Dune Core Modules (2.10.0)

fastamg.hh
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1// SPDX-FileCopyrightText: Copyright © DUNE Project contributors, see file LICENSE.md in module root
2// SPDX-License-Identifier: LicenseRef-GPL-2.0-only-with-DUNE-exception
3// -*- tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*-
4// vi: set et ts=4 sw=2 sts=2:
5#ifndef DUNE_ISTL_FASTAMG_HH
6#define DUNE_ISTL_FASTAMG_HH
7
8#include <memory>
14#include <dune/istl/solvers.hh>
16#include <dune/istl/superlu.hh>
17#include <dune/istl/umfpack.hh>
19#include <dune/istl/io.hh>
21
22#include "fastamgsmoother.hh"
23
32namespace Dune
33{
34 namespace Amg
35 {
58 template<class M, class X, class PI=SequentialInformation, class A=std::allocator<X> >
59 class FastAMG : public Preconditioner<X,X>
60 {
61 public:
63 typedef M Operator;
75
77 typedef X Domain;
79 typedef X Range;
82
90 FastAMG(OperatorHierarchy& matrices, CoarseSolver& coarseSolver,
91 const Parameters& parms,
92 bool symmetric=true);
93
105 template<class C>
106 FastAMG(std::shared_ptr<const Operator> fineOperator,
107 const C& criterion,
108 const Parameters& parms=Parameters(),
109 bool symmetric=true,
111
124 template<class C>
125 FastAMG(const Operator& fineOperator,
126 const C& criterion,
127 const Parameters& parms=Parameters(),
128 bool symmetric=true,
130 : FastAMG(stackobject_to_shared_ptr(fineOperator),
131 criterion, parms, symmetric, pinfo)
132 {}
133
137 FastAMG(const FastAMG& amg);
138
140 void pre(Domain& x, Range& b);
141
143 void apply(Domain& v, const Range& d);
144
147 {
149 }
150
152 void post(Domain& x);
153
158 template<class A1>
159 void getCoarsestAggregateNumbers(std::vector<std::size_t,A1>& cont);
160
161 std::size_t levels();
162
163 std::size_t maxlevels();
164
174 {
175 matrices_->recalculateGalerkin(NegateSet<typename PI::OwnerSet>());
176 }
177
182 bool usesDirectCoarseLevelSolver() const;
183
184 private:
191 template<class C>
192 void createHierarchies(C& criterion,
193 std::shared_ptr<const Operator> fineOperator,
194 const PI& pinfo);
195
202 struct LevelContext
203 {
215 typename OperatorHierarchy::RedistributeInfoList::const_iterator redist;
219 typename OperatorHierarchy::AggregatesMapList::const_iterator aggregates;
235 std::size_t level;
236 };
237
239 void mgc(LevelContext& levelContext, Domain& x, const Range& b);
240
247 void presmooth(LevelContext& levelContext, Domain& x, const Range& b);
248
255 void postsmooth(LevelContext& levelContext, Domain& x, const Range& b);
256
263 void moveToFineLevel(LevelContext& levelContext, bool processedFineLevel,
264 Domain& fineX);
265
270 bool moveToCoarseLevel(LevelContext& levelContext);
271
276 void initIteratorsWithFineLevel(LevelContext& levelContext);
277
279 std::shared_ptr<OperatorHierarchy> matrices_;
281 std::shared_ptr<CoarseSolver> solver_;
283 std::shared_ptr<Hierarchy<Range,A>> rhs_;
285 std::shared_ptr<Hierarchy<Domain,A>> lhs_;
287 std::shared_ptr<Hierarchy<Domain,A>> residual_;
288
292 std::shared_ptr<ScalarProduct> scalarProduct_;
294 std::size_t gamma_;
296 std::size_t preSteps_;
298 std::size_t postSteps_;
299 std::size_t level;
300 bool buildHierarchy_;
301 bool symmetric;
302 bool coarsesolverconverged;
304 typedef std::shared_ptr<Smoother> SmootherPointer;
305 SmootherPointer coarseSmoother_;
307 std::size_t verbosity_;
308 };
309
310 template<class M, class X, class PI, class A>
312 : matrices_(amg.matrices_), solver_(amg.solver_),
313 rhs_(), lhs_(), residual_(), scalarProduct_(amg.scalarProduct_),
314 gamma_(amg.gamma_), preSteps_(amg.preSteps_), postSteps_(amg.postSteps_),
315 symmetric(amg.symmetric), coarsesolverconverged(amg.coarsesolverconverged),
316 coarseSmoother_(amg.coarseSmoother_), verbosity_(amg.verbosity_)
