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I stumbled upon a problem I (nor do any of my more knowledgeable colleagues) know how to solve (of work around). The problem in the end comes to not being able to create a virtual template function. I have searched the net thoroughly, found several ways of dealing with it, but none seem to be applicable in my case.

I don't know how to describe this situation in short, but I'll do my best and hope it makes sense.

The problem is processing two curves, each of them consists of one or several segments of same or different curve types. So I began with creating an interface for a curve segment, with a template class of the curve it will be interacting with (functions are of the same type as intersections between two different curve segments, for example):

template<class curve> class curve_segment { // some methods here }

user can then implement several types of curves, and appropriate functions depending with what curves it will be interacting with. For example, circle and line, where both can interact with both:

class line :  public curve_segment<line>, public curve_segment<circle> { //... }
class circle :  public curve_segment<line>, public curve_segment<circle> { //... }

Following that, I have a class cell, which depends on two curve segments, and a base class cell_base which encapsulates it:

template<class curve1, class curve2> class cell : public cell_base { 
  cell_base* up; cell_base* down;

  curve_segment<curve1>* segment_x;
  curve_segment<curve2>* segment_y;

  // some methods that depend on both curves
}

In the end, there is a 2D grid m*n of such cells, where the two curves consist of m and n curve_segments of possibly different types, and is held together by the two pointers in each cell.

The problem begins to show when a new curve_segment would be added to one of the two curves. The obvious solution would be to add

template<class curve> virtual void add_curve_x(curve_segment<curve> seg) =0;

to the cell_base class, where the implementation in cell could extract the appropriate segment of the other curve, and appended a new cell to it. For example, if curves a and b where a represents the x axis in the grid, and we were to add another curve segment to the curve a, we could find the right hand most cells of the grid, extract the curve on the y axis of each such cell, and from that and the newly provided segment make a new cell, which would append to it's right.

Type erasure wouldn't work since we would need to know the type of the newly added segment at the point of the cell creation (we would need to provide types of both segments as template parameters to the cell class).

Moving template to the cell_base class also wouldn't work, since that would mean that at the time of each cell allocation I would have to know the type of the next curve_segment.

Is there a way around this?

edit: As suggested, adding the add_curve_x method:

template<class curve1, class curve2>
template<class curve> 
cell<curve1, curve>* cell<curve1, curve2>::add_curve_x(curve_segment<curve1>* seg) {
  return new cell<curve1, curve>(seg, (curve_segment<curve>*)(this->segment_y));
}

In this case seg has to be of type curve, which has to implement curve_segment<curve1>. segment_y also has to implement curve_segment<curve>.

edit 2: explanation of why the cast is there

pic

Take the case with non-bolded rectangles. In that situations, there are two curves, curve a with 2 segments and curve b with 3 segments. class line has to implement curve_segment<line> as well as curve_segment<circle>, and circle has to implement both as well. Now let's add another bezier curve segment to curve a. class bezier has to implement curve_segment<line> and curve_segment<circle>, and line and circle have to implement curve_segment<bezier>.

Let's look how we create the middle of the bolded three cells. We would make a call

add_curve_x<bezier>(new bezier(...));

on the cell object of type cell<circle, circle>.

The argument seg will be a new bezier object (which can be cast to curve_segment<circle>), and that is also what curve type is, and segment_y will have to be cast to curve_segment<bezier>, since that's the curve type it's interacting with in the newly created cell.

share|improve this question
    
It is not clear what you are trying to do. Please show a concrete implementation of add_curve_x in cell (just imagine template virtual functions are allowed). –  n.m. Oct 17 '12 at 22:44
    
done, thanks for your time! –  vuce Oct 17 '12 at 22:51
    
Still unclear... what is this cast doing there? Can you cast any curve segment to any other one? –  n.m. Oct 17 '12 at 22:58
    
One curve can implement several curve_segments with different parameters. The implementation depends on what kind of curves might interact with each other. In this case, curves in the cell interact with curve1 and curve2, but when we add a different type of a curve segment (curve), segment_y also has to interact with that one. Imagine you have one curve consisting of two lines and one circle, and the second one of a bezier curve and a circle and a line. Then everything has to be able to interact with everything. –  vuce Oct 17 '12 at 23:03
    
In the end I can always force all curve segment to be of the same type and not have this problem, but that would reduce usefulness considerably. –  vuce Oct 17 '12 at 23:34

1 Answer 1

Add curve_segment_base:

class curve_segment_base {
   // for double dispatching here:
  virtual cell_base* add_curve_x(cell_base* cell) = 0;
};

template<class curve> 
class curve_segment : public virtual curve_segment_base { 
     // some specific methods here 
     // for double dispatching here:
     virtual cell_base* add_curve_x(cell_base* cell)
     {
         // this has to be moved to cpp file due to dependency from cell_base
         return cell->add_curve_x(this); // now the correct method from cell is called
     }
};

So you can add this method as virtual to your cell_base

class cell_base {
   virtual cell_base* add_curve_x(curve_segment_base* seg) = 0;

   // methods necessary for double dispatching here:
   virtual cell_base* add_curve_x(curve_segment<line>* seg) = 0;
   virtual cell_base* add_curve_x(curve_segment<circle>* seg) = 0;
   ...
};

So your method would look like, with double dispatching here:

template<class curve1, class curve2>
virtual cell_base* cell<curve1, curve2>::add_curve_x(curve_segment_base* seg) {
  return seg->add_curve_x(this);
}

And you will have to implement all the real implementation methods for all segments:

template<class curve1, class curve2>
virtual cell_base* cell<curve1, curve2>::add_curve_x(curve_segment<line>* seg) {
  return new cell<curve1, line>(...);
}
template<class curve1, class curve2>
virtual cell_base* cell<curve1, curve2>::add_curve_x(curve_segment<circle>* seg) {
  return new cell<curve1, circle>(...);
}
share|improve this answer
    
Thank you! This is a nice solution, but it's something I was trying to avoid, since user would have to implement add_curve_x, where there is actually no need for it. I guess I should have chosen a more appropriate language :) –  vuce Oct 19 '12 at 11:23

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