48 DriverArnoldi::DriverArnoldi(
72 "VelocityCorrectionScheme",
88 if(
m_session->DefinesSolverInfo(
"ModeType") &&
89 (boost::iequals(
m_session->GetSolverInfo(
"ModeType"),
91 boost::iequals(
m_session->GetSolverInfo(
"ModeType"),
96 m_equ[0]->UpdateFields()[i]->SetWaveSpace(
true);
117 if(!
m_session->DefinesSolverInfo(
"HOMOGENEOUS")&&!
m_session->DefinesSolverInfo(
"ModeType"))
121 else if(!boost::iequals(
m_session->GetSolverInfo(
"ModeType"),
"SingleMode"))
131 if (
m_comm->GetRank() == 0)
133 if(
m_session->DefinesSolverInfo(
"ModeType") &&
134 boost::iequals(
m_session->GetSolverInfo(
"ModeType"),
137 out <<
"\tSingle Fourier mode : true " << endl;
139 "Expected a homogeneous expansion to be defined "
144 out <<
"\tSingle Fourier mode : false " << endl;
146 if(
m_session->DefinesSolverInfo(
"BetaZero"))
148 out <<
"\tBeta set to Zero : true (overrides LHom)"
153 out <<
"\tBeta set to Zero : false " << endl;
158 out <<
"\tEvolution operator : "
159 <<
m_session->GetSolverInfo(
"EvolutionOperator")
167 out <<
"\tKrylov-space dimension : " <<
m_kdim << endl;
168 out <<
"\tNumber of vectors : " <<
m_nvec << endl;
169 out <<
"\tMax iterations : " <<
m_nits << endl;
170 out <<
"\tEigenvalue tolerance : " <<
m_evtol << endl;
171 out <<
"======================================================"
184 int nq = fields[0]->GetNcoeffs();
188 Vmath::Vcopy(nq, &array[k*nq], 1, &fields[k]->UpdateCoeffs()[0], 1);
189 fields[k]->SetPhysState(
false);
207 fields =
m_equ[0]->UpdateFields();
216 int nq = fields[0]->GetNcoeffs();
217 Vmath::Vcopy(nq, &fields[k]->GetCoeffs()[0], 1, &array[k*nq], 1);
218 fields[k]->SetPhysState(
false);
232 "Transient Growth non available for Coupled Solver");
234 fields =
m_equ[0]->UpdateFields();
235 int nq = fields[0]->GetNcoeffs();
240 &fields[k]->GetCoeffs()[0], 1,
241 &
m_equ[1]->UpdateFields()[k]->UpdateCoeffs()[0], 1);
248 std::vector<std::string> variables(
m_nfields);
253 variables[i] =
m_equ[0]->GetVariable(i);
256 m_equ[0]->WriteFld(file,
m_equ[0]->UpdateFields()[0], coeffs, variables);
263 std::vector<std::string> variables(
m_nfields);
264 std::vector<Array<OneD, NekDouble> > fieldcoeffs(
m_nfields);
266 int ncoeffs =
m_equ[0]->UpdateFields()[0]->GetNcoeffs();
267 ASSERTL1(coeffs.num_elements() >= ncoeffs*
m_nfields,
"coeffs is not of sufficient size");
271 variables[i] =
m_equ[0]->GetVariable(i);
272 fieldcoeffs[i] = coeffs + i*ncoeffs;
275 m_equ[0]->WriteFld(file,
m_equ[0]->UpdateFields()[0], fieldcoeffs, variables);
291 evlout <<
"EV: " << setw(2) << i
292 << setw(12) << abs_ev
293 << setw(12) << ang_ev
294 << setw(12) << log (abs_ev) /
m_period
299 evlout << setw(12) << resid;
305 NekDouble invmag = 1.0/(re_ev*re_ev + im_ev*im_ev);
316 evlout <<
"EV: " << setw(2) << i
317 << setw(14) <<
sign*re_ev
318 << setw(14) <<
sign*im_ev;
328 evlout << setw(12) << resid;
#define ASSERTL0(condition, msg)
#define NEKERROR(type, msg)
Assert Level 0 – Fundamental assert which is used whether in FULLDEBUG, DEBUG or OPT compilation mode...
#define ASSERTL1(condition, msg)
Assert Level 1 – Debugging which is used whether in FULLDEBUG or DEBUG compilation mode....
#define sign(a, b)
return the sign(b)*a
virtual ~DriverArnoldi()
Destructor.
void CopyFwdToAdj()
Copy the forward field to the adjoint system in transient growth calculations.
void WriteFld(std::string file, std::vector< Array< OneD, NekDouble > > coeffs)
Write coefficients to file.
NekDouble m_period
Tolerance of iteratiosn.
int m_infosteps
underlying operator is time stepping
void CopyFieldToArnoldiArray(Array< OneD, NekDouble > &array)
Copy fields to Arnoldi storage.
virtual void v_InitObject(std::ostream &out=std::cout)
int m_nvec
Dimension of Krylov subspace.
bool m_timeSteppingAlgorithm
Period of time stepping algorithm.
int m_nits
Number of vectors to test.
void CopyArnoldiArrayToField(Array< OneD, NekDouble > &array)
Copy Arnoldi storage to fields.
NekDouble m_evtol
Maxmum number of iterations.
int m_nfields
interval to dump information if required.
SOLVER_UTILS_EXPORT void ArnoldiSummary(std::ostream &out)
void WriteEvs(std::ostream &evlout, const int k, const NekDouble real, const NekDouble imag, NekDouble resid=NekConstants::kNekUnsetDouble, bool DumpInverse=true)
Base class for the development of solvers.
LibUtilities::SessionReaderSharedPtr m_session
Session reader object.
virtual SOLVER_UTILS_EXPORT void v_InitObject(std::ostream &out=std::cout)
LibUtilities::CommSharedPtr m_comm
Communication object.
enum EvolutionOperatorType m_EvolutionOperator
Evolution Operator.
Array< OneD, EquationSystemSharedPtr > m_equ
Equation system to solve.
int m_nequ
number of equations
std::shared_ptr< SessionReader > SessionReaderSharedPtr
static const NekDouble kNekUnsetDouble
std::shared_ptr< MeshGraph > MeshGraphSharedPtr
void Vcopy(int n, const T *x, const int incx, T *y, const int incy)