317 {}
318
319 template<class M, class X, class PI, class A>
321 const Parameters& parms, bool symmetric_)
322 : matrices_(stackobject_to_shared_ptr(matrices)), solver_(&coarseSolver),
323 rhs_(), lhs_(), residual_(), scalarProduct_(),
324 gamma_(parms.getGamma()), preSteps_(parms.getNoPreSmoothSteps()),
325 postSteps_(parms.getNoPostSmoothSteps()), buildHierarchy_(false),
326 symmetric(symmetric_), coarsesolverconverged(true),
327 coarseSmoother_(), verbosity_(parms.debugLevel())
328 {
329 if(preSteps_>1||postSteps_>1)
330 {
331 std::cerr<<"WARNING only one step of smoothing is supported!"<<std::endl;
332 preSteps_=postSteps_=0;
333 }
334 assert(matrices_->isBuilt());
335 static_assert(std::is_same<PI,SequentialInformation>::value,
336 "Currently only sequential runs are supported");
337 }
338 template<class M, class X, class PI, class A>
339 template<class C>
340 FastAMG<M,X,PI,A>::FastAMG(std::shared_ptr<const Operator> fineOperator,
341 const C& criterion,
342 const Parameters& parms,
343 bool symmetric_,
344 const PI& pinfo)
345 : solver_(), rhs_(), lhs_(), residual_(), scalarProduct_(), gamma_(parms.getGamma()),
346 preSteps_(parms.getNoPreSmoothSteps()), postSteps_(parms.getNoPostSmoothSteps()),
347 buildHierarchy_(true),
348 symmetric(symmetric_), coarsesolverconverged(true),
349 coarseSmoother_(), verbosity_(criterion.debugLevel())
350 {
351 if(preSteps_>1||postSteps_>1)
352 {
353 std::cerr<<"WARNING only one step of smoothing is supported!"<<std::endl;
354 preSteps_=postSteps_=1;
355 }
356 static_assert(std::is_same<PI,SequentialInformation>::value,
357 "Currently only sequential runs are supported");
358 // TODO: reestablish compile time checks.
359 //static_assert(static_cast<int>(PI::category)==static_cast<int>(S::category),
360 // "Matrix and Solver must match in terms of category!");
361 createHierarchies(criterion, std::move(fineOperator), pinfo);
362 }
363
364 template<class M, class X, class PI, class A>
365 template<class C>
366 void FastAMG<M,X,PI,A>::createHierarchies(C& criterion,
367 std::shared_ptr<const Operator> fineOperator,
368 const PI& pinfo)
369 {
370 Timer watch;
371 matrices_ = std::make_shared<OperatorHierarchy>(
372 std::const_pointer_cast<Operator>(std::move(fineOperator)),
373 stackobject_to_shared_ptr(const_cast<PI&>(pinfo)));
374
375 matrices_->template build<NegateSet<typename PI::OwnerSet> >(criterion);
376
377 if(verbosity_>0 && matrices_->parallelInformation().finest()->communicator().rank()==0)
378 std::cout<<"Building Hierarchy of "<<matrices_->maxlevels()<<" levels took "<<watch.elapsed()<<" seconds."<<std::endl;
379
380 if(buildHierarchy_ && matrices_->levels()==matrices_->maxlevels()) {
381 // We have the carsest level. Create the coarse Solver
382 typedef typename SmootherTraits<Smoother>::Arguments SmootherArgs;
383 SmootherArgs sargs;
384 sargs.iterations = 1;
385
387 cargs.setArgs(sargs);
388 if(matrices_->redistributeInformation().back().isSetup()) {
389 // Solve on the redistributed partitioning
390 cargs.setMatrix(matrices_->matrices().coarsest().getRedistributed().getmat());
391 cargs.setComm(matrices_->parallelInformation().coarsest().getRedistributed());
392 }else{
393 cargs.setMatrix(matrices_->matrices().coarsest()->getmat());
394 cargs.setComm(*matrices_->parallelInformation().coarsest());
395 }
396
397 coarseSmoother_ = ConstructionTraits<Smoother>::construct(cargs);
398 scalarProduct_ = createScalarProduct<X>(cargs.getComm(),category());
399
400#if HAVE_SUPERLU|| HAVE_SUITESPARSE_UMFPACK
401#if HAVE_SUITESPARSE_UMFPACK
402#define DIRECTSOLVER UMFPack
403#else
404#define DIRECTSOLVER SuperLU
405#endif
406 // Use superlu if we are purely sequential or with only one processor on the coarsest level.
