/usr/include/trilinos/Stokhos_GMRESDivisionExpansionStrategy.hpp is in libtrilinos-stokhos-dev 12.10.1-3.
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#ifndef STOKHOS_GMRES_DIVISION_EXPANSION_STRATEGY_HPP
#define STOKHOS_GMRES_DIVISION_EXPANSION_STRATEGY_HPP
#include "Stokhos_DivisionExpansionStrategy.hpp"
#include "Stokhos_OrthogPolyBasis.hpp"
#include "Stokhos_Sparse3Tensor.hpp"
#include "Stokhos_DiagPreconditioner.hpp"
#include "Stokhos_JacobiPreconditioner.hpp"
#include "Stokhos_GSPreconditioner.hpp"
#include "Stokhos_SchurPreconditioner.hpp"
#include "Stokhos_BlockPreconditioner.hpp"
#include "Teuchos_TimeMonitor.hpp"
#include "Teuchos_RCP.hpp"
#include "Teuchos_SerialDenseMatrix.hpp"
#include "Teuchos_BLAS.hpp"
#include "Teuchos_LAPACK.hpp"
namespace Stokhos {
//! Strategy interface for computing PCE of a/b using only b[0]
/*!
* Such a strategy is only useful when the division occurs in a preconditioner
*/
template <typename ordinal_type, typename value_type, typename node_type>
class GMRESDivisionExpansionStrategy :
public DivisionExpansionStrategy<ordinal_type,value_type,node_type> {
public:
//! Constructor
GMRESDivisionExpansionStrategy(
const Teuchos::RCP<const Stokhos::OrthogPolyBasis<ordinal_type, value_type> >& basis_,
const Teuchos::RCP<const Stokhos::Sparse3Tensor<ordinal_type, value_type> >& Cijk_,
const ordinal_type prec_iter_,
const value_type tol_,
const ordinal_type PrecNum_,
const ordinal_type max_it_,
const ordinal_type linear_,
const ordinal_type diag_,
const ordinal_type equil_);
//! Destructor
virtual ~GMRESDivisionExpansionStrategy() {}
// Division operation: c = \alpha*(a/b) + beta*c
virtual void divide(
Stokhos::OrthogPolyApprox<ordinal_type, value_type, node_type>& c,
const value_type& alpha,
const Stokhos::OrthogPolyApprox<ordinal_type, value_type, node_type>& a,
const Stokhos::OrthogPolyApprox<ordinal_type, value_type, node_type>& b,
const value_type& beta);
private:
// Prohibit copying
GMRESDivisionExpansionStrategy(
const GMRESDivisionExpansionStrategy&);
// Prohibit Assignment
GMRESDivisionExpansionStrategy& operator=(
const GMRESDivisionExpansionStrategy& b);
ordinal_type GMRES(
const Teuchos::SerialDenseMatrix<ordinal_type, value_type> & A,
Teuchos::SerialDenseMatrix<ordinal_type,value_type> & X,
const Teuchos::SerialDenseMatrix<ordinal_type,value_type> & B,
ordinal_type max_iter,
value_type tolerance,
ordinal_type prec_iter,
ordinal_type order,
ordinal_type dim,
ordinal_type PrecNum,
const Teuchos::SerialDenseMatrix<ordinal_type, value_type>& M,
ordinal_type diag);
protected:
//! Basis
Teuchos::RCP<const Stokhos::OrthogPolyBasis<ordinal_type, value_type> > basis;
//! Short-hand for Cijk
typedef Stokhos::Sparse3Tensor<ordinal_type, value_type> Cijk_type;
//! Triple product
Teuchos::RCP<const Cijk_type> Cijk;
//! Dense matrices for linear system
Teuchos::RCP< Teuchos::SerialDenseMatrix<ordinal_type,value_type> > A, X, B, M;
//! Tolerance for GMRES
ordinal_type prec_iter;
value_type tol;
ordinal_type PrecNum;
ordinal_type max_it;
ordinal_type linear;
ordinal_type diag;
