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It seems empowering that one can effectively make assertions about legal return values of implementing methods just based on the type of the abstract function/method. I intuitively feel (most of) the compiler behaviour below makes sense but I would appreciate a clear explanation of why I should be able to assert that

def f[T](t: T): T  

can only be the identity function (except that class E compiles too). I can appreciate that we know nothing about T as it is not bounded, but there are gaps in that explanation. The compiler reporting "found scala.Int(42) required Int" is not getting me closer to the light.

trait A{ def f[T](t: T): T }
// compiles
class B extends A{ override def f[Int](t: Int): Int = t }
// does not compile
class C extends A{ override def f[Int](t: Int): Int = t + 1 }
// does not compile
class D extends A{ override def f[Int](t: Int): Int = 42 }
// compiles
class E extends A{ override def f[Int](t: Int): Int = 42.asInstanceOf[Int] }
// compiles
class F extends A{ override def f[Int](t: Int): Int = identity(t) }
share|improve this question
up vote 4 down vote accepted

The problem in your examples is that the Int in your examples is not the normal 32-bit integer type (which is scala.Int); instead, you have a type parameter that happens to be named Int. That's confusing you: you think your Int is scala.Int, but it isn't, it's a type parameter with a confusing name.

So, for example this:

class C extends A{ override def f[Int](t: Int): Int = t + 1 }

Does not mean you are defining a method that takes a scala.Int; you're defining a method with a type parameter that has the name Int. You could give it any other name, for example X, then it would be exactly the same:

class C extends A{ override def f[X](t: X): X = t + 1 }

It doesn't compile because there are no constraints on the type parameter, so the compiler doesn't know that the type has a + method.

share|improve this answer
Or you could just drop the [Int] from B through F. – Rex Kerr Nov 26 '12 at 14:52
That is exactly what I was thought I was doing, thank you! It explains the compiler's complaint too. How does the cast of 42 to my Int work? – involuntary Nov 26 '12 at 14:58
The cast compiles, but when you'd try to run it and you use something else than scala.Int for the type, you'd get a ClassCastException. For example f(0) would work, but f("hello") would throw an exception because you would be trying to cast 42 to the type String. – Jesper Nov 26 '12 at 15:12
Rex, how would the B look, for example, if I drop the [Int]? class B extends A{ override def f(t: Int): Int = t } gives - method f overrides nothing – involuntary Nov 26 '12 at 15:13
@involuntary - That's because you have no implementation to override. You're just providing the implementation that the trait specifies. – Rex Kerr Nov 26 '12 at 15:20

Jesper has the correct answer with the main question: [Int] isn't filling in a type of Int for T, it's creating a new generic type parameter confusingly named Int.

But I also have an addendum:

You are being a little too trusting that the user won't do something sneaky, even if it's valid at runtime.

def f[T](t: T): T = (t match {
  case i: Int => -i
  case s: String => s.reverse
  case b: Boolean => !b
  case o: Option[_] => None
  case s: Seq[_] => throw new Exception("Ack")
  case _ => t

Not exactly the identity function any more, is it? If you forbid matches and asInstanceOf and exceptions and so on, then it's got to be identity.

share|improve this answer
so, if we do ignore those cases for a minute, what is the most succinct way to describe how you know f[T](t: T): T _ must be identity_? – involuntary Nov 26 '12 at 15:18
@involuntary - At runtime, you do not know what the compile-time type T is. Therefore, you cannot produce one de novo; you must used the instance that's passed in. Because the type is unknown, you can only use operations valid on all types. There are no operations defined on all types that return the same type. So the only possible choice is identity. – Rex Kerr Nov 26 '12 at 15:23
"Because the type is unknown, you can only use operations valid on all types. There are no operations defined on all types that return the same type." - I think that is the key, thanks! – involuntary Nov 26 '12 at 15:29
@involuntary - