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I'm new to Scala, and I'm trying to use type bounds to avoid code duplication in the following code (cleaned from irrelevant stuff):

trait StandardStep1[-I1] {
  def next_step(i:I1):StandardStep2
}

trait StandardStep2

trait UniqueStep1[-I1] extends StandardStep1[I1] {
  def next_step(i:I1):UniqueStep2
}

trait UniqueStep2 extends StandardStep2

class DoubleStandardStep1[-IL,-IR](left:StandardStep1[IL], right:StandardStep1[IR]) extends StandardStep1[(IL,IR)] {
  def next_step(i:(IL,IR)) = {
    val (i_left, i_right) = i
    val new_left = left.next_step(i_left)
    val new_right = right.next_step(i_right)
    new DoubleStandardStep2(new_left, new_right)
  }
}

class DoubleStandardStep2(left:StandardStep2, right:StandardStep2) extends StandardStep2

class DoubleUniqueStep1[-IL,-IR](left:UniqueStep1[IL], right:UniqueStep1[IR]) extends UniqueStep1[(IL,IR)] {
  def next_step(i:(IL,IR)) = {
    val (i_left, i_right) = i
    val new_left = left.next_step(i_left)
    val new_right = right.next_step(i_right)
    new DoubleUniqueStep2(new_left, new_right)
  }
}

class DoubleUniqueStep2(left:UniqueStep2, right:UniqueStep2) extends UniqueStep2

Explanation:

StandardStep1 represents a step in some state machine, and has a next_step operation that gives a StandardStep2 for a given input.

UniqueStep1 is a special type of StandardStep1 which gives a UniqueStep2 when it's next_step is called - and obviously UniqueStep2 has to inherit from StandardStep2 for that.

Now I had to write a DoubleStep wrappers: DoubleStandardStep1 wraps too StandardStep1s, and returns a DoubleStandardStep2 when its next_step is called. DoubleUniqueStep1 does the same thing, but it returns a DoubleUniqueStep2.

The implementation of the *DoubleStep*s' next_step has an obvious code duplication: they both split the input into i_left and i_right and call their wrapped steps' next_step in the same way.

I wondered how to eliminate this code duplication, by creating a generic abstract DoubleStep1 that will do this part of the code:

object DoubleStepHelper {
  def next_step_args[IL,IR,SL <: StandardStep1[IL],SR <: StandardStep1[IR]](left:SL,right:SR)(i:(IL,IR)) = { 
    val (i_left, i_right) = i
    val new_left = left.next_step(i_left)
    val new_right = right.next_step(i_right)
    (new_left, new_right)
  }
}

class DoubleStandardStep1[-IL,-IR](left:StandardStep1[IL], right:StandardStep1[IR]) extends StandardStep1[(IL,IR)] {
  def next_step(i:(IL,IR)) = {
    ((l,r) => new DoubleStandardStep2(l,r)).tupled(DoubleStepHelper.next_step_args(left,right)(i))
  }
}

class DoubleStandardStep2(left:StandardStep2, right:StandardStep2) extends StandardStep2


class DoubleUniqueStep1[-IL,-IR](left:UniqueStep1[IL], right:UniqueStep1[IR]) extends UniqueStep1[(IL,IR)] {
  def next_step(i:(IL,IR)) = {
    ((l,r) => new DoubleUniqueStep2(l,r)).tupled(DoubleStepHelper.next_step_args(left,right)(i))
  }
}

class DoubleUniqueStep2(left:UniqueStep2, right:UniqueStep2) extends UniqueStep2

Trying to compile this code (scala 2.9.2) fails with the message:

type mismatch;
 found   : (this.StandardStep2, this.StandardStep2)
 required: (this.UniqueStep2, this.UniqueStep2)
    ((l,r) => new DoubleUniqueStep2(l,r)).tupled(DoubleStepHelper.next_step_args(left,right)(i))
                                                                                            ^

I assume this happens because DoubleStepHelper.next_step_args is assumed to return a (StandardStep2, StandardStep2) value, which is bad when we want wrap it with DoubleUniqueStep2.

Can you think of a way to solve this issue? How to tell the compiler that DoubleStepHelper's next_step_args may return a (UniqueStep2, UniqueStep2) if SL and SR inherit from UniqueStep1?

A nice feature could be to be able to define the result type of next_step_args to something like (SL.next_step, SR.next_step), meaning that its return type is built from the return types of specific functions (next_step) in SL and SR.

Could "view" bounds solve it in any way?

I could force casting using asInstanceOf, but this looks ugly.

Thanks

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1 Answer

I found a nice solution. I created AbstractStep1 and AbstractDoubleStep1 in which the type of the following step is given as as a type parameter.

Then I can inherit from this class with the cases where the next-step is StandardStep2 or UniqueStep2.

So here's the code:

trait AbstractStep1[-I,+S2] {
  def next_step(i:I):S2
}

trait StandardStep1[-I] extends AbstractStep1[I,StandardStep2]

trait StandardStep2

trait UniqueStep1[-I] extends AbstractStep1[I,UniqueStep2] with StandardStep1[I]

trait UniqueStep2 extends StandardStep2

abstract class AbstractDoubleStep1[-IL,-IR,-S2L <: StandardStep2,-S2R <: StandardStep2,+S2](left:AbstractStep1[IL,S2L],right:AbstractStep1[IR,S2R]) extends AbstractStep1[(IL,IR),S2] {
  def wrapper(l:S2L,r:S2R):S2

  def next_step(i:(IL,IR)):S2 = {
    val (i_left, i_right) = i
    val new_left = left.next_step(i_left)
    val new_right = right.next_step(i_right)
    wrapper(new_left, new_right)
  }
}

class DoubleStandardStep1[-IL,-IR](left:StandardStep1[IL], right:StandardStep1[IR]) extends AbstractDoubleStep1[IL,IR,StandardStep2,StandardStep2,DoubleStandardStep2](left,right) {
  def wrapper(l:StandardStep2,r:StandardStep2) = {
    new DoubleStandardStep2(l,r)
  }
}

class DoubleStandardStep2(left:StandardStep2, right:StandardStep2) extends StandardStep2


class DoubleUniqueStep1[-IL,-IR](left:UniqueStep1[IL], right:UniqueStep1[IR]) extends AbstractDoubleStep1[IL,IR,UniqueStep2,UniqueStep2,DoubleUniqueStep2](left,right) {
  def wrapper(l:UniqueStep2,r:UniqueStep2) = {
    new DoubleUniqueStep2(l,r)
  }
}

class DoubleUniqueStep2(left:UniqueStep2, right:UniqueStep2) extends UniqueStep2

I think it is also possible to convert AbstractDoubleStep1 to a triat instead of an abstract class, which will make it more useful in mixin inheritence, but this is not important to me at the moment.

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