ordinal_type equil;
}; // class GMRESDivisionExpansionStrategy
} // namespace Stokhos
template <typename ordinal_type, typename value_type, typename node_type>
Stokhos::GMRESDivisionExpansionStrategy<ordinal_type,value_type,node_type>::
GMRESDivisionExpansionStrategy(
const Teuchos::RCP<const Stokhos::OrthogPolyBasis<ordinal_type, value_type> >& basis_,
const Teuchos::RCP<const Stokhos::Sparse3Tensor<ordinal_type, value_type> >& Cijk_,
const ordinal_type prec_iter_,
const value_type tol_,
const ordinal_type PrecNum_,
const ordinal_type max_it_,
const ordinal_type linear_,
const ordinal_type diag_,
const ordinal_type equil_):
basis(basis_),
Cijk(Cijk_),
prec_iter(prec_iter_),
tol(tol_),
PrecNum(PrecNum_),
max_it(max_it_),
linear(linear_),
diag(diag_),
equil(equil_)
{
ordinal_type sz = basis->size();
A = Teuchos::rcp(new Teuchos::SerialDenseMatrix<ordinal_type,value_type>(
sz, sz));
B = Teuchos::rcp(new Teuchos::SerialDenseMatrix<ordinal_type,value_type>(
sz, 1));
X = Teuchos::rcp(new Teuchos::SerialDenseMatrix<ordinal_type,value_type>(
sz, 1));
M = Teuchos::rcp(new Teuchos::SerialDenseMatrix<ordinal_type,value_type>(
sz, sz));
}
template <typename ordinal_type, typename value_type, typename node_type>
void
Stokhos::GMRESDivisionExpansionStrategy<ordinal_type,value_type,node_type>::
divide(Stokhos::OrthogPolyApprox<ordinal_type, value_type, node_type>& c,
const value_type& alpha,
const Stokhos::OrthogPolyApprox<ordinal_type, value_type, node_type>& a,
const Stokhos::OrthogPolyApprox<ordinal_type, value_type, node_type>& b,
const value_type& beta)
{
#ifdef STOKHOS_TEUCHOS_TIME_MONITOR
TEUCHOS_FUNC_TIME_MONITOR("Stokhos::GMRESDivisionStrategy::divide()");
#endif
ordinal_type sz = basis->size();
ordinal_type pa = a.size();
ordinal_type pb = b.size();
ordinal_type pc;
if (pb > 1)
pc = sz;
else
pc = pa;
if (c.size() != pc)
c.resize(pc);
const value_type* ca = a.coeff();
const value_type* cb = b.coeff();
value_type* cc = c.coeff();
if (pb > 1) {
// Compute A
A->putScalar(0.0);
typename Cijk_type::k_iterator k_begin = Cijk->k_begin();
typename Cijk_type::k_iterator k_end = Cijk->k_end();
if (pb < Cijk->num_k())
k_end = Cijk->find_k(pb);
value_type cijk;
ordinal_type i,j,k;
for (typename Cijk_type::k_iterator k_it=k_begin; k_it!=k_end; ++k_it) {
k = index(k_it);
for (typename Cijk_type::kj_iterator j_it = Cijk->j_begin(k_it);
j_it != Cijk->j_end(k_it); ++j_it) {
j = index(j_it);
for (typename Cijk_type::kji_iterator i_it = Cijk->i_begin(j_it);
i_it != Cijk->i_end(j_it); ++i_it) {
i = index(i_it);
cijk = value(i_it);
(*A)(i,j) += cijk*cb[k];
}
}
}
// Compute B
B->putScalar(0.0);
for (ordinal_type i=0; i<pa; i++)
(*B)(i,0) = ca[i]*basis->norm_squared(i);
Teuchos::SerialDenseMatrix<ordinal_type,value_type> D(sz, 1);
//Equilibrate the linear system
if (equil == 1){
//Create diag mtx of max row entries
for (ordinal_type i=0; i<sz; i++){
Teuchos::SerialDenseMatrix<ordinal_type, value_type> r(Teuchos::View, *A, 1, sz, i, 0);
D(i,0)=sqrt(r.normOne());
}
//Compute inv(D)*A*inv(D)
for (ordinal_type i=0; i<sz; i++){
