/*
QEP routines related to options that can be set via the command-line
or procedurally.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
SLEPc - Scalable Library for Eigenvalue Problem Computations
Copyright (c) 2002-2010, Universidad Politecnica de Valencia, Spain
This file is part of SLEPc.
SLEPc is free software: you can redistribute it and/or modify it under the
terms of version 3 of the GNU Lesser General Public License as published by
the Free Software Foundation.
SLEPc is distributed in the hope that it will be useful, but WITHOUT ANY
WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for
more details.
You should have received a copy of the GNU Lesser General Public License
along with SLEPc. If not, see <http://www.gnu.org/licenses/>.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
*/
#include <private/qepimpl.h> /*I "slepcqep.h" I*/
#undef __FUNCT__
#define __FUNCT__ "QEPSetFromOptions"
/*@
QEPSetFromOptions - Sets QEP options from the options database.
This routine must be called before QEPSetUp() if the user is to be
allowed to set the solver type.
Collective on QEP
Input Parameters:
. qep - the quadratic eigensolver context
Notes:
To see all options, run your program with the -help option.
Level: beginner
@*/
PetscErrorCode QEPSetFromOptions(QEP qep)
{
PetscErrorCode ierr;
char type[256],monfilename[PETSC_MAX_PATH_LEN];
PetscBool flg,val;
PetscReal r;
PetscInt i,j,k;
PetscViewer monviewer;
SlepcConvMonitor ctx;
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
if (!QEPRegisterAllCalled) { ierr = QEPRegisterAll(PETSC_NULL);CHKERRQ(ierr); }
if (!qep->ip) { ierr = QEPGetIP(qep,&qep->ip);CHKERRQ(ierr); }
ierr = PetscOptionsBegin(((PetscObject)qep)->comm,((PetscObject)qep)->prefix,"Quadratic Eigenvalue Problem (QEP) Solver Options","QEP");CHKERRQ(ierr);
ierr = PetscOptionsList("-qep_type","Quadratic Eigenvalue Problem method","QEPSetType",QEPList,(char*)(((PetscObject)qep)->type_name?((PetscObject)qep)->type_name:QEPLINEAR),type,256,&flg);CHKERRQ(ierr);
if (flg) {
ierr = QEPSetType(qep,type);CHKERRQ(ierr);
} else if (!((PetscObject)qep)->type_name) {
ierr = QEPSetType(qep,QEPLINEAR);CHKERRQ(ierr);
}
ierr = PetscOptionsBoolGroupBegin("-qep_general","general quadratic eigenvalue problem","QEPSetProblemType",&flg);CHKERRQ(ierr);
if (flg) {ierr = QEPSetProblemType(qep,QEP_GENERAL);CHKERRQ(ierr);}
ierr = PetscOptionsBoolGroup("-qep_hermitian","hermitian quadratic eigenvalue problem","QEPSetProblemType",&flg);CHKERRQ(ierr);
if (flg) {ierr = QEPSetProblemType(qep,QEP_HERMITIAN);CHKERRQ(ierr);}
ierr = PetscOptionsBoolGroupEnd("-qep_gyroscopic","gyroscopic quadratic eigenvalue problem","QEPSetProblemType",&flg);CHKERRQ(ierr);
if (flg) {ierr = QEPSetProblemType(qep,QEP_GYROSCOPIC);CHKERRQ(ierr);}
r = PETSC_IGNORE;
ierr = PetscOptionsReal("-qep_scale","Scale factor","QEPSetScaleFactor",qep->sfactor,&r,PETSC_NULL);CHKERRQ(ierr);
ierr = QEPSetScaleFactor(qep,r);CHKERRQ(ierr);
r = i = PETSC_IGNORE;
