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I have a pair of classes that look something like this. There's a Generator that generates a value based on some class-level values, and a GeneratorFactory that constructs a Generator.

case class Generator[T, S](a: T, b: T, c: T) {
  def generate(implicit bf: CanBuildFrom[S, T, S]): S =
    bf() += (a, b, c) result

case class GeneratorFactory[T]() {
  def build[S <% Seq[T]](seq: S) = Generator[T, S](seq(0), seq(1), seq(2))

You'll notice that accepts an argument of type S and Generator.generate produces a value of type S, but there is nothing of type S stored by the Generator.

We can use the classes like this. The factory works on a sequence of Char, and generate produces a String because build is given a String.

val gb = GeneratorFactory[Char]()
val g ="this string")
val o = g.generate

This is fine and handles the String type implicitly because we are using the GeneratorFactory.

The Problem

Now the problem arises when I want to construct a Generator without going through the factory. I would like to be able to do this:

val g2 = Generator('a', 'b', 'c')
g2.generate // error

But I get an error because g2 has type Generator[Char,Nothing] and Scala "Cannot construct a collection of type Nothing with elements of type Char based on a collection of type Nothing."

What I want is a way to tell Scala that the "default value" of S is something like Seq[T] instead of Nothing. Borrowing from the syntax for default parameters, we could think of this as being something like:

case class Generator[T, S=Seq[T]]

Insufficient Solutions

Of course it works if we explicitly tell the generator what its generated type should be, but I think a default option would be nicer (my actual scenario is more complex):

val g3 = Generator[Char, String]('a', 'b', 'c')
val o3 = g3.generate  // works fine, o3 has type String

I thought about overloading Generator.apply to have a one-generic-type version, but this causes an error since apparently Scala can't distinguish between the two apply definitions:

object Generator {
  def apply[T](a: T, b: T, c: T) = new Generator[T, Seq[T]](a, b, c)

val g2 = Generator('a', 'b', 'c')  // error: ambiguous reference to overloaded definition

Desired Output

What I would like is a way to simply construct a Generator without specifying the type S and have it default to Seq[T] so that I can do:

val g2 = Generator('a', 'b', 'c')
val o2 = g2.generate
// o2 is of type Seq[Char]

I think that this would be the cleanest interface for the user.

Any ideas how I can make this happen?

share|improve this question
you could create a SimpleGenerator and a ComplexGenerator both with an apply method ... – sschaef Aug 4 '12 at 20:45
up vote 4 down vote accepted

Is there a reason you don't want to use a base trait and then narrow S as needed in its subclasses? The following for example fits your requirements:

import scala.collection.generic.CanBuildFrom

trait Generator[T] {
  type S
  def a: T; def b: T; def c: T
  def generate(implicit bf: CanBuildFrom[S, T, S]): S = bf() += (a, b, c) result

object Generator {
  def apply[T](x: T, y: T, z: T) = new Generator[T] {
    type S = Seq[T]
    val (a, b, c) = (x, y, z)

case class GeneratorFactory[T]() {
  def build[U <% Seq[T]](seq: U) = new Generator[T] {
    type S = U
    val Seq(a, b, c, _*) = seq: Seq[T]

I've made S an abstract type to keep it a little more out of the way of the user, but you could just as well make it a type parameter.

share|improve this answer
I like this solution since it covers all the cases without too much added complexity. One thing to note is that making S a type parameter means that generate has the correct return type (String, Seq[Char], etc) instead of a return type like g.S. – dhg Aug 4 '12 at 21:45

This does not directly answer your main question, as I think others are handling that. Rather, it is a response to your request for default values for type arguments.

I have put some thought into this, even going so far as starting to write a proposal for instituting a language change to allow it. However, I stopped when I realized where the Nothing actually comes from. It is not some sort of "default value" like I expected. I will attempt to explain where it comes from.

In order to assign a type to a type argument, Scala uses the most specific possible/legal type. So, for example, suppose you have "class A[T](x: T)" and you say "new A[Int]". You directly specified the value of "Int" for T. Now suppose that you say "new A(4)". Scala knows that 4 and T have to have the same type. 4 can have a type anywhere between "Int" and "Any". In that type range, "Int" is the most specific type, so Scala creates an "A[Int]". Now suppose that you say "new A[AnyVal]". Now, you are looking for the most specific type T such that Int <: T <: Any and AnyVal <: T <: AnyVal. Luckily, Int <: AnyVal <: Any, so T can be AnyVal.

Continuing, now suppose that you have "class B[S >: String <: AnyRef]". If you say "new B", you won't get an B[Nothing]. Rather you will find that you get a B[String]. This is because S is being constrained as String <: S <: AnyRef and String is at the bottom of that range.

So, you see, for "class C[R]", "new C" doesn't give you a C[Nothing] because Nothing is some sort of default value for type arguments. Rather, you get a C[Nothing] because Nothing is the lowest thing that R can be (if you don't specify otherwise, Nothing <: R <: Any).

This is why I gave up on my default type argument idea: I couldn't find a way to make it intuitive. In this system of restricting ranges, how do you implement a low-priority default? Or, does the default out-priority the "choose the lowest type" logic if it is within the valid range? I couldn't think of a solution that wouldn't be confusing for at least some cases. If you can, please let me know, as I'm very interested.

edit: Note that the logic is reversed for contravariant parameters. So if you have "class D[-Q]" and you say "new D", you get a D[Any].

share|improve this answer

One option is to move the summoning of the CanBuildFrom to a place where it (or, rather, its instances) can help to determine S,

case class Generator[T,S](a: T, b: T, c: T)(implicit bf: CanBuildFrom[S, T, S]) {
  def generate : S =
    bf() += (a, b, c) result

Sample REPL session,

scala> val g2 = Generator('a', 'b', 'c')
g2: Generator[Char,String] = Generator(a,b,c)

scala> g2.generate
res0: String = abc


The GeneratorFactory will also have to be modified so that its build method propagates an appropriate CanBuildFrom instance to the Generator constructor,

case class GeneratorFactory[T]() {
  def build[S](seq: S)(implicit conv: S => Seq[T], bf: CanBuildFrom[S, T, S]) =
    Generator[T, S](seq(0), seq(1), seq(2))

Not that with Scala < 2.10.0 you can't mix view bounds and implicit parameter lists in the same method definition, so we have to translate the bound S <% Seq[T] to its equivalent implicit parameter S => Seq[T].

share|improve this answer
This is great for direct construction of Generator, but unfortunately it causes a "not enough arguments for method apply" compilation error in – dhg Aug 4 '12 at 21:15
@dhg: You can fix that part by adding an implicit argument: def build[S](seq: S)(implicit conv: S => Seq[T], cbf: CanBuildFrom[S, T, S]) = .... – Travis Brown Aug 4 '12 at 21:19
The fact that you can't just write Generator(1, 2, 3) is still a problem, though. – Travis Brown Aug 4 '12 at 21:26
Thanks for the update. I assume this works for the Char/String case since there's an implicit Seq[Char] => String CanBuildFrom in predef? Unfortunately I'll need it to work even when no implicit CanBuildFrom to be found (as in Generator(1,2,3)) – dhg Aug 4 '12 at 21:35

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