proper class hierarchy for 2D and 3D vectors

I want to have a general vector abstract class / trait that specifies certain methods, e.g.:

``````trait Vec
{
def +(v:Vec):Vec
def *(d:Double):Vec

def dot(v:Vec):Double
def norm:Double
}
``````

I want to have `Vec2D` and `Vec3D` extend `Vec`:

``````class Vec2D extends Vec { /* implementation */ }
class Vec3D extends Vec { /* implementation */ }
``````

But how can I, for instance, make it so that `Vec2D` can only be added to other `Vec2D` and not to `Vec3D`?

Right now I'm just implementing `Vec2D` and `Vec3D` without a common `Vec` ancestor, but this is getting tedious with duplicate code. I have to implement all my geometry classes that depend on these classes (e.g. `Triangle`, `Polygon`, `Mesh`, ...) twice, once for `Vec2D` and again for `Vec3D`.

I see the java implementations: `javax.vecmath.Vector2d` and `javax.vecmath.Vector3d` do not have a common ancestor. What's the reason for this? Is there a way to overcome it in scala?

-

As requested, the most useful way of designing the base trait involves both the CRTP and the self-type annotation.

``````trait Vec[T <: Vec[T]] { this: T =>
def -(v: T): T
def *(d: Double): T

def dot(v: T): Double
def norm: Double = math.sqrt(this dot this)
def dist(v: T) = (this - v).norm
}
``````

Without the self-type, it is not possible to call `this.dot(this)` as `dot` expects a `T`; therefore we need to enforce it with the annotation.

On the other hand, without CRTP, we’ll fail to call `norm` on `(this - v)` as `-` returns a `T` and thus we need to make sure that our type `T` has this method, e.g. declare that `T` is a `Vec[T]`.

-

You can use self types:

``````trait Vec[T] { self:T =>
def +(v:T):T
def *(d:Double):T

def dot(v:T):Double
def norm:Double
}

class Vec2D extends Vec[Vec2D] { /* implementation */ }
class Vec3D extends Vec[Vec3D] { /* implementation */ }
``````

But if both implementations are very similar, you could also try to abstract over the Dimension.

``````sealed trait Dimension
case object Dim2D extends Dimension
case object Dim3D extends Dimension

sealed abstract class Vec[D <: Dimension](val data: Array[Double]) {

def +(v:Vec[D]):Vec[D] = ...
def *(d:Double):Vec[D] = ...

def dot(v:Vec[D]):Double = ...
def norm:Double = math.sqrt(data.map(x => x*x).sum)
}

class Vec2D(x:Double, y:Double) extends Vec[Dim2D.type](Array(x,y))
class Vec3D(x:Double, y:Double, z:Double) extends Vec[Dim3D.type](Array(x,y,z))
``````

Of course it depends on how you want to represent the data, and if you want to have mutable or immutable instances. And for "real world" applications you should consider http://code.google.com/p/simplex3d/

-
Self types allow you to refer to `this`, whereas the CRTP pattern in Dario's answer does not. –  dsg Jan 23 '11 at 15:50
@dsg: What do you mean you can’t refer to `this` with CRTP? –  Debilski Jan 23 '11 at 23:15
Right, you can’t. –  Debilski Jan 24 '11 at 0:29

I'm not sure about the proper Scala syntax, but you can implement the CRTP, i.e. define the actual type through a generic parameter.

``````trait Vec[V <: Vec[V]] {
def +(v:V):V
...
}

class Vec2D extends Vec[Vec2D] { }
class Vec3D extends Vec[Vec3D] { }

class Polygon[V <: Vec[V]] {
...
}
``````
-
Spot on. Syntax is correct and everything! I guess java does not support this (otherwise what's the deal with `javax.vecmath`)? –  dsg Jan 23 '11 at 12:13
Actually, I guess java does support this: stackoverflow.com/questions/2382915/… –  dsg Jan 23 '11 at 12:56