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I've tried to come up with a composition scenario in which self-type and extends behave differently and so far have not found one. The basic example always talks about a self-type not requiring the class/trait not having to be a sub-type of the dependent type, but even in that scenario, the behavior between self-type and extends seems to be identical.

trait Fooable { def X: String }
trait Bar1 { self: Fooable =>
  def Y = X + "-bar"
trait Bar2 extends Fooable {
  def Y = X + "-bar"
trait Foo extends Fooable {
  def X = "foo"
val b1 = new Bar1 with Foo
val b2 = new Bar2 with Foo

Is there a scenario where some form of composition or functionality of composed object is different when using one vs. the other?

Update 1: Thanks for the examples of things that are not possible without self-typing, I appreciate the information, but I am really looking for compositions where self and extends are possible, but are not interchangeable.

Update 2: I suppose the particular question I have is why the various Cake Pattern examples generally talk about having to use self-type instead of extends. I've yet to find a Cake Pattern scenario that doesn't work just as well with extends

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possible duplicate of What is the difference between self-types and trait subclasses? –  rxg Mar 27 at 10:30

5 Answers 5

up vote 7 down vote accepted

Cyclic references can be done with self-types but not with extends:

// Legal
trait A { self: B => }
trait B { self: A => }

// Illegal
trait C extends D
trait D extends C

I use this sometimes to split up implementations across multiple files, when there are cyclic dependencies.

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I found one other things that you can do with self types that you cannot do with extends: Self-types can be structural types –  Arne Claassen Sep 2 '14 at 4:47


scala> trait A { def a: String ; def s = "A" }
defined trait A

scala> trait B { _: A => def s = "B" + a }
defined trait B

scala> trait C extends A { def a = "c" ; override def s = "C" }
defined trait C

scala> new C {}.s
res0: String = C

scala> new A with B { def a = "ab" }.s
<console>:10: error: <$anon: A with B> inherits conflicting members:
  method s in trait A of type => String  and
  method s in trait B of type => String
(Note: this can be resolved by declaring an override in <$anon: A with B>.)
              new A with B { def a = "ab" }.s

scala> new A with B { def a = "ab" ; override def s = super[B].s }.s
res2: String = Bab

The point, if there is one, is that B.s doesn't override A.s.

That's not as motivational as the other answer.

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Curious, would _: A => mean the same thing as this: A =>? –  megri Aug 20 '14 at 22:00
@megri Apparently. trait B { _ => def b = 42 ; class C { def c = `_`.b } } –  som-snytt Aug 20 '14 at 22:29

The generic parameter must be the type itself:

trait Gen[T] {self : T => ...}

I don't see how you can get this constraint in say java or C#. It may however be approximated with

trait Gen[T] {
   def asT : T // abstract
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as for self type, it needs a trait to mix in. It cannot use class or object. The weird thing is it allows to define a class can mix in with class, but it only fails compilation when you try to instantiate it. see this question:

why self-type class can declare class

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The biggest difference is in the public interface that you end up with. Let's take the example you give (slightly simplified):

trait Fooable { def foo: String = "foo" }
trait Bar1 { self: Fooable =>
  def Y = foo + "-bar"
trait Bar2 extends Fooable {
  def Y = foo + "-bar"
// If we let type inference do its thing we would also have foo() in the public interface of b1, but we can choose to hide it
def b1:Bar1 = new Bar1 with Fooable
// b2 will always have the type members from Bar2 and Fooable
def b2:Bar2 = new Bar2{}

// Doesn't compile - 'foo' definition is only visible inside the definition of Bar1
// Compiles - 'foo' definition is visible outside the definition of Bar2

So if you want to use the capabilities of a trait without necessarily letting your clients know that you are mixing the trait in, then you should use the self-type annotation.

Self-type annotation does not expose the public interface of the underlying type. Extending another type always exposes the public interface of the parent type.

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