407 if(std::is_same<ParallelInformation,SequentialInformation>::value // sequential mode
408 || matrices_->parallelInformation().coarsest()->communicator().size()==1 //parallel mode and only one processor
409 || (matrices_->parallelInformation().coarsest().isRedistributed()
410 && matrices_->parallelInformation().coarsest().getRedistributed().communicator().size()==1
411 && matrices_->parallelInformation().coarsest().getRedistributed().communicator().size()>0)) { // redistribute and 1 proc
412 if(verbosity_>0 && matrices_->parallelInformation().coarsest()->communicator().rank()==0)
413 std::cout<<"Using superlu"<<std::endl;
414 if(matrices_->parallelInformation().coarsest().isRedistributed())
415 {
416 if(matrices_->matrices().coarsest().getRedistributed().getmat().N()>0)
417 // We are still participating on this level
418 solver_.reset(new DIRECTSOLVER<typename M::matrix_type>(matrices_->matrices().coarsest().getRedistributed().getmat(), false, false));
419 else
420 solver_.reset();
421 }else
422 solver_.reset(new DIRECTSOLVER<typename M::matrix_type>(matrices_->matrices().coarsest()->getmat(), false, false));
423 }else
424#undef DIRECTSOLVER
425#endif // HAVE_SUPERLU|| HAVE_SUITESPARSE_UMFPACK
426 {
427 if(matrices_->parallelInformation().coarsest().isRedistributed())
428 {
429 if(matrices_->matrices().coarsest().getRedistributed().getmat().N()>0)
430 // We are still participating on this level
431 solver_.reset(new BiCGSTABSolver<X>(const_cast<M&>(matrices_->matrices().coarsest().getRedistributed()),
432 *scalarProduct_,
433 *coarseSmoother_, 1E-2, 1000, 0));
434 else
435 solver_.reset();
436 }else
437 solver_.reset(new BiCGSTABSolver<X>(const_cast<M&>(*matrices_->matrices().coarsest()),
438 *scalarProduct_,
439 *coarseSmoother_, 1E-2, 1000, 0));
440 }
441 }
442
443 if(verbosity_>0 && matrices_->parallelInformation().finest()->communicator().rank()==0)
444 std::cout<<"Building Hierarchy of "<<matrices_->maxlevels()<<" levels took "<<watch.elapsed()<<" seconds."<<std::endl;
445 }
446
447
448 template<class M, class X, class PI, class A>
450 {
451 Timer watch, watch1;
452 // Detect Matrix rows where all offdiagonal entries are
453 // zero and set x such that A_dd*x_d=b_d
454 // Thus users can be more careless when setting up their linear
455 // systems.
456 typedef typename M::matrix_type Matrix;
457 typedef typename Matrix::ConstRowIterator RowIter;
458 typedef typename Matrix::ConstColIterator ColIter;
459 typedef typename Matrix::block_type Block;
460 Block zero;
461 zero=typename Matrix::field_type();
462
463 const Matrix& mat=matrices_->matrices().finest()->getmat();
464 for(RowIter row=mat.begin(); row!=mat.end(); ++row) {
465 bool isDirichlet = true;
466 bool hasDiagonal = false;
467 ColIter diag;
468 for(ColIter col=row->begin(); col!=row->end(); ++col) {
469 if(row.index()==col.index()) {
470 diag = col;
471 hasDiagonal = (*col != zero);
472 }else{
473 if(*col!=zero)
474 isDirichlet = false;
475 }
476 }
477 if(isDirichlet && hasDiagonal)
478 diag->solve(x[row.index()], b[row.index()]);
479 }
480 if (verbosity_>0)
481 std::cout<<" Preprocessing Dirichlet took "<<watch1.elapsed()<<std::endl;
482 watch1.reset();
483 // No smoother to make x consistent! Do it by hand
484 matrices_->parallelInformation().coarsest()->copyOwnerToAll(x,x);
485 rhs_ = std::make_shared<Hierarchy<Range,A>>(std::make_shared<Range>(b));
486 lhs_ = std::make_shared<Hierarchy<Domain,A>>(std::make_shared<Domain>(x));
487 residual_ = std::make_shared<Hierarchy<Domain,A>>(std::make_shared<Domain>(x));
488 matrices_->coarsenVector(*rhs_);
489 matrices_->coarsenVector(*lhs_);
490 matrices_->coarsenVector(*residual_);
491
492 // The preconditioner might change x and b. So we have to
493 // copy the changes to the original vectors.
