Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have a

class BC_TOYFD
{
    public:
        BC_TOYFD( BS_TOYFD * pBS, BC2 dBC2 );
        virtual ~BC_TOYFD( void ) ;
        BS_TOYFD * _pBS ;
        BC2 _dBC2 ;
        double _PDA ; // store price down approximation
        double _PUA ; // store price up approximation
        virtual void COMPUTEBVDOWNFOR( PAYOFF_TOYFD * pPAYOFF, double * attime ) = 0 ;
        virtual void COMPUTEBVUPFOR( PAYOFF_TOYFD * pPAYOFF, double * attime ) = 0     ;
};

from which derives a

class DIRICHLET_TOYFD : public BC_TOYFD
{
    public:
        DIRICHLET_TOYFD( BS_TOYFD * pBS, BC2 dBC2 ) ;
        ~DIRICHLET_TOYFD( void ) ;
        void COMPUTEBVDOWNFOR( PAYOFF_TOYFD * pPAYOFF, double * attime ) ;
        void COMPUTEBVUPFOR( PAYOFF_TOYFD * pPAYOFF, double * attime ) ;
};

and I would like the methods

void DIRICHLET_TOYFD::COMPUTEBVDOWNFOR( PAYOFF_TOYFD * pPAYOFF, double * attime )

and

void DIRICHLET_TOYFD::COMPUTEBVUPFOR( PAYOFF_TOYFD * pPAYOFF, double * attime )

to do things accordingly to the runtime type of pPAYOFF, but without resorting to a

dynamic_cast<>

Typically,

void DIRICHLET_TOYFD::COMPUTEBVDOWNFOR( PAYOFF_TOYFD * pPAYOFF, double * attime )

would do something like

_PUA = something if the runtime type of pPAYOFF (which is an abstract class) is for instance CALL_TOYFD

and

_PUA = something else if the runtime type of pPAYOFF (which is an abstract class) is for instance PUT_TOYFD

where CALL_TOYFD and PUT_TOYFD are public derived from PAYOFF_TOYFD. And after, I would like to be able to write something like

double approx = bc->COMPUTEBVDOWNFOR( pPAYOFF, attime ) ;

where bc is an instance of BC_TOYFD, and where pPAYOFF is a pointer to PAYOFF_TOYFD, such that the right types for bc and pPAYOFF are resolved at runtime.

I have been told to use "double dispatch" or "reverse double dispatch" pattern for, without any other hint/precision. I have tried to implement it in this framework, without really knowing how to do it exactly. By the way, I will have "other" classes like DIRICHLET_TOYFD deriving from BC_TOYFD, for which I will have to save the same problem that the one I am trying to solve, so that I guess that the double dispatch put in practice in my case will have to take this constraint into account.

Any help would be appreciated !

Thanks a lot !

share|improve this question

1 Answer 1

Ok, after realizing being completely ignorant in the involved patterns, and after a bit of learning, I finally understood the dispatch pattern, and that the visitor pattern was a double dispatch pattern indeed. ;-) Concerning the code snippets I proposed, here is the solution :

// fwd decls

class BOUNDARY_CONDITION_DIRICHLET ;
class BOUNDARY_CONDITION_NEUMANN ;

class PAYOFF
{
    public:
        virtual void on_call( BOUNDARY_CONDITION_DIRICHLET * pBOUNDARY_CONDITION_DIRICHLET ) = 0 ;
        virtual void on_call( BOUNDARY_CONDITION_NEUMANN * pBOUNDARY_CONDITION_NEUMANN ) = 0 ;
};

////////////////////////////////////////////////////////

class BOUNDARY_CONDITION_DIRICHLET : public BOUNDARY_CONDITION
{
public:
     void COMPUTE_APPROX( PAYOFF * pPAYOFF )
    {
        pPAYOFF->on_call( this ) ;
    }
     void on_visit( CALL * pCALL )
    {
        std::cout << "The code \"BOUNDARY_CONDITION_DIRICHLET->f(CALL);\" has been executed" << std::endl ;
    }
     void on_visit( PUT * pPUT )
    {
        std::cout << "The code \"BOUNDARY_CONDITION_DIRICHLET->f(PUT);\" has been executed" << std::endl ;
    }
};

