Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

How does one declare in Scala the type signatures needed to implement multiple arithmetic systems that all share a same trait declaring the operations? I thought I had it solved until I tried to add some helper implementations to the base trait/class. In the following code-snippet (which compiles) notice that sq() is defined as this*self not the more obvious this*this. And self() can not be implemented in the trait either (we have to wait until we get to a concrete extending class to implement it).

trait NumberBase [NUMBERTYPE <: NumberBase[NUMBERTYPE]] {
   // type NUMBERTYPE >: this.type
   def self:NUMBERTYPE
   def sq:NUMBERTYPE = { this*self }

class D(val v:Double) extends NumberBase[D] {
   def self:D = { this }
   def *(that: D):D = { new D(this.v*that.v) }

The question/goal is: remove the use of self() or (at least move self()'s implementation into NumberBase) without changing the type signature of * in D. A lot of the fixes in the above link make the derived class unimplementable (things like new D() not being a type returnable by * or * having an unguessable type signature in D). I don't mind some of the signatures getting uglier- but I would like the code to express what this code expresses: that the derived classes work on their own types only and return instances of their own type (they are not moving up and down in a hierarchy).

I found some discussion here that lists some problems (but don't see a solution): . Some issues you don't run into until you see both the base class and the implementation.

Complete code with the work-around given above (forcing implementing classes to implement self()) is given here: where we use the fact different arithmetic systems share the same base-class or trait to write functions that are generic over different arithmetic implementations. This lets us use a wrapping of standard machine arithmetic (like D) or something else (like a number system that computes gradients as a side-effect).

share|improve this question
This is also relevant: – Daenyth Jul 1 '15 at 22:06
up vote 3 down vote accepted

I think you want to use a self-type, which will ensure that the NumberBase[N] instance will also be an instance of type N:

trait NumberBase[N <: NumberBase[N]] { this: N =>
  def *(that: N): N
  def sq: N = this * this

class D(val v: Double) extends NumberBase[D] {
  def *(that: D): D = new D(this.v * that.v)

val a = new D(0.5)
val b = new D(0.25)

a * b  // D(0.125)
a.sq   // D(0.25)

BUT, if you really want to define a new type of number, you should do what the Scala libraries themselves do and use the Numeric typeclass.

share|improve this answer
Thank you very much. Not only did that fix my toy example, it was exactly the problem in the larger code. – jmount Sep 23 '12 at 22:49

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.