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I'd like to define a trait with some properties which have a well defined relationship - for example's sake, let's say that a * b = c. The idea is that implementations of this trait can provide two of these and have an accessor for the the third property derived automatically.

(This is the same feature as Haskell's type classes, if I remember those correctly, where if you defined < from Ord, >= would be implemented as ! . < - though you could define any subset of functions so long as the remainder could be inferred.) (I don't remember Haskell's type classes correctly.)

The naïve approach actually works fairly well:

trait Foo {
  // a * b = c
  def a: Double = c / b
  def b: Double = c / a
  def c: Double = a * b
}

class FooOne(override val a: Double, override val b: Double) extends Foo
class FooTwo(override val a: Double, override val c: Double) extends Foo

Here, implementations FooOne and FooTwo are complete implementations of Foo, and behave as expected. So far, so good; this approach does allow classes to define two of the properties and get the third one "for free".

However, things start to look less rosy if one defines a third class:

class FooFail(override val a: Double) extends Foo

This compiles just fine - however, it will cause a stack overflow if its b or c methods are ever evaluated.


So the naïve approach gives the inference aspect of Haskell's type class approach, but we don't have compile-time safety. What I'd like is for the compiler to complain if less than two of the methods are defined by implementing classes. Clearly the current syntax isn't sufficient here; we need the methods to be considered abstract, albeit with a default implementation which can be used if and only if the dependent methods are non-abstract.

Does Scala expose appropriate semantics to define this? (I don't have a problem if there's a somewhat roundabout way of defining it, similar to union types, since I'm not aware of any first-class support for this in the language).

If not, I'll make do with the naïve approach and just define and test my classes carefully. But I really think this is something that the type system should be able to catch (after all - it's not Ruby. :)).

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2  
Unless I misremember completely, Haskell uses precisely the same naïve approach with the same problem. –  Alexey Romanov Sep 8 '11 at 10:33
    
@Alexey - interesting comment. It's been a while, but I seem to recall that if you didn't define enough of the methods you'd get a compiler/interpreter error along the lines that it wasn't possible to derive all the methods for the type class. Maybe I'll try to reproduce this, and read up on how Haskell does it, for inspiration. –  Andrzej Doyle Sep 8 '11 at 10:50
    
OK, having tested this in Haskell it does indeed suffer from the same problem (it's equivalent to the Scala situation in that it only warns about fully abstract methods). That said, the question still stands, albeit without the precedent in another language. –  Andrzej Doyle Sep 8 '11 at 11:45
    
I'm not sure that a compile-time check that at least two are defined would make me feel safer in any way; you could always override with the same definition, or even with override def a = a. –  Philippe Sep 8 '11 at 14:55
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3 Answers

up vote 6 down vote accepted

Use implicits:

object test {
  case class A(v : Double)
  case class B(v : Double)
  case class C(v : Double)

  implicit def a(implicit b : B, c : C) = A(c.v / b.v)
  implicit def b(implicit a : A, c : C) = B(c.v / a.v)
  implicit def c(implicit a : A, b : B) = C(a.v * b.v)

  def foo(implicit a : A, b : B, c : C) = 
    a + ", " + b + ", " + c

  // Remove either of these and it won't compile
  implicit val aa = A(3)
  implicit val bb = B(4)

  def main(args : Array[String]) {
    println(foo)
  }
}
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Very interesting approach - as per my comment to didierd I suspect implicits will be key in getting the compiler to check that sufficient defintions exist. It's a shame that consumers can't just declare val b = 5 any more, though. I wonder if this can be massaged via another internal layer of traits. –  Andrzej Doyle Sep 8 '11 at 10:59
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How do you get safety in Haskell? I'm not very familiar with the language, but I can do

data Func = Func (Int -> Int) 
instance Eq Func
instance Ord Func

compared = Func (\i ->  i-1) < Func (\i -> i+1)

and get a stack overflow when evaluating compared.

I can imagine a workaround in scala but a rather feeble one. First, leave Foo fully abstract

trait Foo { def a: Double; def b: Double; def c: Double }

Then create mixin traits for each method definition combination allowed

trait FooWithAB extends Foo {def c : Double = a * b}
trait FooWithAC extends Foo {def b : Double = c / a}
trait FooWithBC extends Foo {def a : Double = c / b}

FooOne and FooTwo will have to mix in one of the trait. In FooFail, nothing prevents you to mix in two of them, and still fail, but you have been somewhat warned.

Is is possible to go one step further and forbid mixing two of them, with a kind of phantom type

trait Foo {
  type t;
  def a: Double; def b: Double; def c: Double
}
trait FooWithAB extends Foo {type t = FooWithAB; def c : Double = a * b}
trait FooWithAC extends Foo {type t = FooWithAC; def b : Double = c / a}
trait FooWithBC extends Foo {type t = FooWithBC; def c : Double = c / b}

This prevent mixing two of the FooWithXX, you cannot define

class FooFail(val a: Double) extends FooWithAC with FooWithAB
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Good point - I suspect any solution will involve leaving the methods fully abstract in Foo, and then mixing in default definitions from somewhere. The phantom type approach is interesting, though it's a shame that the clunkiness is exposed to consumers who have to explicitly mix in the trait. Perhaps implicit conversions could work around this somehow, hmm... –  Andrzej Doyle Sep 8 '11 at 10:53
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A solution slightly weaker than what you may want is the following:

trait Foo {
  def a : Double
  def b : Double
  def c : Double
}

// Anything with two out of three can be promoted to Foo status.
implicit def ab2Foo(ab : { def a : Double; def b : Double }) =
  new Foo { val a = ab.a; val b = ab.b; def c = ab.a * ab.b }
implicit def bc2Foo(bc : { def b : Double; def c : Double }) =
  new Foo { val a = bc.c / bc.b; val b = bc.b; def c = bc.c }
implicit def ac2Foo(ac : { def a : Double; def c : Double }) =
  new Foo { val a = ac.a; val b = ac.c / ac.a; def c = ac.c }

Here, any class with two of the three a, b, c methods can be viewed and used as a Foo. For example:

case class AB(a : Double, b : Double)
AB(5.0, 7.1).c // prints 35.5

But if you try for instance:

case class ABC(a : Double, b : Double, c : Double)
val x : Foo = ABC(1.0, 2.0, 3.0)

...you get an "ambiguous implicit" error.

The main problem w.r.t your original statement is that the classes don't properly inherit from Foo, which may be a problem if you wanted to reuse other methods. You can work around it though by having another trait FooImpl that contains these other methods, and restrict the implicit conversions to subtypes of FooImpl.

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I like what you've done here, using structural types together with implicit conversions in order to perform the check at compile time, without placing any extra requirements on consumers. I agree that not being a Foo isn't ideal, but I fear that may be unavoidable in order to get both of the other requirements (else the methods in Foo have to be both simultaneously abstract and defined). –  Andrzej Doyle Sep 8 '11 at 16:49
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