExpandedNS, NCand));
double MyEnergyBefore = sqrt((A(level + 1) * AdditionalNS) * AdditionalNS);
// FIXME scale with something: norm of the matrix, ...;
if (MyEnergyBefore < 1e-10) {
++level;
break;
}
// ======================================================= //
// run Nits_coarse cycles, using AdditionalNS as starting //
// solution, and a zero right hand-side. //
// ======================================================= //
b0.Reshape(AdditionalNS.GetVectorSpace());
b0 = 0.;
for (int i=0; i< GetNumItersCoarse() ; i++)
SolveMultiLevelSA(b0,AdditionalNS,level+1);
// ======================================================= //
// Get the norm of the first null space component, then //
// analyze the energy after the application of the cycle. //
// If the energy after is zero, we have to check whether //
// the new guy is zero or not. //
// Then, we scale the new candidate so that its largest //
// entry is of the same magniture of the largest entry of //
// the first component. //
// ======================================================= //
double NormFirstComponent = ExpandedNS.NormInf(0);
double MyEnergyAfter = sqrt((A(level + 1) * AdditionalNS) * AdditionalNS);
if (MyEnergyAfter == 0.0) {
if (AdditionalNS.NormInf() != 0.0) {
for (int i=0; i<AdditionalNS.GetMyLength(); i++)
ExpandedNS(i,NCand) = AdditionalNS(i);
}
}
else {
for (int i=0; i<AdditionalNS.GetMyLength(); i++) {
ExpandedNS(i,NCand) = AdditionalNS(i);
}
}
double NormExpanded = ExpandedNS.NormInf(NCand);
ExpandedNS.Scale(NormFirstComponent / NormExpanded, NCand);
if (GetPrintLevel() == 0) {
std::cout << "energy before cycle =" << MyEnergyBefore << std::endl;
std::cout << "energy after =" << MyEnergyAfter << std::endl;
}
// FIXME: still to do:
// - scaling of the new computed component
if (pow(MyEnergyAfter/MyEnergyBefore,1.0 / GetNumItersCoarse()) < GetMaxReduction()) {
++level;
break;
}
}
--level;
AdditionalNS = Extract(ExpandedNS, NCand);
// ======================================================= //
// project back to fine level the AdditionalNS vector. //
// Then, reset the number of PDE equations, and finally //
// set the null space of this object using SetNullSpace(). //
// Note that at this point the hierarchy is broken, and //
// must be reconstructed using Compute(). //
// ======================================================= //
// FIXME: put scaling on every level in here?
for (int i=level; i>=0 ; i--) {
AdditionalNS = P(i) * AdditionalNS;
}
InputNS.Append(AdditionalNS);
SetNullSpace(InputNS);
if (GetPrintLevel()) ML_print_line("-", 80);
StackPop();
UpdateTime();
IsComputed_ = false;
return(true);
}
// @}
// @{ \name Mathematical methods
// ======================================================================
//! Applies the preconditioner to \c b_f, returns the result in \c x_f.
// ======================================================================
int Apply(const MultiVector& b_f, MultiVector& x_f) const
{
ResetTimer();
StackPush();
if (IsComputed() == false)
ML_THROW("Method Compute() must be called", -1);
SolveMultiLevelSA(b_f,x_f,0);
StackPop();
UpdateTime();
return(0);
}
// ======================================================================
//! Recursively called core of the multi level preconditioner.
// ======================================================================
int SolveMultiLevelSA(const MultiVector& b_f,MultiVector& x_f, int level) const
{
if (level == GetMaxLevels() - 1) {
x_f = S(level) * b_f;
return(0);
}
MultiVector r_f(P(level).GetRangeSpace());
MultiVector r_c(P(level).GetDomainSpace());
MultiVector z_c(P(level).GetDomainSpace());
// reset flop counter
S(level).SetFlops(0.0);
A(level).SetFlops(0.0);
R(level).SetFlops(0.0);
P(level).SetFlops(0.0);
// apply pre-smoother
S(level).Apply(b_f,x_f);
// new residual
r_f = b_f - A(level) * x_f;
// restrict to coarse
r_c = R(level) * r_f;
// solve coarse problem
SolveMultiLevelSA(r_c,z_c,level + 1);
// prolongate back and add to solution
x_f = x_f + P(level) * z_c;
// apply post-smoother
S(level).Apply(b_f,x_f);
UpdateFlops(2.0 * S(level).GetFlops());
UpdateFlops(A(level).GetFlops());
UpdateFlops(R(level).GetFlops());
UpdateFlops(P(level).GetFlops());
UpdateFlops(2.0 * x_f.GetGlobalLength());
return(0);
}
// @}
// @{ \name Miscellaneous methods
//! Prints basic information about \c this preconditioner.