494 x = *lhs_->finest();
495 b = *rhs_->finest();
496 }
497 template<class M, class X, class PI, class A>
498 std::size_t FastAMG<M,X,PI,A>::levels()
499 {
500 return matrices_->levels();
501 }
502 template<class M, class X, class PI, class A>
503 std::size_t FastAMG<M,X,PI,A>::maxlevels()
504 {
505 return matrices_->maxlevels();
506 }
507
509 template<class M, class X, class PI, class A>
511 {
512 LevelContext levelContext;
513 // Init all iterators for the current level
514 initIteratorsWithFineLevel(levelContext);
515
516 assert(v.two_norm()==0);
517
518 level=0;
519 if(matrices_->maxlevels()==1){
520 // The coarse solver might modify the d!
521 Range b(d);
522 mgc(levelContext, v, b);
523 }else
524 mgc(levelContext, v, d);
525 if(postSteps_==0||matrices_->maxlevels()==1)
526 levelContext.pinfo->copyOwnerToAll(v, v);
527 }
528
529 template<class M, class X, class PI, class A>
530 void FastAMG<M,X,PI,A>::initIteratorsWithFineLevel(LevelContext& levelContext)
531 {
532 levelContext.matrix = matrices_->matrices().finest();
533 levelContext.pinfo = matrices_->parallelInformation().finest();
534 levelContext.redist =
535 matrices_->redistributeInformation().begin();
536 levelContext.aggregates = matrices_->aggregatesMaps().begin();
537 levelContext.lhs = lhs_->finest();
538 levelContext.residual = residual_->finest();
539 levelContext.rhs = rhs_->finest();
540 levelContext.level=0;
541 }
542
543 template<class M, class X, class PI, class A>
544 bool FastAMG<M,X,PI,A>
545 ::moveToCoarseLevel(LevelContext& levelContext)
546 {
547 bool processNextLevel=true;
548
549 if(levelContext.redist->isSetup()) {
550 throw "bla";
551 levelContext.redist->redistribute(static_cast<const Range&>(*levelContext.residual),
552 levelContext.residual.getRedistributed());
553 processNextLevel = levelContext.residual.getRedistributed().size()>0;
554 if(processNextLevel) {
555 //restrict defect to coarse level right hand side.
556 ++levelContext.pinfo;
557 Transfer<typename OperatorHierarchy::AggregatesMap::AggregateDescriptor,Range,ParallelInformation>
558 ::restrictVector(*(*levelContext.aggregates), *levelContext.rhs,
559 static_cast<const Range&>(levelContext.residual.getRedistributed()),
560 *levelContext.pinfo);
561 }
562 }else{
563 //restrict defect to coarse level right hand side.
