libMesh
Public Types | Public Member Functions | Static Public Member Functions | Public Attributes | Protected Types | Protected Member Functions | Protected Attributes | Static Protected Attributes | List of all members
libMesh::SecondOrderUnsteadySolver Class Referenceabstract

Generic class from which second order UnsteadySolvers should subclass. More...

#include <second_order_unsteady_solver.h>

Inheritance diagram for libMesh::SecondOrderUnsteadySolver:
[legend]

Public Types

typedef DifferentiableSystem sys_type
 The type of system. More...
 

Public Member Functions

 SecondOrderUnsteadySolver (sys_type &s)
 Constructor. More...
 
virtual ~SecondOrderUnsteadySolver ()
 Destructor. More...
 
virtual unsigned int time_order () const override
 
virtual void init () override
 The initialization function. More...
 
virtual void init_data () override
 The data initialization function. More...
 
virtual void reinit () override
 The reinitialization function. More...
 
virtual void retrieve_timestep () override
 This method retrieves all the stored solutions at the current system.time. More...
 
void project_initial_rate (FunctionBase< Number > *f, FunctionBase< Gradient > *g=nullptr)
 Specify non-zero initial velocity. More...
 
Number old_solution_rate (const dof_id_type global_dof_number) const
 
Number old_solution_accel (const dof_id_type global_dof_number) const
 
virtual void solve () override
 This method solves for the solution at the next timestep. More...
 
virtual void advance_timestep () override
 This method advances the solution to the next timestep, after a solve() has been performed. More...
 
virtual void adjoint_advance_timestep () override
 This method advances the adjoint solution to the previous timestep, after an adjoint_solve() has been performed. More...
 
virtual Real error_order () const =0
 This method should return the expected convergence order of the (non-local) error of the time discretization scheme - e.g. More...
 
Number old_nonlinear_solution (const dof_id_type global_dof_number) const
 
virtual Real du (const SystemNorm &norm) const override
 Computes the size of ||u^{n+1} - u^{n}|| in some norm. More...
 
virtual bool is_steady () const override
 This is not a steady-state solver. More...
 
virtual bool element_residual (bool request_jacobian, DiffContext &)=0
 This method uses the DifferentiablePhysics element_time_derivative(), element_constraint(), and mass_residual() to build a full residual on an element. More...
 
virtual bool side_residual (bool request_jacobian, DiffContext &)=0
 This method uses the DifferentiablePhysics side_time_derivative(), side_constraint(), and side_mass_residual() to build a full residual on an element's side. More...
 
virtual bool nonlocal_residual (bool request_jacobian, DiffContext &)=0
 This method uses the DifferentiablePhysics nonlocal_time_derivative(), nonlocal_constraint(), and nonlocal_mass_residual() to build a full residual of non-local terms. More...
 
virtual void before_timestep ()
 This method is for subclasses or users to override to do arbitrary processing between timesteps. More...
 
const sys_typesystem () const
 
sys_typesystem ()
 
virtual std::unique_ptr< DiffSolver > & diff_solver ()
 An implicit linear or nonlinear solver to use at each timestep. More...
 
virtual std::unique_ptr< LinearSolver< Number > > & linear_solver ()
 An implicit linear solver to use for adjoint and sensitivity problems. More...
 
void set_solution_history (const SolutionHistory &_solution_history)
 A setter function users will employ if they need to do something other than save no solution history. More...
 
bool is_adjoint () const
 Accessor for querying whether we need to do a primal or adjoint solve. More...
 
void set_is_adjoint (bool _is_adjoint_value)
 Accessor for setting whether we need to do a primal or adjoint solve. More...
 

Static Public Member Functions

static std::string get_info ()
 Gets a string containing the reference information. More...
 
static void print_info (std::ostream &out=libMesh::out)
 Prints the reference information, by default to libMesh::out. More...
 
static unsigned int n_objects ()
 Prints the number of outstanding (created, but not yet destroyed) objects. More...
 
static void enable_print_counter_info ()
 Methods to enable/disable the reference counter output from print_info() More...
 
static void disable_print_counter_info ()
 

Public Attributes

std::unique_ptr< NumericVector< Number > > old_local_nonlinear_solution
 Serial vector of _system.get_vector("_old_nonlinear_solution") More...
 
bool quiet
 Print extra debugging information if quiet == false. More...
 
unsigned int reduce_deltat_on_diffsolver_failure
 This value (which defaults to zero) is the number of times the TimeSolver is allowed to halve deltat and let the DiffSolver repeat the latest failed solve with a reduced timestep. More...
 

