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Represents the primary variables used by the a model. More...
#include <fvbaseprimaryvariables.hh>
Public Member Functions | |
FvBasePrimaryVariables (const FvBasePrimaryVariables &value)=default | |
Assignment from another primary variables object. | |
FvBasePrimaryVariables & | operator= (const FvBasePrimaryVariables &value)=default |
Assignment from another primary variables object. | |
Evaluation | makeEvaluation (unsigned varIdx, unsigned timeIdx, LinearizationType linearizationType=LinearizationType()) const |
Return a primary variable intensive evaluation. | |
template<class FluidState > | |
void | assignNaive (const FluidState &) |
Assign the primary variables "somehow" from a fluid state. | |
void | checkDefined () const |
Instruct valgrind to check the definedness of all attributes of this class. | |
Static Public Member Functions | |
static void | init () |
< Import base class assignment operators. | |
static void | registerParameters () |
Represents the primary variables used by the a model.
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inline |
Assign the primary variables "somehow" from a fluid state.
That is without considering any consistency issues which the fluid state might have. This method is guaranteed to produce consistent results if the fluid state is consistent to the properties at a given spatial location. (Where "consistent results" means that the same fluid state can be reconstructed from the primary variables.)
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inline |
Return a primary variable intensive evaluation.
i.e., the result represents the function f = x_i if the time index is zero, else it represents the a constant f = x_i. (the difference is that in the first case, the derivative w.r.t. x_i is 1, while it is 0 in the second case.