# Compile-time check for vector dimension

I am implementing some lightweight mathematical vectors in scala. I would like to use the type system to check vector compatibility at compile time. For example, trying to add a vector of dimension 2 to another vector of dimension 3 should result in a compile error.

So far, I defined dimensions as case classes:

``````sealed trait Dim
case class One() extends Dim
case class Two() extends Dim
case class Three() extends Dim
case class Four() extends Dim
case class Five() extends Dim
``````

And here is the vectors definition:

``````class Vec[D <: Dim](val values: Vector[Double]) {

def apply(i: Int) = values(i)

def *(k: Double) = new Vec[D]( values.map(_*k) )

def +(that: Vec[D]) = {
val newValues = ( values zip that.values ) map {
pair => pair._1 + pair._2
}
new Vec[D](newValues)
}

override lazy val toString = "Vec(" + values.mkString(", ") + ")"

}
``````

This solution works well, however I have two concerns:

• How can I add a `dimension():Int` method that returns the dimension (ie. 3 for a `Vec[Three]`)?

• How can I handle higher dimensions without declaring all the needed case classes in advance ?

PS: I know there are nice existing mathematical vector libs, I am just trying to improve my scala understanding.

-

My suggestions:

-
Aaahhh, the joys of type-level programming. –  Jörg W Mittag Feb 12 '11 at 17:14
Yes but to solve my problem, how can I "convert" a peano type to an Int and how can I build automatically the correct peano type corresponding to a given Int ? –  paradigmatic Feb 13 '11 at 11:44
@paradigmatic You can't do Int -> Peano. That requires dependent types, which is not supported by Scala. Converting Peano to Int it trivial and left as an exercise to the reader. ;-) For languages that do support dependent types, see Agda and Coq. –  Daniel C. Sobral Feb 13 '11 at 15:43

I's suggest something like this:

``````sealed abstract class Dim(val dimension:Int)

object Dim {
class One extends Dim(1)
class Two extends Dim(2)
class Three extends Dim(3)

implicit object One extends One
implicit object Two extends Two
implicit object Three extends Three
}

case class Vec[D <: Dim](values: Vector[Double])(implicit dim:D) {

require(values.size == dim.dimension)

def apply(i: Int) = values(i)

def *(k: Double) = Vec[D]( values.map(_*k) )

def +(that: Vec[D]) = Vec[D](
( values zip that.values ) map {
pair => pair._1 + pair._2
})

override lazy val toString = values.mkString("Vec(",", ",")")
}
``````

Of course you can get only a runtime check on the vector length that way, but as others pointed already out you need something like Church numerals or other typelevel programming techniques to achieve compile time checks.

``````  import Dim._
val a = Vec[Two](Vector(1.0,2.0))
val b = Vec[Two](Vector(1.0,3.0))
println(a + b)
//--> Vec(2.0, 5.0)

val c = Vec[Three](Vector(1.0,3.0))
//--> Exception in thread "main" java.lang.ExceptionInInitializerError
//-->        at scalatest.vecTest.main(vecTest.scala)
//--> Caused by: java.lang.IllegalArgumentException: requirement failed
``````
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If you don't wish to go down the Peano route, you could always have your `Vec` be constructed with a `D` and then use the instance for determine the dimension via the `Dim` companion object. For instance:

``````object Dim {
def dimensionOf(d : Dim) = d match {
case One => 1
case Two => 2
case Three => 3
}
}
sealed trait Dim
``````

I think for choice, you should be using case objects rather than case classes:

``````case object One extends Dim
case object Two extends Dim
``````

Then on your vector, you might have to actually store the Dim:

``````object Vec {
def vec1 = new Vec[One](One)
def vec2 = new Vec[Two](Two)
def vec3 = new Vec[Three](Three)
}

class Vec[D <: Dim](d : D) {
def dimension : Int = Dim dimensionOf d
//etc
``````
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