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I'm looking for a neat way to implement a cool design pattern for my geometry collection. Right now I've got a trait called Geometry at the top of my geometry type hierarchy. The idea is to let every geometry inherit the trait and then implement specific code for the specific types of geometry. As geometric objects these geometries needs to implement various methods of course. Take for example the ability to calculate the distance to any other geometry - I've termed that distanceTo. The most clean way to do it must be to have a method in the Geometry trait like so:

def distanceTo(geometry : Geometry) : Double

My problem is this: How do I implement this method in a geometry (say a Rectangle) without having to type-check for every shape that exists? Are there any handy ways to delegate the requests to the individual geometries?

Cheers,

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You may want to look up "double dispatch" and "visitor pattern". These things do not free you from the need to implement N^2 or so variants of your function, they just make the job a bit easier and let you do it in more organized fashion. –  n.m. Nov 24 '11 at 21:39
    
double dispatch and the visitor pattern are a good way to do it in languages like Java, that lack both (language level) multiple dispatch and pattern matching. But the visitor pattern is quite cumbersome and requires a lot of boilerplate code. –  Kim Stebel Nov 24 '11 at 21:44
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1 Answer

up vote 2 down vote accepted

Since Scala doesn't have multiple dispatch, your best bet is pattern matching on pairs of geometric objects. Something like

(geo1, geo2) match {
  case (Rectangle(x1,y1,w1,h1), Rectangle(x2,y2,w2,h2)) => ....
  ...
}

You could then define a convenience method on the Geometry trait that calls this method. If Geometry is a sealed trait, the compiler will even warn you about missing cases when pattern matching.

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Yes that was what I thought. I had hoped there were a better solution, but I think I'm going to stick with the N^2 variants instead. Thanks for your replies! –  Jens Egholm Nov 25 '11 at 14:04
    
Don't forget to use recursion to shave off half the cases. Only write the code for (Rectangle, Circle) and make the last case in the above match say case (a,b) => distance(b,a) assuming the function is called distance. (Circle, Rectangle) is then handled for you. –  Bart Schuller Nov 26 '11 at 17:26
    
@Bart: That's a bad idea, because if you miss a combination it will go into an infinite loop. A better idea to achieve the same effect is to sort the pair by the types of the shapes first. –  Kim Stebel Nov 26 '11 at 17:40
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