for (ordinal_type j=0; j<sz; j++){
(*A)(i,j)=(*A)(i,j)/(D(i,0)*D(j,0));
}
}
//Scale b by inv(D)
for (ordinal_type i=0; i<sz; i++){
(*B)(i,0)=(*B)(i,0)/D(i,0);
}
}
if (linear == 1){
//Compute M, the linear matrix to be used in the preconditioner
pb = basis->dimension()+1;
M->putScalar(0.0);
if (pb < Cijk->num_k())
k_end = Cijk->find_k(pb);
for (typename Cijk_type::k_iterator k_it=k_begin; k_it!=k_end; ++k_it) {
k = index(k_it);
for ( typename Cijk_type::kj_iterator j_it = Cijk->j_begin(k_it);
j_it != Cijk->j_end(k_it); ++j_it) {
j = index(j_it);
for ( typename Cijk_type::kji_iterator i_it = Cijk->i_begin(j_it);
i_it != Cijk->i_end(j_it); ++i_it) {
i = index(i_it);
cijk = value(i_it);
(*M)(i,j) += cijk*cb[k];
}
}
}
//Scale M
if (equil == 1){
//Compute inv(D)*M*inv(D)
for (ordinal_type i=0; i<sz; i++){
for (ordinal_type j=0; j<sz; j++){
(*M)(i,j)=(*M)(i,j)/(D(i,0)*D(j,0));
}
}
}
// Compute X = A^{-1}*B
GMRES(*A,*X,*B, max_it, tol, prec_iter, basis->order(), basis->dimension(), PrecNum, *M, diag);
}
else{
GMRES(*A,*X,*B, max_it, tol, prec_iter, basis->order(), basis->dimension(), PrecNum, *A, diag);
}
if (equil == 1 ) {
//Rescale X
for (ordinal_type i=0; i<sz; i++){
(*X)(i,0)=(*X)(i,0)/D(i,0);
}
}
// Compute c
for (ordinal_type i=0; i<pc; i++)
cc[i] = alpha*(*X)(i,0) + beta*cc[i];
}
else {
for (ordinal_type i=0; i<pc; i++)
cc[i] = alpha*ca[i]/cb[0] + beta*cc[i];
}
}
template <typename ordinal_type, typename value_type, typename node_type>
ordinal_type
Stokhos::GMRESDivisionExpansionStrategy<ordinal_type,value_type,node_type>::
GMRES(const Teuchos::SerialDenseMatrix<ordinal_type, value_type> & A,
Teuchos::SerialDenseMatrix<ordinal_type,value_type> & X,
const Teuchos::SerialDenseMatrix<ordinal_type,value_type> & B,
ordinal_type max_iter,
value_type tolerance,
ordinal_type prec_iter,
ordinal_type order,
ordinal_type dim,
ordinal_type PrecNum,
const Teuchos::SerialDenseMatrix<ordinal_type, value_type> & M,
ordinal_type diag)
{
ordinal_type n = A.numRows();
ordinal_type k = 1;
value_type resid;
Teuchos::SerialDenseMatrix<ordinal_type, value_type> P(n,n);
Teuchos::SerialDenseMatrix<ordinal_type, value_type> Ax(n,1);
Ax.multiply(Teuchos::NO_TRANS,Teuchos::NO_TRANS,1.0, A, X, 0.0);
Teuchos::SerialDenseMatrix<ordinal_type, value_type> r0(Teuchos::Copy,B);
r0-=Ax;
resid=r0.normFrobenius();
//define vector v=r/norm(r) where r=b-Ax
Teuchos::SerialDenseMatrix<ordinal_type, value_type> v(n,1);
r0.scale(1/resid);
Teuchos::SerialDenseMatrix<ordinal_type, value_type> h(1,1);
//Matrix of orthog basis vectors V
Teuchos::SerialDenseMatrix<ordinal_type, value_type> V(n,1);
//Set v=r0/norm(r0) to be 1st col of V
for (ordinal_type i=0; i<n; i++){
V(i,0)=r0(i,0);
}
//right hand side
Teuchos::SerialDenseMatrix<ordinal_type, value_type> bb(1,1);
bb(0,0)=resid;
Teuchos::SerialDenseMatrix<ordinal_type, value_type> w(n,1);
Teuchos::SerialDenseMatrix<ordinal_type, value_type> c;
Teuchos::SerialDenseMatrix<ordinal_type, value_type> s;
while (resid > tolerance && k < max_iter){
h.reshape(k+1,k);
//Arnoldi iteration(Gram-Schmidt )
V.reshape(n,k+1);
//set vk to be kth col of V