////////////////////////////////////////////////////////

class BOUNDARY_CONDITION_NEUMANN : public BOUNDARY_CONDITION
{
    public:
         void COMPUTE_APPROX( PAYOFF * pPAYOFF )
        {
            pPAYOFF->on_call( this ) ;
        }
         void on_visit( CALL * pCALL )
        {
            std::cout << "The code \"BOUNDARY_CONDITION_NEUMANN->f(CALL);\" has been executed" << std::endl ;
        }
         void on_visit( PUT * pPUT )
        {
            std::cout << "The code \"BOUNDARY_CONDITION_NEUMANN->f(PUT);\" has been executed" << std::endl ;
        }
};

////////////////////////////////////////////////////////

class CALL : public PAYOFF
{
    public:
         void on_call ( BOUNDARY_CONDITION_DIRICHLET * pBOUNDARY_CONDITION_DIRICHLET )
        {
            pBOUNDARY_CONDITION_DIRICHLET->on_visit( this ) ;
        }
         void on_call( BOUNDARY_CONDITION_NEUMANN * pBOUNDARY_CONDITION_NEUMANN)
        {
            pBOUNDARY_CONDITION_NEUMANN->on_visit( this ) ;
        }
};

////////////////////////////////////////////////////////

class PUT : public PAYOFF
{
    public:
         void on_call ( BOUNDARY_CONDITION_DIRICHLET * pBOUNDARY_CONDITION_DIRICHLET )
        {
            pBOUNDARY_CONDITION_DIRICHLET->on_visit( this ) ;
        }
         void on_call( BOUNDARY_CONDITION_NEUMANN * pBOUNDARY_CONDITION_NEUMANN )
        {
            pBOUNDARY_CONDITION_NEUMANN->on_visit( this ) ;
        }
};

int _tmain(int argc, _TCHAR* argv[])
{
    BOUNDARY_CONDITION_DIRICHLET dBOUNDARY_CONDITION_DIRICHLET ;
    BOUNDARY_CONDITION_NEUMANN dBOUNDARY_CONDITION_NEUMANN ;
    CALL dCALL ;
    PUT dPUT ;
    BOUNDARY_CONDITION_DIRICHLET * pBOUNDARY_CONDITION_DIRICHLET = &dBOUNDARY_CONDITION_DIRICHLET ;
    BOUNDARY_CONDITION_NEUMANN * pBOUNDARY_CONDITION_NEUMANN = &dBOUNDARY_CONDITION_NEUMANN ;
    CALL * pCALL = &dCALL ;
    PUT * pPUT = &dPUT ;

    BOUNDARY_CONDITION * pBOUNDARY_CONDITION = pBOUNDARY_CONDITION_DIRICHLET ;
    PAYOFF * pPAYOFF = pCALL ;
    pBOUNDARY_CONDITION->COMPUTE_APPROX( pPAYOFF ) ;

    pBOUNDARY_CONDITION = pBOUNDARY_CONDITION_DIRICHLET ;
    pPAYOFF = pPUT ;
    pBOUNDARY_CONDITION->COMPUTE_APPROX( pPAYOFF ) ;

    pBOUNDARY_CONDITION = pBOUNDARY_CONDITION_NEUMANN ;
    pPAYOFF = pCALL ;
    pBOUNDARY_CONDITION->COMPUTE_APPROX( pPAYOFF ) ;

    pBOUNDARY_CONDITION = pBOUNDARY_CONDITION_NEUMANN ;
    pPAYOFF = pPUT ;
    pBOUNDARY_CONDITION->COMPUTE_APPROX( pPAYOFF ) ;

    system("pause") ;
    return 0;
}

doing indeed what I expect it to do

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.