564 ++levelContext.rhs;
565 ++levelContext.pinfo;
566 Transfer<typename OperatorHierarchy::AggregatesMap::AggregateDescriptor,Range,ParallelInformation>
567 ::restrictVector(*(*levelContext.aggregates), *levelContext.rhs,
568 static_cast<const Range&>(*levelContext.residual), *levelContext.pinfo);
569 }
570
571 if(processNextLevel) {
572 // prepare coarse system
573 ++levelContext.residual;
574 ++levelContext.lhs;
575 ++levelContext.matrix;
576 ++levelContext.level;
577 ++levelContext.redist;
578
579 if(levelContext.matrix != matrices_->matrices().coarsest() || matrices_->levels()<matrices_->maxlevels()) {
580 // next level is not the globally coarsest one
581 ++levelContext.aggregates;
582 }
583 // prepare the lhs on the next level
584 *levelContext.lhs=0;
585 *levelContext.residual=0;
586 }
587 return processNextLevel;
588 }
589
590 template<class M, class X, class PI, class A>
591 void FastAMG<M,X,PI,A>
592 ::moveToFineLevel(LevelContext& levelContext, bool processNextLevel, Domain& x)
593 {
594 if(processNextLevel) {
595 if(levelContext.matrix != matrices_->matrices().coarsest() || matrices_->levels()<matrices_->maxlevels()) {
596 // previous level is not the globally coarsest one
597 --levelContext.aggregates;
598 }
599 --levelContext.redist;
600 --levelContext.level;
601 //prolongate and add the correction (update is in coarse left hand side)
602 --levelContext.matrix;
603 --levelContext.residual;
604
605 }
606
607 typename Hierarchy<Domain,A>::Iterator coarseLhs = levelContext.lhs--;
608 if(levelContext.redist->isSetup()) {
609
610 // Need to redistribute during prolongate
611 Transfer<typename OperatorHierarchy::AggregatesMap::AggregateDescriptor,Range,ParallelInformation>
612 ::prolongateVector(*(*levelContext.aggregates), *coarseLhs, x,
613 levelContext.lhs.getRedistributed(),
614 matrices_->getProlongationDampingFactor(),
615 *levelContext.pinfo, *levelContext.redist);
616 }else{
617 Transfer<typename OperatorHierarchy::AggregatesMap::AggregateDescriptor,Range,ParallelInformation>
618 ::prolongateVector(*(*levelContext.aggregates), *coarseLhs, x,
619 matrices_->getProlongationDampingFactor(), *levelContext.pinfo);
620
621 // printvector(std::cout, *lhs, "prolongated coarse grid correction", "lhs", 10, 10, 10);
622 }
623
624
625 if(processNextLevel) {
626 --levelContext.rhs;
627 }
628
629 }
630
631
632 template<class M, class X, class PI, class A>
633 void FastAMG<M,X,PI,A>
634 ::presmooth(LevelContext& levelContext, Domain& x, const Range& b)
635 {
636 constexpr auto bl = blockLevel<typename M::matrix_type>();
637 GaussSeidelPresmoothDefect<bl>::apply(levelContext.matrix->getmat(),
638 x,
639 *levelContext.residual,
640 b);
641 }
642
643 template<class M, class X, class PI, class A>
644 void FastAMG<M,X,PI,A>
645 ::postsmooth(LevelContext& levelContext, Domain& x, const Range& b)
646 {
647 constexpr auto bl = blockLevel<typename M::matrix_type>();
648 GaussSeidelPostsmoothDefect<bl>
649 ::apply(levelContext.matrix->getmat(), x, *levelContext.residual, b);
650 }
651
652
653 template<class M, class X, class PI, class A>
655 {
656 return IsDirectSolver< CoarseSolver>::value;
657 }
658
659 template<class M, class X, class PI, class A>
660 void FastAMG<M,X,PI,A>::mgc(LevelContext& levelContext, Domain& v, const Range& b){
661
662 if(levelContext.matrix == matrices_->matrices().coarsest() && levels()==maxlevels()) {
663 // Solve directly
665 res.converged=true; // If we do not compute this flag will not get updated
666 if(levelContext.redist->isSetup()) {
667 levelContext.redist->redistribute(b, levelContext.rhs.getRedistributed());
668 if(levelContext.rhs.getRedistributed().size()>0) {
669 // We are still participating in the computation
670 levelContext.pinfo.getRedistributed().copyOwnerToAll(levelContext.rhs.getRedistributed(),
671 levelContext.rhs.getRedistributed());
672 solver_->apply(levelContext.lhs.getRedistributed(), levelContext.rhs.getRedistributed(), res);
673 }