Protected Types

typedef bool(DifferentiablePhysics::* ResFuncType) (bool, DiffContext &)
 Definitions of argument types for use in refactoring subclasses. More...
 
typedef void(DiffContext::* ReinitFuncType) (Real)
 
typedef std::map< std::string, std::pair< unsigned int, unsigned int > > Counts
 Data structure to log the information. More...
 

Protected Member Functions

void increment_constructor_count (const std::string &name)
 Increments the construction counter. More...
 
void increment_destructor_count (const std::string &name)
 Increments the destruction counter. More...
 

Protected Attributes

std::unique_ptr< NumericVector< Number > > _old_local_solution_rate
 Serial vector of previous time step velocity $ \dot{u}_n $. More...
 
std::unique_ptr< NumericVector< Number > > _old_local_solution_accel
 Serial vector of previous time step acceleration $ \ddot{u}_n $. More...
 
bool first_solve
 A bool that will be true the first time solve() is called, and false thereafter. More...
 
bool first_adjoint_step
 A bool that will be true the first time adjoint_advance_timestep() is called, (when the primal solution is to be used to set adjoint boundary conditions) and false thereafter. More...
 
std::unique_ptr< DiffSolver_diff_solver
 An implicit linear or nonlinear solver to use at each timestep. More...
 
std::unique_ptr< LinearSolver< Number > > _linear_solver
 An implicit linear solver to use for adjoint problems. More...
 
sys_type_system
 A reference to the system we are solving. More...
 
std::unique_ptr< SolutionHistorysolution_history
 A std::unique_ptr to a SolutionHistory object. More...
 

Static Protected Attributes

static Counts _counts
 Actually holds the data. More...
 
static Threads::atomic< unsigned int > _n_objects
 The number of objects. More...
 
static Threads::spin_mutex _mutex
 Mutual exclusion object to enable thread-safe reference counting. More...
 
static bool _enable_print_counter
 Flag to control whether reference count information is printed when print_info is called. More...
 

Detailed Description

Generic class from which second order UnsteadySolvers should subclass.

Subclasses of this class are meant to solve problems of the form

\[ M(u)\ddot{u} + C(u)\dot{u} + F(u) = 0 \]

This class is part of the new DifferentiableSystem framework, which is still experimental. Users of this framework should beware of bugs and future API changes.

Author
Paul T. Bauman
Date
2015

Definition at line 38 of file second_order_unsteady_solver.h.

Member Typedef Documentation

◆ Counts

typedef std::map<std::string, std::pair<unsigned int, unsigned int> > libMesh::ReferenceCounter::Counts
protectedinherited

Data structure to log the information.

The log is identified by the class name.

Definition at line 117 of file reference_counter.h.

◆ ReinitFuncType

typedef void(DiffContext::* libMesh::TimeSolver::ReinitFuncType) (Real)
protectedinherited

Definition at line 273 of file time_solver.h.

◆ ResFuncType

typedef bool(DifferentiablePhysics::* libMesh::TimeSolver::ResFuncType) (bool, DiffContext &)
protectedinherited

Definitions of argument types for use in refactoring subclasses.

Definition at line 271 of file time_solver.h.

◆ sys_type

The type of system.

Definition at line 65 of file time_solver.h.

Constructor & Destructor Documentation

◆ SecondOrderUnsteadySolver()

libMesh::SecondOrderUnsteadySolver::SecondOrderUnsteadySolver ( sys_type s)
explicit

Constructor.

Requires a reference to the system to be solved.

◆ ~SecondOrderUnsteadySolver()

virtual libMesh::SecondOrderUnsteadySolver::~SecondOrderUnsteadySolver ( )
virtual

Destructor.

Member Function Documentation

◆ adjoint_advance_timestep()

virtual void libMesh::UnsteadySolver::adjoint_advance_timestep ( )
overridevirtualinherited

This method advances the adjoint solution to the previous timestep, after an adjoint_solve() has been performed.