Teuchos::SerialDenseMatrix<ordinal_type, value_type> vk(Teuchos::Copy, V, n,1,0,k-1);
//Preconditioning step: solve Mz=vk
Teuchos::SerialDenseMatrix<ordinal_type, value_type> z(vk);
if (PrecNum == 1){
Stokhos::DiagPreconditioner<ordinal_type, value_type> precond(M);
precond.ApplyInverse(vk,z,prec_iter);
}
else if (PrecNum == 2){
Stokhos::JacobiPreconditioner<ordinal_type, value_type> precond(M);
precond.ApplyInverse(vk,z,2);
}
else if (PrecNum == 3){
Stokhos::GSPreconditioner<ordinal_type, value_type> precond(M,1);
precond.ApplyInverse(vk,z,1);
}
else if (PrecNum == 4){
Stokhos::SchurPreconditioner<ordinal_type, value_type> precond(M, order, dim, diag);
precond.ApplyInverse(vk,z,prec_iter);
}
w.multiply(Teuchos::NO_TRANS, Teuchos::NO_TRANS, 1, A, z, 0.0);
Teuchos::SerialDenseMatrix<ordinal_type, value_type> vi(n,1);
Teuchos::SerialDenseMatrix<ordinal_type, value_type> ip(1,1);
for (ordinal_type i=0; i<k; i++){
//set vi to be ith col of V
Teuchos::SerialDenseMatrix<ordinal_type, value_type> vi(Teuchos::Copy, V, n,1,0,i);
//Calculate inner product
ip.multiply(Teuchos::TRANS, Teuchos::NO_TRANS, 1.0, vi, w, 0.0);
h(i,k-1)= ip(0,0);
//scale vi by h(i,k-1)
vi.scale(ip(0,0));
w-=vi;
}
h(k,k-1)=w.normFrobenius();
w.scale(1.0/h(k,k-1));
//add column vk+1=w to V
for (ordinal_type i=0; i<n; i++){
V(i,k)=w(i,0);
}
//Solve upper hessenberg least squares problem via Givens rotations
//Compute previous Givens rotations
for (ordinal_type i=0; i<k-1; i++){
value_type q=c(i,0)*h(i,k-1)+s(i,0)*h(i+1,k-1);
h(i+1,k-1)=-1*s(i,0)*h(i,k-1)+c(i,0)*h(i+1,k-1);
h(i,k-1)=q;
}
//Compute next Givens rotations
c.reshape(k,1);
s.reshape(k,1);
bb.reshape(k+1,1);
value_type l = sqrt(h(k-1,k-1)*h(k-1,k-1)+h(k,k-1)*h(k,k-1));
c(k-1,0)=h(k-1,k-1)/l;
s(k-1,0)=h(k,k-1)/l;
// Givens rotation on h and bb
h(k-1,k-1)=l;
h(k,k-1)=0;
bb(k,0)=-s(k-1,0)*bb(k-1,0);
bb(k-1,0)=c(k-1,0)*bb(k-1,0);
//Determine residual
resid = fabs(bb(k,0));
k++;
}
//Extract upper triangular square matrix
bb.reshape(h.numRows()-1 ,1);
//Solve linear system
ordinal_type info;
Teuchos::LAPACK<ordinal_type, value_type> lapack;
lapack.TRTRS('U', 'N', 'N', h.numRows()-1, 1, h.values(), h.stride(), bb.values(), bb.stride(),&info);
Teuchos::SerialDenseMatrix<ordinal_type, value_type> ans(X);
V.reshape(n,k-1);
ans.multiply(Teuchos::NO_TRANS, Teuchos::NO_TRANS, 1.0, V, bb, 0.0);
if (PrecNum == 1){
Stokhos::DiagPreconditioner<ordinal_type, value_type> precond(M);
precond.ApplyInverse(ans,ans,prec_iter);
}
else if (PrecNum == 2){
Stokhos::JacobiPreconditioner<ordinal_type, value_type> precond(M);
precond.ApplyInverse(ans,ans,2);
}
else if (PrecNum == 3){
Stokhos::GSPreconditioner<ordinal_type, value_type> precond(M,1);
precond.ApplyInverse(ans,ans,1);
}
else if (PrecNum == 4){
Stokhos::SchurPreconditioner<ordinal_type, value_type> precond(M, order, dim, diag);
precond.ApplyInverse(ans,ans,prec_iter);}
X+=ans;
//std::cout << "iteration count= " << k-1 << std::endl;
return 0;
}
#endif // STOKHOS_DIVISION_EXPANSION_STRATEGY_HPP
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