Coupleable

This class provides an API for coupling different kinds of variables values into MOOSE systems. The following tables summarize the methods it provides.

Methods for scalar field variablesDescription
coupledValue*‡§Value of a coupled variable at q-points
coupledGradient*‡§Gradient of a coupled variable at q-points
coupledSecond*‡§Second spatial derivatives of a coupled variable at q-points
coupledDot†§Time derivative of a coupled variable at q-points
coupledDotDot†§Second time derivative of a coupled variable at q-points
coupledDotDuDerivative with regards to the variable of the time derivative of a coupled variable at q-points
coupledDotDotDuDerivative with regards to the variable of the second time derivative of a coupled variable at q-points
coupledGradientDot§Time derivative of the gradient of a coupled variable at q-points
coupledGradientDotDotSecond time derivative of the gradient of a coupled variable at q-points

Methods for nodal scalar field variablesDescription
coupledNodalValue*‡§Value of a coupled variable at nodes
coupledNodalDotTime derivative of a coupled variable at nodes
coupledNodalDotDotSecond time derivative of a coupled variable at nodes

Methods for array field variablesDescription
coupledArrayValueValue of a coupled array variable at q-points
coupledArrayGradientGradient of a coupled array variable at q-points
coupledArrayDotTime derivative of a coupled array variable at q-points
coupledArrayDotDotSecond time derivative of a coupled array variable at q-points
coupledArrayDotDuDerivative with regards to the variable of the time derivative of a coupled array variable at q-points
coupledArrayGradientDotTime derivative of the gradient of a coupled array variable at q-points

Methods for vector field variablesDescription
coupledVectorValue‡§Value of a coupled vector variable at q-points
coupledVectorGradient‡§Gradient of a coupled vector variable at q-points
coupledCurlCurl of a coupled vector variable at q-points
coupledDivDivergence of a coupled vector variable at q-points
coupledVectorDot†§Time derivative of a coupled vector variable at q-points
coupledVectorDotDotSecond time derivative of a coupled vector variable at q-points
coupledVectorDotDuDerivative with regards to the variable of the time derivative of a coupled vector variable at q-points
coupledVectorDotDotDuDerivative with regards to the variable of the second time derivative of a coupled vector variable at q-points

Methods for nodal vector field variablesDescription
coupledNodalValue*‡§Value of a coupled vector variable at nodes
coupledNodalDotTime derivative of a coupled vector variable at nodes

*: These methods are also provided with values from the previous Newton iteration by suffixing their name with PreviousNL, e.g. coupledSecondPreviousNL.

†: These methods are also provided with values from the previous time step of a transient simulation by suffixing their name with Old, e.g. coupledDotOld.

‡: These methods are also provided with values from the previous or second previous time steps of a transient simulation by suffixing their name with Old or Older, respectively, e.g. coupledDivOld or coupledDivOlder.

§: These methods are also provided with automatic differentiation info by prefixing their name with ad and preserving camelCase, e.g. adCoupledValue or adCoupledVectorDot.

Note that all of these prefixes and suffixes are mutually exclusive, i.e. none can be mixed and matched in any way.

Lastly, some methods are only available with automatic differentiation info, e.g. adCoupledLowerValue returns the value of a coupled lower-dimensional variable and adCoupledVectorSecond returns the second spatial derivatives of a coupled vector variable.

Optional Coupling

To determine if a variable was coupled, users can use isCoupled method. The typical use case looks like this:


_value(isCoupled("v") ? coupledValue("v") : _zero)

However, this use case became obsolete and now it is recommended to use default values for optionally coupled variables, see the following example:


InputParameters
Class::validParams()
{
  InputParameters params = BaseClass::validParams();
  params.addCoupledVar("v", 2., "Coupled value");
  ...
  return params;
}

Class::Class(...) : BaseClass(...),
  _v(coupledValue('v'))

The advantage here is that users can provide arbitrary default values to their variables.

Coupling of Vectors of Variables

Users can couple a vector of variables using the following syntax:


v = 'a b c'

This syntax provides 3 variables coupled as a variable v in a MOOSE object using the Coupleable interface. The number of components coupled into can be obtained by coupledComponents method. Then, individual components can be obtained by calling coupledValue (or any other method mentioned above) passing in the variable name (as usual) and the component index. See the following example:

Declarations:


class B : public A
{
  ...
protected:
  unsigned int _n_vars;
  std::vector<MooseVariable *> _vars;
};

Implementation:


InputParameters
B::validParams()
{
  InputParameters params = A::validParams();
  params.addRequiredCoupledVar("v", "Coupled value");
  ...
  return params;
}

B::B(...) : A(...),
  _n_vars(coupledComponents("v"))
{
  for (unsigned int i = 0; i < _n_vars; i++)
    _vars.push_back(dynamic_cast<MooseVariable *>(getVar("v", i)));
}

Defaults for Coupling of Vectors of Variables

Vectors of variables can be added using params.addCoupledVar as described above. The parameter class allows providing defaults for vector variables as follows:


InputParameters
B::validParams()
{
  InputParameters params = A::validParams();
  params.addCoupledVar("v", {1, 2, 3}, "Coupled value");
  ...
  return params;
}

Coupled variable parameters can be set to constant real numbers in the input file using the syntax


v = '1'

for a single coupled variable or using


v = '1 2 3'

for a vector of coupled variables. Currently mixing actual variable assignments and defaults like this:


v = '1 actual_var 3'

is not supported.