674 levelContext.redist->redistributeBackward(v, levelContext.lhs.getRedistributed());
675 levelContext.pinfo->copyOwnerToAll(v, v);
676 }else{
677 levelContext.pinfo->copyOwnerToAll(b, b);
678 solver_->apply(v, const_cast<Range&>(b), res);
679 }
680
681 // printvector(std::cout, *lhs, "coarse level update", "u", 10, 10, 10);
682 // printvector(std::cout, *rhs, "coarse level rhs", "rhs", 10, 10, 10);
683 if (!res.converged)
684 coarsesolverconverged = false;
685 }else{
686 // presmoothing
687 presmooth(levelContext, v, b);
688 // printvector(std::cout, *lhs, "update", "u", 10, 10, 10);
689 // printvector(std::cout, *residual, "post presmooth residual", "r", 10);
690#ifndef DUNE_AMG_NO_COARSEGRIDCORRECTION
691 bool processNextLevel = moveToCoarseLevel(levelContext);
692
693 if(processNextLevel) {
694 // next level
695 for(std::size_t i=0; i<gamma_; i++)
696 mgc(levelContext, *levelContext.lhs, *levelContext.rhs);
697 }
698
699 moveToFineLevel(levelContext, processNextLevel, v);
700#else
701 *lhs=0;
702#endif
703
704 if(levelContext.matrix == matrices_->matrices().finest()) {
705 coarsesolverconverged = matrices_->parallelInformation().finest()->communicator().prod(coarsesolverconverged);
706 if(!coarsesolverconverged)
707 DUNE_THROW(MathError, "Coarse solver did not converge");
708 }
709
710 postsmooth(levelContext, v, b);
711 }
712 }
713
714
716 template<class M, class X, class PI, class A>
717 void FastAMG<M,X,PI,A>::post([[maybe_unused]] Domain& x)
718 {
719 lhs_=nullptr;
720 rhs_=nullptr;
721 residual_=nullptr;
722 }
723
724 template<class M, class X, class PI, class A>
725 template<class A1>
726 void FastAMG<M,X,PI,A>::getCoarsestAggregateNumbers(std::vector<std::size_t,A1>& cont)
727 {
728 matrices_->getCoarsestAggregatesOnFinest(cont);
729 }
730
731 } // end namespace Amg
732} // end namespace Dune
733
734#endif
A fast (sequential) algebraic multigrid based on agglomeration that saves memory bandwidth.
Definition: fastamg.hh:60
LevelIterator< Hierarchy< ParallelInformation, Allocator >, ParallelInformation > Iterator
Type of the mutable iterator.
Definition: hierarchy.hh:216
LevelIterator< const Hierarchy< MatrixOperator, Allocator >, const MatrixOperator > ConstIterator
Type of the const iterator.
Definition: hierarchy.hh:219
The hierarchies build by the coarsening process.
Definition: matrixhierarchy.hh:61
All parameters for AMG.
Definition: parameters.hh:416
ConstIterator class for sequential access.
Definition: matrix.hh:404
A generic dynamic dense matrix.
Definition: matrix.hh:561
typename Imp::BlockTraits< T >::field_type field_type
Export the type representing the underlying field.
Definition: matrix.hh:565
row_type::const_iterator ConstColIterator
Const iterator for the entries of each row.
Definition: matrix.hh:589
T block_type
Export the type representing the components.
Definition: matrix.hh:568
The negation of a set. An item is contained in the set if and only if it is not contained in the nega...
Definition: enumset.hh:96
Base class for matrix free definition of preconditioners.
Definition: preconditioner.hh:33
Base class for scalar product and norm computation.
Definition: scalarproducts.hh:52
Sequential SSOR preconditioner.
Definition: preconditioners.hh:142
A simple stop watch.
Definition: timer.hh:43
void reset() noexcept
Reset timer while keeping the running/stopped state.
Definition: timer.hh:57
double elapsed() const noexcept
Get elapsed user-time from last reset until now/last stop in seconds.
Definition: timer.hh:77
A few common exception classes.
Traits for type conversions and type information.
Some generic functions for pretty printing vectors and matrices.
#define DUNE_THROW(E, m)
Definition: exceptions.hh:218
OperatorHierarchy::ParallelMatrixHierarchy::ConstIterator matrix
The iterator over the matrices.
Definition: fastamg.hh:207
void getCoarsestAggregateNumbers(std::vector< std::size_t, A1 > &cont)
Get the aggregate number of each unknown on the coarsest level.