This will be done before every UnsteadySolver::adjoint_solve().

Reimplemented from libMesh::TimeSolver.

Reimplemented in libMesh::NewmarkSolver.

◆ advance_timestep()

virtual void libMesh::UnsteadySolver::advance_timestep ( )
overridevirtualinherited

This method advances the solution to the next timestep, after a solve() has been performed.

Often this will be done after every UnsteadySolver::solve(), but adaptive mesh refinement and/or adaptive time step selection may require some solve() steps to be repeated.

Reimplemented from libMesh::TimeSolver.

Reimplemented in libMesh::AdaptiveTimeSolver, and libMesh::NewmarkSolver.

◆ before_timestep()

virtual void libMesh::TimeSolver::before_timestep ( )
virtualinherited

This method is for subclasses or users to override to do arbitrary processing between timesteps.

Definition at line 167 of file time_solver.h.

167 {}

◆ diff_solver()

virtual std::unique_ptr<DiffSolver>& libMesh::TimeSolver::diff_solver ( )
virtualinherited

An implicit linear or nonlinear solver to use at each timestep.

Reimplemented in libMesh::AdaptiveTimeSolver.

Definition at line 182 of file time_solver.h.

References libMesh::TimeSolver::_diff_solver.

182 { return _diff_solver; }
std::unique_ptr< DiffSolver > _diff_solver
An implicit linear or nonlinear solver to use at each timestep.
Definition: time_solver.h:248

◆ disable_print_counter_info()

static void libMesh::ReferenceCounter::disable_print_counter_info ( )
staticinherited

◆ du()

virtual Real libMesh::UnsteadySolver::du ( const SystemNorm norm) const
overridevirtualinherited

Computes the size of ||u^{n+1} - u^{n}|| in some norm.

Note
While you can always call this function, its result may or may not be very meaningful. For example, if you call this function right after calling advance_timestep() then you'll get a result of zero since old_nonlinear_solution is set equal to nonlinear_solution in this function.

Implements libMesh::TimeSolver.

◆ element_residual()

virtual bool libMesh::TimeSolver::element_residual ( bool  request_jacobian,
DiffContext  
)
pure virtualinherited

This method uses the DifferentiablePhysics element_time_derivative(), element_constraint(), and mass_residual() to build a full residual on an element.

What combination

it uses will depend on the type of solver. See the subclasses for more details.

Implemented in libMesh::EigenTimeSolver, libMesh::NewmarkSolver, libMesh::AdaptiveTimeSolver, libMesh::SteadySolver, libMesh::Euler2Solver, and libMesh::EulerSolver.

◆ enable_print_counter_info()

static void libMesh::ReferenceCounter::enable_print_counter_info ( )
staticinherited

Methods to enable/disable the reference counter output from print_info()

◆ error_order()

virtual Real libMesh::UnsteadySolver::error_order ( ) const
pure virtualinherited

This method should return the expected convergence order of the (non-local) error of the time discretization scheme - e.g.

2 for the O(deltat^2) Crank-Nicholson, or 1 for the O(deltat) Backward Euler.

Useful for adaptive timestepping schemes.

Implemented in libMesh::NewmarkSolver, libMesh::AdaptiveTimeSolver, libMesh::Euler2Solver, and libMesh::EulerSolver.

◆ get_info()

static std::string libMesh::ReferenceCounter::get_info ( )
staticinherited

Gets a string containing the reference information.

◆ increment_constructor_count()

void libMesh::ReferenceCounter::increment_constructor_count ( const std::string &  name)
protectedinherited

Increments the construction counter.

Should be called in the constructor of any derived class that will be reference counted.

Definition at line 181 of file reference_counter.h.

References libMesh::ReferenceCounter::_counts, libMesh::Quality::name(), and libMesh::Threads::spin_mtx.

Referenced by libMesh::ReferenceCountedObject< RBParametrized >::ReferenceCountedObject().

182 {
183  Threads::spin_mutex::scoped_lock lock(Threads::spin_mtx);
184  std::pair<unsigned int, unsigned int> & p = _counts[name];
185 
186  p.first++;
187 }
std::string name(const ElemQuality q)
static Counts _counts
Actually holds the data.
spin_mutex spin_mtx
A convenient spin mutex object which can be used for obtaining locks.

