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I'm doing a linear genetic programming project, where programs are bred and evolved by means of natural evolution mechanisms. Their "DNA" is basically a container (I've used arrays and vectors successfully) which contain function pointers to a set of functions available. Now, for simple problems, such as mathematical problems, I could use one type-defined function pointer which could point to functions that all return a double and all take as parameters two doubles.

Unfortunately this is not very practical. I need to be able to have a container which can have different sorts of function pointers, say a function pointer to a function which takes no arguments, or a function which takes one argument, or a function which returns something, etc (you get the idea)...

Is there any way to do this using any kind of container ? Could I do that using a container which contains polymorphic classes, which in their turn have various kinds of function pointers? I hope someone can direct me towards a solution because redesigning everything I've done so far is going to be painful.

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Say that you have a container c with lots of different kinds of functions. How are you going to call them? How are you going to process function results for the non-void functions? –  Cheers and hth. - Alf Jan 15 '11 at 10:19
    
I'd call them by iterating through the container and sequentially execute the function that is pointed to by the function pointer. I am not so sure if what i want to do is possible. For non void functions I would just assign the return value to a void pointer and try to handle it (is that even possible?). –  Alex Jan 15 '11 at 20:35
    
Why store the function pointers? Why not just store an identifier that you can use to choose the function to execute? (E.g., switch(FuncId){ case MULT: ... break; } ) Either way, you'll need some method of meaningfully applying the function chosen (e.g., where does the return value of a function go?) –  MatthewToday Jan 20 '11 at 3:40
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3 Answers

A typical idea for virtual machines is to have a separate stack that is used for argument and return value passing.

Your functions can still all be of type void fn(void), but you do argument passing and returning manually.

You can do something like this:

class ArgumentStack {
    public:
        void push(double ret_val) { m_stack.push_back(ret_val); }

        double pop() {
             double arg = m_stack.back();
             m_stack.pop_back();
             return arg;
        }

    private:
        std::vector<double> m_stack;
};
ArgumentStack stack;

...so a function could look like this:

// Multiplies two doubles on top of the stack.
void multiply() {
    // Read arguments.
    double a1 = stack.pop();
    double a2 = stack.pop();

    // Multiply!
    double result = a1 * a2;

    // Return the result by putting it on the stack.
    stack.push(result);
}

This can be used in this way:

// Calculate 4 * 2.
stack.push(4);
stack.push(2);
multiply();
printf("2 * 4 = %f\n", stack.pop());

Do you follow?

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No not really and it's a shame cuz it seems like u have something here... Have u got a link I can find out more about custom stacks ? –  Alex Jan 15 '11 at 10:50
    
Maybe you can try learning a little Forth. en.wikipedia.org/wiki/Forth_%28programming_language%29 It uses the same approach, which also inspired Java VM (if I am right) Please ask again if you need more help. –  kotlinski Jan 15 '11 at 11:53
    
@Alex you may want to have a look at en.wikipedia.org/wiki/Stack-oriented_programming_language –  wich Jan 15 '11 at 12:24
    
@Alex: I added some more example code now... hope it helps –  kotlinski Jan 15 '11 at 13:18
    
This seems like it could work with some adjustments, but this would only change the arguments passed into a function pointer. Would this have to be done to the functions that the function pointer points too as well ? About FORTH, this is really interesting but sadly I do not have the time to adapt all this into another language or learn it at this moment, however thank you for letting me know! –  Alex Jan 15 '11 at 20:23
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You cannot put a polymorphic function in a class, since functions that take (or return) different things cannot be used in the same way (with the same interface), which is something required by polymorphism.

The idea of having a class providing a virtual function for any possible function type you need would work, but (without knowing anything about your problem!) its usage feels weird to me: what functions would a derived class override? Aren't your functions uncorrelated?

If your functions are uncorrelated (if there's no reason why you should group them as members of the same class, or if they would be static function since they don't need member variables) you should opt for something else... If you pick your functions at random you could just have several different containers, one for function type, and just pick a container at random, and then a function within it.

Could you make some examples of what your functions do?

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Yes some functions are uncorrelated, but not all, for example the function set for solving first degree polynomials is basically: add, subtract, divide, multiply, root, square and also swap (two variables) and reverse (make a number from positive, negative or vice versa ). However in more complex problems, such as 2nd degree polynomials, or differentials, I need to use functions which compare values, functions which have a "logic" or a simple algorithm, etc... These functions might need a reference or to return a value and are thus completely different from the first set. –  Alex Jan 15 '11 at 10:53
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What you mentioned itself can be implemented probably by a container of std::function or discriminated union like Boost::variant.
For example:

#include <functional>
#include <cstdio>
#include <iostream>

struct F {
  virtual ~F() {}
};

template< class Return, class Param = void >
struct Func : F {
  std::function< Return( Param ) >  f;
  Func( std::function< Return( Param ) > const& f ) : f( f ) {}
  Return operator()( Param const& x ) const { return f( x ); }
};

template< class Return >
struct Func< Return, void > : F {
  std::function< Return() >  f;
  Func( std::function< Return() > const& f ) : f( f ) {}
  Return operator()() const { return f(); }
};

static void f_void_void( void ) { puts("void"); }
static int f_int_int( int x ) { return x; }

int main()
{
  F  *f[] = {
    new Func< void >( f_void_void ),
    new Func< int, int >( f_int_int ),
  };

  for ( F **a = f, **e = f + 2;  a != e;  ++ a ) {
    if      ( auto p = dynamic_cast< Func< void >*     >( *a ) ) {
      (*p)();
    }
    else if ( auto p = dynamic_cast< Func< int, int >* >( *a ) ) {
      std::cout<< (*p)( 1 ) <<'\n';
    }
  }
}

But I'm not sure this is really what you want...
What do you think about Alf P. Steinbach's comment?

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Im not so sure I understand your code, but it seems like what you have coded could work. I hadn't thought too much about what Steinbach comment, and still aren't really sure about it. –  Alex Jan 15 '11 at 20:39
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