std::ostream& Print(std::ostream& os,
const bool verbose = true) const
{
if (GetMyPID() == 0) {
os << std::endl;
os << "*** MLAPI::MultiLevelSA, label = `" << GetLabel() << "'" << std::endl;
os << std::endl;
os << "Number of levels = " << GetMaxLevels() << std::endl;
os << "Flop count = " << GetFlops() << std::endl;
os << "Cumulative time = " << GetTime() << std::endl;
if (GetTime() != 0.0)
os << "MFlops rate = " << 1.0e-6 * GetFlops() / GetTime() << std::endl;
else
os << "MFlops rate = 0.0" << std::endl;
os << std::endl;
for (int level = 0 ; level < GetMaxLevels() ; ++level) {
ML_print_line("-", 80);
std::cout << "Information for level = " << level;
std::cout << "number of global rows = "
<< A(level).GetNumGlobalRows() << std::endl;
std::cout << "number of global nnz = "
<< A(level).GetNumGlobalNonzeros() << std::endl;
}
ML_print_line("-", 80);
}
return(os);
}
// @}
private:
//! Returns the smoothed prolongator operator.
void GetSmoothedP(const Operator & Aop, Teuchos::ParameterList& List, MultiVector& NS,
Operator& Pop, MultiVector& NewNS)
{
double LambdaMax;
Operator IminusA;
std::string EigenAnalysis = List.get("eigen-analysis: type", "Anorm");
double Damping = List.get("aggregation: damping", 1.333);
Operator Ptent;
GetPtent(Aop, List, NS, Ptent, NewNS);
if (EigenAnalysis == "Anorm")
LambdaMax = MaxEigAnorm(Aop,true);
else if (EigenAnalysis == "cg")
LambdaMax = MaxEigCG(Aop,true);
else if (EigenAnalysis == "power-method")
LambdaMax = MaxEigPowerMethod(Aop,true);
else
ML_THROW("incorrect parameter (" + EigenAnalysis + ")", -1);
if (GetPrintLevel()) {
std::cout << "omega = " << Damping << std::endl;
std::cout << "lambda max = " << LambdaMax << std::endl;
std::cout << "damping factor = " << Damping / LambdaMax << std::endl;
}
if (Damping != 0.0) {
IminusA = GetJacobiIterationOperator(Aop, Damping / LambdaMax);
Pop = IminusA * Ptent;
}
else
Pop = Ptent;
// fix the number of equations in Pop, so that GetRAP() will
// get the correct number for C= RAP
Pop.GetML_Operator()->num_PDEs = Ptent.GetML_Operator()->num_PDEs;
return;
}
void ResizeArrays(const int MaxLevels)
{
A_.resize(MaxLevels);
R_.resize(MaxLevels);
P_.resize(MaxLevels);
S_.resize(MaxLevels);
}
//! Maximum number of levels.
int MaxLevels_;
//! Fine-level matrix.
Operator FineMatrix_;
//! Contains the hierarchy of operators.
std::vector<Operator> A_;
//! Contains the hierarchy of restriction operators.
std::vector<Operator> R_;
//! Contains the hierarchy of prolongator operators.
std::vector<Operator> P_;
//! Contains the hierarchy of inverse operators.
std::vector<InverseOperator> S_;
Teuchos::ParameterList List_;
//! Contains the current null space
MultiVector NullSpace_;
//! \c true if a hierarchy has been successfully computed.
bool IsComputed_;
//! Number of PDE equations on the finest grid.
int NumPDEEqns_;
}; // class MultiLevelAdaptiveSA
} // namespace MLAPI
#endif
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