◆ increment_destructor_count()

void libMesh::ReferenceCounter::increment_destructor_count ( const std::string &  name)
protectedinherited

Increments the destruction counter.

Should be called in the destructor of any derived class that will be reference counted.

Definition at line 194 of file reference_counter.h.

References libMesh::ReferenceCounter::_counts, libMesh::Quality::name(), and libMesh::Threads::spin_mtx.

Referenced by libMesh::ReferenceCountedObject< RBParametrized >::~ReferenceCountedObject().

195 {
196  Threads::spin_mutex::scoped_lock lock(Threads::spin_mtx);
197  std::pair<unsigned int, unsigned int> & p = _counts[name];
198 
199  p.second++;
200 }
std::string name(const ElemQuality q)
static Counts _counts
Actually holds the data.
spin_mutex spin_mtx
A convenient spin mutex object which can be used for obtaining locks.

◆ init()

virtual void libMesh::SecondOrderUnsteadySolver::init ( )
overridevirtual

The initialization function.

This method is used to initialize internal data structures before a simulation begins.

Reimplemented from libMesh::UnsteadySolver.

◆ init_data()

virtual void libMesh::SecondOrderUnsteadySolver::init_data ( )
overridevirtual

The data initialization function.

This method is used to initialize internal data structures after the underlying System has been initialized

Reimplemented from libMesh::UnsteadySolver.

◆ is_adjoint()

bool libMesh::TimeSolver::is_adjoint ( ) const
inherited

Accessor for querying whether we need to do a primal or adjoint solve.

Definition at line 233 of file time_solver.h.

References libMesh::TimeSolver::_is_adjoint.

234  { return _is_adjoint; }
bool _is_adjoint
This boolean tells the TimeSolver whether we are solving a primal or adjoint problem.
Definition: time_solver.h:281

◆ is_steady()

virtual bool libMesh::UnsteadySolver::is_steady ( ) const
overridevirtualinherited

This is not a steady-state solver.

Implements libMesh::TimeSolver.

Definition at line 154 of file unsteady_solver.h.

154 { return false; }

◆ linear_solver()

virtual std::unique_ptr<LinearSolver<Number> >& libMesh::TimeSolver::linear_solver ( )
virtualinherited

An implicit linear solver to use for adjoint and sensitivity problems.

Reimplemented in libMesh::AdaptiveTimeSolver.

Definition at line 187 of file time_solver.h.

References libMesh::TimeSolver::_linear_solver.

187 { return _linear_solver; }
std::unique_ptr< LinearSolver< Number > > _linear_solver
An implicit linear solver to use for adjoint problems.
Definition: time_solver.h:253

◆ n_objects()

static unsigned int libMesh::ReferenceCounter::n_objects ( )
staticinherited

Prints the number of outstanding (created, but not yet destroyed) objects.

Definition at line 83 of file reference_counter.h.

References libMesh::ReferenceCounter::_n_objects.

84  { return _n_objects; }
static Threads::atomic< unsigned int > _n_objects
The number of objects.

◆ nonlocal_residual()

virtual bool libMesh::TimeSolver::nonlocal_residual ( bool  request_jacobian,
DiffContext  
)
pure virtualinherited

This method uses the DifferentiablePhysics nonlocal_time_derivative(), nonlocal_constraint(), and nonlocal_mass_residual() to build a full residual of non-local terms.

What combination it uses will depend on the type of solver. See the subclasses for more details.

Implemented in libMesh::NewmarkSolver, libMesh::EigenTimeSolver, libMesh::SteadySolver, libMesh::AdaptiveTimeSolver, libMesh::Euler2Solver, and libMesh::EulerSolver.

◆ old_nonlinear_solution()

Number libMesh::UnsteadySolver::old_nonlinear_solution ( const dof_id_type  global_dof_number) const
inherited
Returns
The old nonlinear solution for the specified global DOF.

◆ old_solution_accel()

Number libMesh::SecondOrderUnsteadySolver::old_solution_accel ( const dof_id_type  global_dof_number) const
Returns
The solution acceleration at the previous time step, $\ddot{u}_n$, for the specified global DOF.