ierr = PetscOptionsInt("-qep_max_it","Maximum number of iterations","QEPSetTolerances",qep->max_it,&i,PETSC_NULL);CHKERRQ(ierr);
ierr = PetscOptionsReal("-qep_tol","Tolerance","QEPSetTolerances",qep->tol,&r,PETSC_NULL);CHKERRQ(ierr);
ierr = QEPSetTolerances(qep,r,i);CHKERRQ(ierr);
ierr = PetscOptionsBoolGroupBegin("-qep_convergence_default","Default (relative error) convergence test","QEPSetConvergenceTest",&flg);CHKERRQ(ierr);
if (flg) {ierr = QEPSetConvergenceTest(qep,QEPDefaultConverged,PETSC_NULL);CHKERRQ(ierr);}
ierr = PetscOptionsBoolGroupEnd("-qep_convergence_absolute","Absolute error convergence test","QEPSetConvergenceTest",&flg);CHKERRQ(ierr);
if (flg) {ierr = QEPSetConvergenceTest(qep,QEPAbsoluteConverged,PETSC_NULL);CHKERRQ(ierr);}
i = j = k = PETSC_IGNORE;
ierr = PetscOptionsInt("-qep_nev","Number of eigenvalues to compute","QEPSetDimensions",qep->nev,&i,PETSC_NULL);CHKERRQ(ierr);
ierr = PetscOptionsInt("-qep_ncv","Number of basis vectors","QEPSetDimensions",qep->ncv,&j,PETSC_NULL);CHKERRQ(ierr);
ierr = PetscOptionsInt("-qep_mpd","Maximum dimension of projected problem","QEPSetDimensions",qep->mpd,&k,PETSC_NULL);CHKERRQ(ierr);
ierr = QEPSetDimensions(qep,i,j,k);CHKERRQ(ierr);
/* -----------------------------------------------------------------------*/
/*
Cancels all monitors hardwired into code before call to QEPSetFromOptions()
*/
flg = PETSC_FALSE;
ierr = PetscOptionsBool("-qep_monitor_cancel","Remove any hardwired monitor routines","QEPMonitorCancel",flg,&flg,PETSC_NULL);CHKERRQ(ierr);
if (flg) {
ierr = QEPMonitorCancel(qep);CHKERRQ(ierr);
}
/*
Prints approximate eigenvalues and error estimates at each iteration
*/
ierr = PetscOptionsString("-qep_monitor","Monitor first unconverged approximate eigenvalue and error estimate","QEPMonitorSet","stdout",monfilename,PETSC_MAX_PATH_LEN,&flg);CHKERRQ(ierr);
if (flg) {
ierr = PetscViewerASCIIOpen(((PetscObject)qep)->comm,monfilename,&monviewer);CHKERRQ(ierr);
ierr = QEPMonitorSet(qep,QEPMonitorFirst,monviewer,(PetscErrorCode (*)(void**))PetscViewerDestroy);CHKERRQ(ierr);
}
ierr = PetscOptionsString("-qep_monitor_conv","Monitor approximate eigenvalues and error estimates as they converge","QEPMonitorSet","stdout",monfilename,PETSC_MAX_PATH_LEN,&flg);CHKERRQ(ierr);
if (flg) {
ierr = PetscNew(struct _n_SlepcConvMonitor,&ctx);CHKERRQ(ierr);
ierr = PetscViewerASCIIOpen(((PetscObject)qep)->comm,monfilename,&ctx->viewer);CHKERRQ(ierr);
ierr = QEPMonitorSet(qep,QEPMonitorConverged,ctx,(PetscErrorCode (*)(void**))SlepcConvMonitorDestroy);CHKERRQ(ierr);
}
ierr = PetscOptionsString("-qep_monitor_all","Monitor approximate eigenvalues and error estimates","QEPMonitorSet","stdout",monfilename,PETSC_MAX_PATH_LEN,&flg);CHKERRQ(ierr);
if (flg) {
ierr = PetscViewerASCIIOpen(((PetscObject)qep)->comm,monfilename,&monviewer);CHKERRQ(ierr);
ierr = QEPMonitorSet(qep,QEPMonitorAll,monviewer,(PetscErrorCode (*)(void**))PetscViewerDestroy);CHKERRQ(ierr);