Definition: fastamg.hh:726
ParallelInformationHierarchy::Iterator pinfo
The iterator over the parallel information.
Definition: fastamg.hh:211
void recalculateHierarchy()
Recalculate the matrix hierarchy.
Definition: fastamg.hh:173
void post(Domain &x)
Clean up.
Definition: fastamg.hh:717
X Domain
The domain type.
Definition: fastamg.hh:77
Hierarchy< Domain, A >::Iterator residual
The iterator over the residuals.
Definition: fastamg.hh:227
virtual SolverCategory::Category category() const
Category of the preconditioner (see SolverCategory::Category)
Definition: fastamg.hh:146
MatrixHierarchy< M, ParallelInformation, A > OperatorHierarchy
The operator hierarchy type.
Definition: fastamg.hh:72
OperatorHierarchy::RedistributeInfoList::const_iterator redist
The iterator over the redistribution information.
Definition: fastamg.hh:215
X Range
The range type.
Definition: fastamg.hh:79
PI ParallelInformation
The type of the parallel information. Either OwnerOverlapCommunication or another type describing the...
Definition: fastamg.hh:70
M Operator
The matrix operator type.
Definition: fastamg.hh:63
FastAMG(const Operator &fineOperator, const C &criterion, const Parameters &parms=Parameters(), bool symmetric=true, const ParallelInformation &pinfo=ParallelInformation())
Construct an AMG with an inexact coarse solver based on the smoother.
Definition: fastamg.hh:125
InverseOperator< X, X > CoarseSolver
the type of the coarse solver.
Definition: fastamg.hh:81
bool usesDirectCoarseLevelSolver() const
Check whether the coarse solver used is a direct solver.
Definition: fastamg.hh:654
Hierarchy< Domain, A >::Iterator lhs
The iterator over the left hand side.
Definition: fastamg.hh:223
Hierarchy< Range, A >::Iterator rhs
The iterator over the right hand sided.
Definition: fastamg.hh:231
std::size_t level
The level index.
Definition: fastamg.hh:235
void apply(Domain &v, const Range &d)
Apply one step of the preconditioner to the system A(v)=d.
Definition: fastamg.hh:510
OperatorHierarchy::ParallelInformationHierarchy ParallelInformationHierarchy
The parallal data distribution hierarchy type.
Definition: fastamg.hh:74
void pre(Domain &x, Range &b)
Prepare the preconditioner.
Definition: fastamg.hh:449
FastAMG(OperatorHierarchy &matrices, CoarseSolver &coarseSolver, const Parameters &parms, bool symmetric=true)
Construct a new amg with a specific coarse solver.
Definition: fastamg.hh:320
OperatorHierarchy::AggregatesMapList::const_iterator aggregates
The iterator over the aggregates maps.
Definition: fastamg.hh:219
void presmooth(LevelContext &levelContext, size_t steps)
Apply pre smoothing on the current level.
Definition: smoother.hh:406
const void * Arguments
A type holding all the arguments needed to call the constructor.
Definition: construction.hh:44
static std::shared_ptr< T > construct(Arguments &args)
Construct an object with the specified arguments.
Definition: construction.hh:52
void postsmooth(LevelContext &levelContext, size_t steps)
Apply post smoothing on the current level.
Definition: smoother.hh:428
Provides a classes representing the hierarchies in AMG.
Dune namespace.
Definition: alignedallocator.hh:13
std::shared_ptr< T > stackobject_to_shared_ptr(T &t)
Create a shared_ptr for a stack-allocated object.
Definition: shared_ptr.hh:72
Define general preconditioner interface.
Define base class for scalar product and norm.
Classes for the generic construction and application of the smoothers.
Implementations of the inverse operator interface.
Templates characterizing the type of a solver.
Traits class for getting the attribute class of a smoother.
Definition: smoother.hh:66
Statistics about the application of an inverse operator.
Definition: solver.hh:50
bool converged
True if convergence criterion has been met.
Definition: solver.hh:75
Category
Definition: solvercategory.hh:23
@ sequential
Category for sequential solvers.
Definition: solvercategory.hh:25
Classes for using SuperLU with ISTL matrices.
Prolongation and restriction for amg.
Classes for using UMFPack with ISTL matrices.
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