◆ old_solution_rate()

Number libMesh::SecondOrderUnsteadySolver::old_solution_rate ( const dof_id_type  global_dof_number) const
Returns
The solution rate at the previous time step, $\dot{u}_n$, for the specified global DOF.

◆ print_info()

static void libMesh::ReferenceCounter::print_info ( std::ostream &  out = libMesh::out)
staticinherited

Prints the reference information, by default to libMesh::out.

◆ project_initial_rate()

void libMesh::SecondOrderUnsteadySolver::project_initial_rate ( FunctionBase< Number > *  f,
FunctionBase< Gradient > *  g = nullptr 
)

Specify non-zero initial velocity.

Should be called before solve(). The function value f and its gradient g are user-provided cloneable functors. A gradient g is only required/used for projecting onto finite element spaces with continuous derivatives.

◆ reinit()

virtual void libMesh::SecondOrderUnsteadySolver::reinit ( )
overridevirtual

The reinitialization function.

This method is used to resize internal data vectors after a mesh change.

Reimplemented from libMesh::UnsteadySolver.

◆ retrieve_timestep()

virtual void libMesh::SecondOrderUnsteadySolver::retrieve_timestep ( )
overridevirtual

This method retrieves all the stored solutions at the current system.time.

Reimplemented from libMesh::UnsteadySolver.

◆ set_is_adjoint()

void libMesh::TimeSolver::set_is_adjoint ( bool  _is_adjoint_value)
inherited

Accessor for setting whether we need to do a primal or adjoint solve.

Definition at line 240 of file time_solver.h.

References libMesh::TimeSolver::_is_adjoint.

241  { _is_adjoint = _is_adjoint_value; }
bool _is_adjoint
This boolean tells the TimeSolver whether we are solving a primal or adjoint problem.
Definition: time_solver.h:281

◆ set_solution_history()

void libMesh::TimeSolver::set_solution_history ( const SolutionHistory _solution_history)
inherited

A setter function users will employ if they need to do something other than save no solution history.

◆ side_residual()

virtual bool libMesh::TimeSolver::side_residual ( bool  request_jacobian,
DiffContext  
)
pure virtualinherited

This method uses the DifferentiablePhysics side_time_derivative(), side_constraint(), and side_mass_residual() to build a full residual on an element's side.

What combination it uses will depend on the type of solver. See the subclasses for more details.

Implemented in libMesh::NewmarkSolver, libMesh::EigenTimeSolver, libMesh::AdaptiveTimeSolver, libMesh::SteadySolver, libMesh::Euler2Solver, and libMesh::EulerSolver.

◆ solve()

virtual void libMesh::UnsteadySolver::solve ( )
overridevirtualinherited

This method solves for the solution at the next timestep.

Usually we will only need to solve one (non)linear system per timestep, but more complex subclasses may override this.

Reimplemented from libMesh::TimeSolver.

Reimplemented in libMesh::NewmarkSolver, libMesh::AdaptiveTimeSolver, and libMesh::TwostepTimeSolver.

◆ system() [1/2]

const sys_type& libMesh::TimeSolver::system ( ) const
inherited
Returns
A constant reference to the system we are solving.

Definition at line 172 of file time_solver.h.

References libMesh::TimeSolver::_system.

172 { return _system; }
sys_type & _system
A reference to the system we are solving.
Definition: time_solver.h:258

◆ system() [2/2]

sys_type& libMesh::TimeSolver::system ( )
inherited
Returns
A writable reference to the system we are solving.

Definition at line 177 of file time_solver.h.

References libMesh::TimeSolver::_system.

177 { return _system; }
sys_type & _system
A reference to the system we are solving.
Definition: time_solver.h:258

◆ time_order()

virtual unsigned int libMesh::SecondOrderUnsteadySolver::time_order ( ) const
overridevirtual
Returns
The maximum order of time derivatives for which the UnsteadySolver subclass is capable of handling.

For example, EulerSolver will have time_order() = 1 and NewmarkSolver will have time_order() = 2.

Implements libMesh::UnsteadySolver.

Definition at line 53 of file second_order_unsteady_solver.h.