Coupled Solution DOFs

It is possible to retrieve the solution DOFs of an element in an elemental loop. This is different than the "value" type coupling which holds the interpolated values of the shape functions themselves. Obtaining the raw DOFs all the user to perform their own integration or other evaluation without going through the interpolation process. These functions can be found here:

  /**
   * Returns DoFs in the current solution vector of a coupled variable for the local element
   * @param var_name Name of coupled variable
   * @param comp Component number for vector of coupled variables
   * @return Reference to a VariableValue for the DoFs of the coupled variable
   */
  virtual const VariableValue & coupledDofValues(const std::string & var_name,
                                                 unsigned int comp = 0) const;

  /**
   * Returns DoFs in the current solution vector of all of a coupled variable's components for the
   * local element
   * @param var_name Name of coupled variable
   * @return Vector of VariableValue pointers for each component of the coupled variable
   */
  std::vector<const VariableValue *> coupledAllDofValues(const std::string & var_name) const;

  /**
   * Returns DoFs in the old solution vector of a coupled variable for the local element
   * @param var_name Name of coupled variable
   * @param comp Component number for vector of coupled variables
   * @return Reference to a VariableValue for the old DoFs of the coupled variable
   */
  virtual const VariableValue & coupledDofValuesOld(const std::string & var_name,
                                                    unsigned int comp = 0) const;

  /**
   * Returns DoFs in the old solution vector of all of a coupled variable's components for the local
   * element
   * @param var_name Name of coupled variable
   * @return Vector of VariableValue pointers for each compontnet of the coupled variable
   */
  std::vector<const VariableValue *> coupledAllDofValuesOld(const std::string & var_name) const;

  /**
   * Returns DoFs in the older solution vector of a coupled variable for the local element
   * @param var_name Name of coupled variable
   * @param comp Component number for vector of coupled variables
   * @return Reference to a VariableValue for the older DoFs of the coupled variable
   */
  virtual const VariableValue & coupledDofValuesOlder(const std::string & var_name,
                                                      unsigned int comp = 0) const;

  /**
   * Returns DoFs in the older solution vector of all of a coupled variable's components for the
   * local element
   * @param var_name Name of coupled variable
   * @return Vector of VariableValue pointers for each component of the coupled variable
   */
  std::vector<const VariableValue *> coupledAllDofValuesOlder(const std::string & var_name) const;

  /**
   * Returns DoFs in the current solution vector of a coupled array variable for the local element
   * @param var_name Name of coupled array variable
   * @param comp Component number for vector of coupled array variables
   * @return Reference to a VariableValue for the DoFs of the coupled variable
   */
  virtual const ArrayVariableValue & coupledArrayDofValues(const std::string & var_name,
                                                           unsigned int comp = 0) const;
(moose/framework/include/interfaces/Coupleable.h)

Coupling of variables through their names

Typically variables are coupled in through calling params.addCoupledVar or params.addRequiredCoupledVar of the valid parameters of an object. There are cases where the variable names are provided through parameters in other types with params.addParam or params.addRequiredParam. For these cases, this interface provides two functions coupledValueByName and coupledArrayValueByName that take a variable name directly. This suffix ByName is only available for the two functions currently because they are the only onces needed by MOOSE and MOOSE applications. More can be added as desired in the future.

Writing directly to coupled variables

Element- and nodal user objects as well AuxKernels may obtain a writable reference to a MOOSE field variable through the Coupleable::writableVariable function. The returned variable reference provides a setDofValue (for FE and FV variables) and setNodalvalue (only for FE variables) methods that can be used to set the nodal or elemental DOF value(s) of the variable.

Coupleable::writableVariable enforces compatibility between the calling object type and the family of the requested variable. I.e. nodal user objects and AuxKernels may only obtain references to nodal variables, and element user objects and elemental AuxKernels may only obtain references to elemental variables.

The block restrictions of the variables are also checked not to exceed the block restrictions of the calling object. MOOSE keeps track of all variables to which a reference was obtained through Coupleable::writableVariable. Each variable in the system may at most be written to by a single object on any given subdomain.

The user object and aux kernel thread loops check if an executed object has any writable variable references, and if so, will insert those variables into the aux solution vector. This obviates the need for using the ProjectionAux kernel.

warningwarning

Coupleable::writableVariable can let users write to both FE / FV from AuxKernels and UserObjects but one must exercise caution about whether Nodal or Elemental type AuxKernels / UOs are used as the quadrature would depend on this choice and might lead to segfault if a FV variable values are set using setDofValue function for non-zero values of _qp .