ierr = QEPSetTrackAll(qep,PETSC_TRUE);CHKERRQ(ierr);
}
flg = PETSC_FALSE;
ierr = PetscOptionsBool("-qep_monitor_draw","Monitor first unconverged approximate error estimate graphically","QEPMonitorSet",flg,&flg,PETSC_NULL);CHKERRQ(ierr);
if (flg) {
ierr = QEPMonitorSet(qep,QEPMonitorLG,PETSC_NULL,PETSC_NULL);CHKERRQ(ierr);
}
flg = PETSC_FALSE;
ierr = PetscOptionsBool("-qep_monitor_draw_all","Monitor error estimates graphically","QEPMonitorSet",flg,&flg,PETSC_NULL);CHKERRQ(ierr);
if (flg) {
ierr = QEPMonitorSet(qep,QEPMonitorLGAll,PETSC_NULL,PETSC_NULL);CHKERRQ(ierr);
ierr = QEPSetTrackAll(qep,PETSC_TRUE);CHKERRQ(ierr);
}
/* -----------------------------------------------------------------------*/
ierr = PetscOptionsBoolGroupBegin("-qep_largest_magnitude","compute largest eigenvalues in magnitude","QEPSetWhichEigenpairs",&flg);CHKERRQ(ierr);
if (flg) {ierr = QEPSetWhichEigenpairs(qep,QEP_LARGEST_MAGNITUDE);CHKERRQ(ierr);}
ierr = PetscOptionsBoolGroup("-qep_smallest_magnitude","compute smallest eigenvalues in magnitude","QEPSetWhichEigenpairs",&flg);CHKERRQ(ierr);
if (flg) {ierr = QEPSetWhichEigenpairs(qep,QEP_SMALLEST_MAGNITUDE);CHKERRQ(ierr);}
ierr = PetscOptionsBoolGroup("-qep_largest_real","compute largest real parts","QEPSetWhichEigenpairs",&flg);CHKERRQ(ierr);
if (flg) {ierr = QEPSetWhichEigenpairs(qep,QEP_LARGEST_REAL);CHKERRQ(ierr);}
ierr = PetscOptionsBoolGroup("-qep_smallest_real","compute smallest real parts","QEPSetWhichEigenpairs",&flg);CHKERRQ(ierr);
if (flg) {ierr = QEPSetWhichEigenpairs(qep,QEP_SMALLEST_REAL);CHKERRQ(ierr);}
ierr = PetscOptionsBoolGroup("-qep_largest_imaginary","compute largest imaginary parts","QEPSetWhichEigenpairs",&flg);CHKERRQ(ierr);
if (flg) {ierr = QEPSetWhichEigenpairs(qep,QEP_LARGEST_IMAGINARY);CHKERRQ(ierr);}
ierr = PetscOptionsBoolGroupEnd("-qep_smallest_imaginary","compute smallest imaginary parts","QEPSetWhichEigenpairs",&flg);CHKERRQ(ierr);
if (flg) {ierr = QEPSetWhichEigenpairs(qep,QEP_SMALLEST_IMAGINARY);CHKERRQ(ierr);}
ierr = PetscOptionsBool("-qep_left_vectors","Compute left eigenvectors also","QEPSetLeftVectorsWanted",qep->leftvecs,&val,&flg);CHKERRQ(ierr);
if (flg) {
ierr = QEPSetLeftVectorsWanted(qep,val);CHKERRQ(ierr);
}
ierr = PetscOptionsName("-qep_view","Print detailed information on solver used","QEPView",0);CHKERRQ(ierr);
ierr = PetscOptionsName("-qep_view_binary","Save the matrices associated to the eigenproblem","QEPSetFromOptions",0);CHKERRQ(ierr);
ierr = PetscOptionsName("-qep_plot_eigs","Make a plot of the computed eigenvalues","QEPSolve",0);CHKERRQ(ierr);
if (qep->ops->setfromoptions) {
ierr = (*qep->ops->setfromoptions)(qep);CHKERRQ(ierr);
}
ierr = PetscObjectProcessOptionsHandlers((PetscObject)qep);CHKERRQ(ierr);
ierr = PetscOptionsEnd();CHKERRQ(ierr);
ierr = IPSetFromOptions(qep->ip);CHKERRQ(ierr);
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPGetTolerances"
/*@
QEPGetTolerances - Gets the tolerance and maximum iteration count used
by the QEP convergence tests.
Not Collective
Input Parameter:
. qep - the quadratic eigensolver context
Output Parameters:
+ tol - the convergence tolerance
- maxits - maximum number of iterations
Notes:
The user can specify PETSC_NULL for any parameter that is not needed.
Level: intermediate
.seealso: QEPSetTolerances()
@*/
PetscErrorCode QEPGetTolerances(QEP qep,PetscReal *tol,PetscInt *maxits)
{
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
if (tol) *tol = qep->tol;
if (maxits) *maxits = qep->max_it;
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPSetTolerances"
/*@
QEPSetTolerances - Sets the tolerance and maximum iteration count used
by the QEP convergence tests.
Logically Collective on QEP
Input Parameters:
+ qep - the quadratic eigensolver context
. tol - the convergence tolerance
- maxits - maximum number of iterations to use
Options Database Keys:
+ -qep_tol <tol> - Sets the convergence tolerance
- -qep_max_it <maxits> - Sets the maximum number of iterations allowed
Notes:
Use PETSC_IGNORE for an argument that need not be changed.
Use PETSC_DECIDE for maxits to assign a reasonably good value, which is
dependent on the solution method.
Level: intermediate
.seealso: QEPGetTolerances()
@*/
PetscErrorCode QEPSetTolerances(QEP qep,PetscReal tol,PetscInt maxits)
{
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
PetscValidLogicalCollectiveReal(qep,tol,2);
PetscValidLogicalCollectiveInt(qep,maxits,3);
if (tol != PETSC_IGNORE) {
if (tol == PETSC_DEFAULT) {
qep->tol = 1e-7;
} else {
if (tol < 0.0) SETERRQ(((PetscObject)qep)->comm,PETSC_ERR_ARG_OUTOFRANGE,"Illegal value of tol. Must be > 0");
qep->tol = tol;
}
}
if (maxits != PETSC_IGNORE) {
if (maxits == PETSC_DEFAULT || maxits == PETSC_DECIDE) {
qep->max_it = 0;
qep->setupcalled = 0;
} else {
if (maxits < 0) SETERRQ(((PetscObject)qep)->comm,PETSC_ERR_ARG_OUTOFRANGE,"Illegal value of maxits. Must be > 0");
qep->max_it = maxits;
}
}
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPGetDimensions"
/*@
QEPGetDimensions - Gets the number of eigenvalues to compute
and the dimension of the subspace.
Not Collective
Input Parameter:
. qep - the quadratic eigensolver context
Output Parameters:
+ nev - number of eigenvalues to compute
. ncv - the maximum dimension of the subspace to be used by the solver
- mpd - the maximum dimension allowed for the projected problem
Notes:
The user can specify PETSC_NULL for any parameter that is not needed.
Level: intermediate
.seealso: QEPSetDimensions()
@*/
PetscErrorCode QEPGetDimensions(QEP qep,PetscInt *nev,PetscInt *ncv,PetscInt *mpd)
{
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
if (nev) *nev = qep->nev;
if (ncv) *ncv = qep->ncv;
if (mpd) *mpd = qep->mpd;
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPSetDimensions"
/*@
QEPSetDimensions - Sets the number of eigenvalues to compute
and the dimension of the subspace.
Logically Collective on QEP
Input Parameters:
+ qep - the quadratic eigensolver context
. nev - number of eigenvalues to compute
. ncv - the maximum dimension of the subspace to be used by the solver
- mpd - the maximum dimension allowed for the projected problem
Options Database Keys:
+ -qep_nev <nev> - Sets the number of eigenvalues
. -qep_ncv <ncv> - Sets the dimension of the subspace
- -qep_mpd <mpd> - Sets the maximum projected dimension
Notes:
Use PETSC_IGNORE to retain the previous value of any parameter.