54  { return 2; }

Member Data Documentation

◆ _counts

Counts libMesh::ReferenceCounter::_counts
staticprotectedinherited

◆ _diff_solver

std::unique_ptr<DiffSolver> libMesh::TimeSolver::_diff_solver
protectedinherited

An implicit linear or nonlinear solver to use at each timestep.

Definition at line 248 of file time_solver.h.

Referenced by libMesh::TimeSolver::diff_solver().

◆ _enable_print_counter

bool libMesh::ReferenceCounter::_enable_print_counter
staticprotectedinherited

Flag to control whether reference count information is printed when print_info is called.

Definition at line 141 of file reference_counter.h.

◆ _linear_solver

std::unique_ptr<LinearSolver<Number> > libMesh::TimeSolver::_linear_solver
protectedinherited

An implicit linear solver to use for adjoint problems.

Definition at line 253 of file time_solver.h.

Referenced by libMesh::TimeSolver::linear_solver().

◆ _mutex

Threads::spin_mutex libMesh::ReferenceCounter::_mutex
staticprotectedinherited

Mutual exclusion object to enable thread-safe reference counting.

Definition at line 135 of file reference_counter.h.

◆ _n_objects

Threads::atomic<unsigned int> libMesh::ReferenceCounter::_n_objects
staticprotectedinherited

The number of objects.

Print the reference count information when the number returns to 0.

Definition at line 130 of file reference_counter.h.

Referenced by libMesh::ReferenceCounter::n_objects(), libMesh::ReferenceCounter::ReferenceCounter(), and libMesh::ReferenceCounter::~ReferenceCounter().

◆ _old_local_solution_accel

std::unique_ptr<NumericVector<Number> > libMesh::SecondOrderUnsteadySolver::_old_local_solution_accel
protected

Serial vector of previous time step acceleration $ \ddot{u}_n $.

Definition at line 112 of file second_order_unsteady_solver.h.

◆ _old_local_solution_rate

std::unique_ptr<NumericVector<Number> > libMesh::SecondOrderUnsteadySolver::_old_local_solution_rate
protected

Serial vector of previous time step velocity $ \dot{u}_n $.

Definition at line 107 of file second_order_unsteady_solver.h.

◆ _system

sys_type& libMesh::TimeSolver::_system
protectedinherited

A reference to the system we are solving.

Definition at line 258 of file time_solver.h.

Referenced by libMesh::TimeSolver::system().

◆ first_adjoint_step

bool libMesh::UnsteadySolver::first_adjoint_step
protectedinherited

A bool that will be true the first time adjoint_advance_timestep() is called, (when the primal solution is to be used to set adjoint boundary conditions) and false thereafter.

Definition at line 168 of file unsteady_solver.h.

◆ first_solve

bool libMesh::UnsteadySolver::first_solve
protectedinherited

A bool that will be true the first time solve() is called, and false thereafter.

Definition at line 162 of file unsteady_solver.h.

◆ old_local_nonlinear_solution

std::unique_ptr<NumericVector<Number> > libMesh::UnsteadySolver::old_local_nonlinear_solution
inherited

Serial vector of _system.get_vector("_old_nonlinear_solution")

Definition at line 138 of file unsteady_solver.h.

◆ quiet

bool libMesh::TimeSolver::quiet
inherited

Print extra debugging information if quiet == false.

Definition at line 192 of file time_solver.h.

◆ reduce_deltat_on_diffsolver_failure

unsigned int libMesh::TimeSolver::reduce_deltat_on_diffsolver_failure
inherited

This value (which defaults to zero) is the number of times the TimeSolver is allowed to halve deltat and let the DiffSolver repeat the latest failed solve with a reduced timestep.

Note
This has no effect for SteadySolvers.
You must set at least one of the DiffSolver flags "continue_after_max_iterations" or "continue_after_backtrack_failure" to allow the TimeSolver to retry the solve.

Definition at line 221 of file time_solver.h.

◆ solution_history

std::unique_ptr<SolutionHistory> libMesh::TimeSolver::solution_history
protectedinherited

A std::unique_ptr to a SolutionHistory object.

Default is NoSolutionHistory, which the user can override by declaring a different kind of SolutionHistory in the application

Definition at line 265 of file time_solver.h.


The documentation for this class was generated from the following file: