Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I fail to understand why I am getting an “inferred type arguments do not conform to type parameter bounds”. First, I defined a trait called CS which may be implemented by several classes (e.g., CS01 and CS02):

trait CS[+T <: CS[T]] {
  this: T =>
  def add: T
  def remove: T
}

class CS01 extends CS[CS01] {
  def add: CS01 = new CS01
  def remove: CS01 = new CS01
}

class CS02 extends CS[CS02] {
  def add: CS02 = new CS02
  def remove: CS02 = new CS02
}

The idea is to keep the implemented type when calling add or remove on CS01 and CS02. Secondly, I would like to define operations that may be executed on every classes compliant with trait CS. Then, I defined a trait called Exec(with two very simple examples of classes Exec01 and Exec02 mixin the Exec traits):

trait Exec {
  def exec[U <: CS[U]](x: U): U
}

class Exec01 extends Exec {
  def exec[U <: CS[U]](x: U): U = x.add
}

class Exec02 extends Exec {
  def exec[U <: CS[U]](x: U): U = x.remove
}

Once again, I need to keep the implemented type of the class that mixes the CS trait. That is why exec is parametrized with [U <: CS[U]].

Finally, I want any CS enabling operations on it to mixin the trait Executable which makes it possible to execute an operation that follows trait Exec:

trait Executable[T <: CS[T]] {
  this: T =>
  def execute(e: Exec): T = e.exec(this)
}

However, I get the following error when I am trying to compile:

error: inferred type arguments [this.Executable[T] with T] do not conform to method exec's type parameter bounds [U <: this.CS[U]]
  def execute(e: Exec): T = e.exec(this)
                              ^

I don't quite understand because any classes that mix Executable must be of type T with the constraint of mixin the CS trait due to the bound in trait Executable[T <: CS[T]]. So, why this does not conform to the type parameter bound U <: CS[U] ?

share|improve this question
add comment

2 Answers 2

up vote 3 down vote accepted

Works if you specify the type parameter to exec explicitly:

def execute(e: Exec): T = e.exec[T](this)

Seems to be a limitation in the type inference.

share|improve this answer
    
It looks like it is the right answer ! –  GDD Jan 14 '13 at 12:06
add comment

Disclaimer: not a scala guru here, I'm learning it as I'm writing this.

First, let's simplify the example.

scala> trait Moo[+X <: Moo[X]] 
defined trait Moo

scala> class Foo extends Moo[Foo]
defined class Foo

scala> def foobar[U <: Moo[U]](x: U) = x
foobar: [U <: Moo[U]](x: U)U

scala> foobar(new Foo)
res0: Foo = Foo@191275b

scala> class Bar extends Foo
defined class Bar

scala> foobar(new Bar)
<console>:12: error: inferred type arguments [Bar] do not conform to method 
foobar's type parameter bounds [U <: Moo[U]]
              foobar(new Bar)
              ^

scala> 

foobar accepts a Foo argument but rejects a Bar which only extends Foo. Why? foobar is a generic, paramaterized by the type of its argument. It imposes a bound on that type. The type inferencer will not check each and every ancestor of the argument type, hoping to find one that satisfies the bound.

So how to impose a bound on an ancestor type? One method is with existential types.

scala> def foobar[V <: Moo[U] forSome {type U}](x: V) = x
foobar: [U <: Moo[_], V <: U](x: V)V

scala> foobar(new Foo)
res3: Foo = Foo@1154718

scala> foobar(new Bar)
res4: Bar = Bar@5a7ff7

scala> 
share|improve this answer
    
Well, this is not exactly my question. However, your point focuses on my attempt to return an instance of type T thanks to the parametrization CS[+T <: CS[T]]. In fact, I used the technique presented in the question How to use Scala's this typing, abstract types, etc. to implement a Self type? by IttayD. –  GDD Jan 14 '13 at 12:20
    
I'm not sure I understand you. –  n.m. Jan 14 '13 at 15:04
    
Trait CS implements a Self type to make it possible to return the right type in methods of trait CS for an instance of a class that is a specialization of a class mixin trait CS. This is exactly the subject discussed in the question previously mentioned. If you take a closer look at the solution proposed by IttayD, you realise that each class B specializing a class A mixin trait CS will also mixin trait CS[B]. Consequently, the use of existential type is not necessary. –  GDD Jan 17 '13 at 13:07
    
So does this technique work for you? Do you need to specify the type explicitly like in the accepted answer? –  n.m. Jan 17 '13 at 15:29
    
Yes, I just had to specify explicitly the type. –  GDD Jan 21 '13 at 13:05
show 1 more comment

Your Answer

 
discard

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.