Use PETSC_DECIDE for ncv and mpd to assign a reasonably good value, which is
dependent on the solution method.
The parameters ncv and mpd are intimately related, so that the user is advised
to set one of them at most. Normal usage is the following:
(a) In cases where nev is small, the user sets ncv (a reasonable default is 2*nev).
(b) In cases where nev is large, the user sets mpd.
The value of ncv should always be between nev and (nev+mpd), typically
ncv=nev+mpd. If nev is not too large, mpd=nev is a reasonable choice, otherwise
a smaller value should be used.
Level: intermediate
.seealso: QEPGetDimensions()
@*/
PetscErrorCode QEPSetDimensions(QEP qep,PetscInt nev,PetscInt ncv,PetscInt mpd)
{
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
PetscValidLogicalCollectiveInt(qep,nev,2);
PetscValidLogicalCollectiveInt(qep,ncv,3);
PetscValidLogicalCollectiveInt(qep,mpd,4);
if (nev != PETSC_IGNORE) {
if (nev<1) SETERRQ(((PetscObject)qep)->comm,PETSC_ERR_ARG_OUTOFRANGE,"Illegal value of nev. Must be > 0");
qep->nev = nev;
qep->setupcalled = 0;
}
if (ncv != PETSC_IGNORE) {
if (ncv == PETSC_DECIDE || ncv == PETSC_DEFAULT) {
qep->ncv = 0;
} else {
if (ncv<1) SETERRQ(((PetscObject)qep)->comm,PETSC_ERR_ARG_OUTOFRANGE,"Illegal value of ncv. Must be > 0");
qep->ncv = ncv;
}
qep->setupcalled = 0;
}
if (mpd != PETSC_IGNORE) {
if (mpd == PETSC_DECIDE || mpd == PETSC_DEFAULT) {
qep->mpd = 0;
} else {
if (mpd<1) SETERRQ(((PetscObject)qep)->comm,PETSC_ERR_ARG_OUTOFRANGE,"Illegal value of mpd. Must be > 0");
qep->mpd = mpd;
}
}
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPSetWhichEigenpairs"
/*@
QEPSetWhichEigenpairs - Specifies which portion of the spectrum is
to be sought.
Logically Collective on QEP
Input Parameters:
+ qep - eigensolver context obtained from QEPCreate()
- which - the portion of the spectrum to be sought
Possible values:
The parameter 'which' can have one of these values
+ QEP_LARGEST_MAGNITUDE - largest eigenvalues in magnitude (default)
. QEP_SMALLEST_MAGNITUDE - smallest eigenvalues in magnitude
. QEP_LARGEST_REAL - largest real parts
. QEP_SMALLEST_REAL - smallest real parts
. QEP_LARGEST_IMAGINARY - largest imaginary parts
- QEP_SMALLEST_IMAGINARY - smallest imaginary parts
Options Database Keys:
+ -qep_largest_magnitude - Sets largest eigenvalues in magnitude
. -qep_smallest_magnitude - Sets smallest eigenvalues in magnitude
. -qep_largest_real - Sets largest real parts
. -qep_smallest_real - Sets smallest real parts
. -qep_largest_imaginary - Sets largest imaginary parts
- -qep_smallest_imaginary - Sets smallest imaginary parts
Notes:
Not all eigensolvers implemented in QEP account for all the possible values
stated above. If SLEPc is compiled for real numbers QEP_LARGEST_IMAGINARY
and QEP_SMALLEST_IMAGINARY use the absolute value of the imaginary part
for eigenvalue selection.
