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In the following, I will present only very reduced versions of my Scala code. Just enough to show the problem. Unnecessary blocks of code will be reduced to ....

The part that works

I have created a vector library (that is, for modeling mathematical vectors, not vectors in the sense of scala.collection.Vector). The basic trait looks like this:

trait Vec[C] extends Product {
  def -(o:Vec[C]):Vec[C] = ...
  ...
}

I have created numerous subtypes for specific vectors, like Vec2 for two-dimensional vectors, or Vec2Int specialized for two-dimensional Int vectors.

The subtypes narrow the return types of some operations. For example, subtracting a Vec2Int from another vector will not return a generic Vec[Int], but the more specific Vec2Int.

Additionally, I have declared those methods in very specific subtypes like Vec2Int as final, thereby allowing the compiler to elect those methods for inlining.

This works very well, and I have created a fast and usable library for vector calculations.

Building on top of that, I now want to create a set of types to model basic geometrical shapes. The basic shape trait looks like this:

trait Shape[C, V <: Vec[C]] extends (V=>Boolean) {
  def boundingBox:Box[C,V]
}

Where Box would be a subtype of Shape, modeling an n-dimensional box.

The part that does not work

Now, I tried to define box:

trait Box[C, V <: Vec[C]] extends Shape[C,V] {
  def lowCorner:V
  def highCorner:V
  def boundingBox = this
  def diagonal:V = highCorner - lowCorner // does not compile
}

The diagonal method does not compile, because the method Vec.- returns Vec[C], not V.

Of course, I could make diagonal return a Vec[C], but this would be unacceptable in many ways. For once, I would lose the compiler optimization for specific Vec subtypes. Also, When you for example have a box described by two two-dimensional Float vectors (Vec2Float), it makes a lot of sense to assume that the diagonal is also a Vec2Float. I do not want to lose that information.

My attempt to fix the problem

Following the example of the Scala collection hierarchy, I introduced a type VecLike:

trait VecLike[C, +This <: VecLike[C,This] with Vec[C]] {
  def -(o:Vec[C]):This
  ...
}

and I made Vec extend it:

trait Vec[C] extends Product with VecLike[C, Vec[C]] ...

(I would then go on to create more specific subtypes of VecLike, like Vec2Like or Vec3Like, to accompany my hierarchy of Vec types.)

Now, the new definition for Shape and Box looks like this:

trait Shape[C, V <: VecLike[C,V] with Vec[C]] ...

trait Box[C, V <: VecLike[C,V] with Vec[C]] extends Shape[C,V] {
  ...
  def diagonal:V = highCorner - lowCorner 
}

Still, the compiler complains:

Error: type mismatch;
found: Vec[C]
required: V

This confuses me. The type VecLike clearly returns This in the minus method, which translates to the type parameter V of the Box type. I can see that the minus method of Vec still returns Vec[C], but why cannot the compiler at this point use the return type of VecLike's minus method?

How can I fix this problem?

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1  
Just a word of advice--I tried doing this a while ago and ran into some of the same problems, plus problems with specialization. I found that it ended up being considerably easier to write a code generator to make a small vector/matrix library. –  Rex Kerr Feb 24 '11 at 1:49
    
@Rex Kerr: Thanks for the advice. This is my second try. In the first try, I ended up with too many specific classes, and unmanageable code. This time, I limited specialization to 1, 2 and 3 dimensions and five numerical types. Should I need more in the future or find the code base unmanageable, I definitely will use a code generator. Which one did you use? Any recommendations? –  Madoc Feb 24 '11 at 1:56
1  
I wrote my own code generator in Scala, and have dimensions 2-4 for vectors and square matrices, and the five most useful primitive types (Short, Int, Long, Float, Double). (Actually, the generator can generate arbitrary dimensions, but the size of the generated library starts getting unwieldy past 4.) The generator's only about 1k lines of code, and it does things that I was never able to figure out how to do correctly with specialization (e.g. conversions between types and promotion of Long+Float to Double). I wish you the best of luck! It is nicer to work with code than a code generator. –  Rex Kerr Feb 24 '11 at 2:07
    
@Rex Kerr: Thanks a lot for those comments. It is amazing how similar our ideas are - I specialized for exactly the same primitive types as you did, and I have also consider writing a code generator in Scala. So far, I did not do it because I have too much respect before such a task. But it's great to see how you did exactly that and ended up successfully with a useful library. –  Madoc Feb 24 '11 at 2:13
    
@Madoc - Incidentally, if you want to see what I did, I uploaded an alpha version a while ago to code.google.com/p/shipvl –  Rex Kerr Feb 24 '11 at 20:18

1 Answer 1

up vote 6 down vote accepted

My advice is to work much less hard on omitting the code you think is irrelevant, and just show the code. It's really amazing how often people manage to remove the part which matters. The mantra is "if you don't know why it doesn't work, then you don't know what is relevant." This is very serious, genuine advice: I can help you in five seconds if you give me code which would compile except for the thing you don't understand, or I can help you in five minutes if I have to reconstruct all the pieces you left out. Guess which one happens more often.

On to the code. It compiles exactly as given, after I make guesses about how the bits from the first attempt fill into the second attempt. (This "guessing" phase is another good reason to show the code up front.)

trait VecLike[C, +This <: VecLike[C, This] with Vec[C]] {
  def -(o: Vec[C]): This
}

trait Vec[C] extends Product with VecLike[C, Vec[C]] { }

trait Shape[C, V <: VecLike[C,V] with Vec[C]] { }

trait Box[C, V <: VecLike[C,V] with Vec[C]] extends Shape[C, V] {
  def lowCorner: V
  def highCorner: V
  def boundingBox = this
  def diagonal: V = highCorner - lowCorner 
}

% scalac281 a.scala 
%
share|improve this answer
    
Since my Vec type with its companion alone has 121 lines of code, I chose to shorten it. When you add the minus method in your code example to Vec, as in the first code block of my question, then the code won't compile any more. (def -(o:Vec[C]):Vec[C] = ...) Omitting the return type of the minus method does not help either. The only option that works is to remove the definition of the minus method from Vec completely. Although I still don't understand exactly why, this helps me. I will pull the default implementations for VecLike methods out of Vec. Thanks! –  Madoc Feb 24 '11 at 14:55
    
The definition of - you just described declares itself to return Vec[C]. The declaration of diagonal declares itself to return V, which is some subtype of Vec[C]. Supplying an AnyRef doesn't mean you get a String, even if the AnyRef happens to be a String. You need the return type of the method to move in unison with V -- that is what "This" achieves in VecLike, and why it works there and not in Vec. –  extempore Feb 24 '11 at 15:34
    
@extempore: - is defined and inherited twice; once in Vec and once in VecLike. While the Vec definition returns Vec, the VecLike definition returns This. So it seems to me like the Scala compiler could have a choice as to which one it follows in diagonal. If it would follow the one from VecLike, then there would be no problem at all. So why does it choose to follow the one from Vec? And how could I implement - in Vec to return This? There is no This type parameter variable in Vec... –  Madoc Feb 24 '11 at 16:38
    
@Madoc - If you follow the example of the Scala collections, XLike does almost everything while X itself does almost nothing. So the question is: why have - in Vec at all, if VecLike has it? –  Rex Kerr Feb 24 '11 at 20:17
    
I don't know what you mean about a choice. In your code you are making a claim that is not true: the method doesn't return V. Nobody has any choice in this matter. If the - method is defined twice (this is another detail which you did not make at all clear) then the implementation must satisfy both: it must be "This" and "V". Since it isn't V, you're no closer. –  extempore Feb 25 '11 at 5:04

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