Level: intermediate
.seealso: QEPGetWhichEigenpairs(), QEPWhich
@*/
PetscErrorCode QEPSetWhichEigenpairs(QEP qep,QEPWhich which)
{
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
PetscValidLogicalCollectiveEnum(qep,which,2);
if (which!=PETSC_IGNORE) {
if (which==PETSC_DECIDE || which==PETSC_DEFAULT) qep->which = (QEPWhich)0;
else switch (which) {
case QEP_LARGEST_MAGNITUDE:
case QEP_SMALLEST_MAGNITUDE:
case QEP_LARGEST_REAL:
case QEP_SMALLEST_REAL:
case QEP_LARGEST_IMAGINARY:
case QEP_SMALLEST_IMAGINARY:
if (qep->which != which) {
qep->setupcalled = 0;
qep->which = which;
}
break;
default:
SETERRQ(((PetscObject)qep)->comm,PETSC_ERR_ARG_OUTOFRANGE,"Invalid 'which' value");
}
}
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPGetWhichEigenpairs"
/*@C
QEPGetWhichEigenpairs - Returns which portion of the spectrum is to be
sought.
Not Collective
Input Parameter:
. qep - eigensolver context obtained from QEPCreate()
Output Parameter:
. which - the portion of the spectrum to be sought
Notes:
See QEPSetWhichEigenpairs() for possible values of 'which'.
Level: intermediate
.seealso: QEPSetWhichEigenpairs(), QEPWhich
@*/
PetscErrorCode QEPGetWhichEigenpairs(QEP qep,QEPWhich *which)
{
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
PetscValidPointer(which,2);
*which = qep->which;
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPSetLeftVectorsWanted"
/*@
QEPSetLeftVectorsWanted - Specifies which eigenvectors are required.
Logically Collective on QEP
Input Parameters:
+ qep - the quadratic eigensolver context
- leftvecs - whether left eigenvectors are required or not
Options Database Keys:
. -qep_left_vectors <boolean> - Sets/resets the boolean flag 'leftvecs'
Notes:
If the user sets leftvecs=PETSC_TRUE then the solver uses a variant of
the algorithm that computes both right and left eigenvectors. This is
usually much more costly. This option is not available in all solvers.
Level: intermediate
.seealso: QEPGetLeftVectorsWanted(), QEPGetEigenvectorLeft()
@*/
PetscErrorCode QEPSetLeftVectorsWanted(QEP qep,PetscBool leftvecs)
{
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
PetscValidLogicalCollectiveBool(qep,leftvecs,2);
if (qep->leftvecs != leftvecs) {
qep->leftvecs = leftvecs;
qep->setupcalled = 0;
}
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPGetLeftVectorsWanted"
/*@C
QEPGetLeftVectorsWanted - Returns the flag indicating whether left
eigenvectors are required or not.
Not Collective
Input Parameter:
. qep - the eigensolver context
Output Parameter:
. leftvecs - the returned flag
Level: intermediate
.seealso: QEPSetLeftVectorsWanted()
@*/
PetscErrorCode QEPGetLeftVectorsWanted(QEP qep,PetscBool *leftvecs)
{
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
PetscValidPointer(leftvecs,2);
*leftvecs = qep->leftvecs;
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPGetScaleFactor"
/*@
QEPGetScaleFactor - Gets the factor used for scaling the quadratic eigenproblem.
Not Collective
Input Parameter:
. qep - the quadratic eigensolver context
Output Parameters:
. alpha - the scaling factor
Notes:
If the user did not specify a scaling factor, then after QEPSolve() the
default value is returned.
Level: intermediate
.seealso: QEPSetScaleFactor(), QEPSolve()
@*/
PetscErrorCode QEPGetScaleFactor(QEP qep,PetscReal *alpha)
{
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
PetscValidPointer(alpha,2);
*alpha = qep->sfactor;
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPSetScaleFactor"
/*@
QEPSetScaleFactor - Sets the scaling factor to be used for scaling the
quadratic problem before attempting to solve.
Logically Collective on QEP
Input Parameters:
+ qep - the quadratic eigensolver context
- alpha - the scaling factor
Options Database Keys:
. -qep_scale <alpha> - Sets the scaling factor
Notes:
For the problem (l^2*M + l*C + K)*x = 0, the effect of scaling is to work
with matrices (alpha^2*M, alpha*C, K), then scale the computed eigenvalue.
The default is to scale with alpha = norm(K)/norm(M).
Level: intermediate
.seealso: QEPGetScaleFactor()
@*/
PetscErrorCode QEPSetScaleFactor(QEP qep,PetscReal alpha)
{
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
PetscValidLogicalCollectiveReal(qep,alpha,2);
if (alpha != PETSC_IGNORE) {
if (alpha == PETSC_DEFAULT || alpha == PETSC_DECIDE) {
qep->sfactor = 0.0;
} else {
if (alpha < 0.0) SETERRQ(((PetscObject)qep)->comm,PETSC_ERR_ARG_OUTOFRANGE,"Illegal value of alpha. Must be > 0");
qep->sfactor = alpha;
}
}
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPSetProblemType"
/*@
QEPSetProblemType - Specifies the type of the quadratic eigenvalue problem.
Logically Collective on QEP
Input Parameters:
+ qep - the quadratic eigensolver context
- type - a known type of quadratic eigenvalue problem
Options Database Keys:
+ -qep_general - general problem with no particular structure
. -qep_hermitian - problem whose coefficient matrices are Hermitian
- -qep_gyroscopic - problem with Hamiltonian structure
Notes:
Allowed values for the problem type are: general (QEP_GENERAL), Hermitian
(QEP_HERMITIAN), and gyroscopic (QEP_GYROSCOPIC).
This function is used to instruct SLEPc to exploit certain structure in
the quadratic eigenproblem. By default, no particular structure is assumed.
If the problem matrices are Hermitian (symmetric in the real case) or
Hermitian/skew-Hermitian then the solver can exploit this fact to perform
less operations or provide better stability.
Level: intermediate
.seealso: QEPSetOperators(), QEPSetType(), QEPGetProblemType(), QEPProblemType
@*/
PetscErrorCode QEPSetProblemType(QEP qep,QEPProblemType type)
{
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
PetscValidLogicalCollectiveEnum(qep,type,2);
if (type!=QEP_GENERAL && type!=QEP_HERMITIAN && type!=QEP_GYROSCOPIC)
SETERRQ(((PetscObject)qep)->comm,PETSC_ERR_ARG_WRONG,"Unknown eigenvalue problem type");
qep->problem_type = type;
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPGetProblemType"
/*@C
QEPGetProblemType - Gets the problem type from the QEP object.
Not Collective
Input Parameter:
. qep - the quadratic eigensolver context
Output Parameter:
. type - name of QEP problem type
Level: intermediate
.seealso: QEPSetProblemType(), QEPProblemType
@*/
PetscErrorCode QEPGetProblemType(QEP qep,QEPProblemType *type)
{
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
PetscValidPointer(type,2);
*type = qep->problem_type;
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPSetConvergenceTest"
/*@C
QEPSetConvergenceTest - Sets a function to compute the error estimate used in
the convergence test.
Logically Collective on QEP
Input Parameters:
+ qep - eigensolver context obtained from QEPCreate()
. func - a pointer to the convergence test function
- ctx - a context pointer (the last parameter to the convergence test function)
Calling Sequence of func:
$ func(QEP qep,PetscScalar eigr,PetscScalar eigi,PetscReal res,PetscReal* errest,void *ctx)
+ qep - eigensolver context obtained from QEPCreate()
. eigr - real part of the eigenvalue
. eigi - imaginary part of the eigenvalue
. res - residual norm associated to the eigenpair
. errest - (output) computed error estimate
- ctx - optional context, as set by QEPSetConvergenceTest()
Note:
If the error estimate returned by the convergence test function is less than
the tolerance, then the eigenvalue is accepted as converged.
Level: advanced
.seealso: QEPSetTolerances()
@*/
extern PetscErrorCode QEPSetConvergenceTest(QEP qep,PetscErrorCode (*func)(QEP,PetscScalar,PetscScalar,PetscReal,PetscReal*,void*),void* ctx)
{
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
qep->conv_func = func;
qep->conv_ctx = ctx;
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPSetTrackAll"
/*@
QEPSetTrackAll - Specifies if the solver must compute the residual of all
approximate eigenpairs or not.
Logically Collective on QEP
Input Parameters:
+ qep - the eigensolver context
- trackall - whether compute all residuals or not
Notes:
If the user sets trackall=PETSC_TRUE then the solver explicitly computes
the residual for each eigenpair approximation. Computing the residual is
usually an expensive operation and solvers commonly compute the associated
residual to the first unconverged eigenpair.
The options '-qep_monitor_all' and '-qep_monitor_draw_all' automatically
activates this option.
Level: intermediate
.seealso: QEPGetTrackAll()
@*/
PetscErrorCode QEPSetTrackAll(QEP qep,PetscBool trackall)
{
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
PetscValidLogicalCollectiveBool(qep,trackall,2);
qep->trackall = trackall;
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPGetTrackAll"
/*@
QEPGetTrackAll - Returns the flag indicating whether all residual norms must
be computed or not.
Not Collective
Input Parameter:
. qep - the eigensolver context
Output Parameter:
. trackall - the returned flag
Level: intermediate
.seealso: QEPSetTrackAll()
@*/
PetscErrorCode QEPGetTrackAll(QEP qep,PetscBool *trackall)
{
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
PetscValidPointer(trackall,2);
*trackall = qep->trackall;
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPSetOptionsPrefix"
/*@C
QEPSetOptionsPrefix - Sets the prefix used for searching for all
QEP options in the database.
Logically Collective on QEP
Input Parameters:
+ qep - the quadratic eigensolver context
- prefix - the prefix string to prepend to all QEP option requests
Notes:
A hyphen (-) must NOT be given at the beginning of the prefix name.
The first character of all runtime options is AUTOMATICALLY the
hyphen.
For example, to distinguish between the runtime options for two
different QEP contexts, one could call
.vb
QEPSetOptionsPrefix(qep1,"qeig1_")
QEPSetOptionsPrefix(qep2,"qeig2_")
.ve
Level: advanced
.seealso: QEPAppendOptionsPrefix(), QEPGetOptionsPrefix()
@*/
PetscErrorCode QEPSetOptionsPrefix(QEP qep,const char *prefix)
{
PetscErrorCode ierr;
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
ierr = PetscObjectSetOptionsPrefix((PetscObject)qep,prefix);CHKERRQ(ierr);
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPAppendOptionsPrefix"
/*@C
QEPAppendOptionsPrefix - Appends to the prefix used for searching for all
QEP options in the database.
Logically Collective on QEP
Input Parameters:
+ qep - the quadratic eigensolver context
- prefix - the prefix string to prepend to all QEP option requests
Notes:
A hyphen (-) must NOT be given at the beginning of the prefix name.
The first character of all runtime options is AUTOMATICALLY the hyphen.
Level: advanced
.seealso: QEPSetOptionsPrefix(), QEPGetOptionsPrefix()
@*/
PetscErrorCode QEPAppendOptionsPrefix(QEP qep,const char *prefix)
{
PetscErrorCode ierr;
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
ierr = PetscObjectAppendOptionsPrefix((PetscObject)qep,prefix);CHKERRQ(ierr);
PetscFunctionReturn(0);
}
#undef __FUNCT__
#define __FUNCT__ "QEPGetOptionsPrefix"
/*@C
QEPGetOptionsPrefix - Gets the prefix used for searching for all
QEP options in the database.
Not Collective
Input Parameters:
. qep - the quadratic eigensolver context
Output Parameters:
. prefix - pointer to the prefix string used is returned
Notes: On the fortran side, the user should pass in a string 'prefix' of
sufficient length to hold the prefix.
Level: advanced
.seealso: QEPSetOptionsPrefix(), QEPAppendOptionsPrefix()
@*/
PetscErrorCode QEPGetOptionsPrefix(QEP qep,const char *prefix[])
{
PetscErrorCode ierr;
PetscFunctionBegin;
PetscValidHeaderSpecific(qep,QEP_CLASSID,1);
PetscValidPointer(prefix,2);
ierr = PetscObjectGetOptionsPrefix((PetscObject)qep,prefix);CHKERRQ(ierr);
PetscFunctionReturn(0);
}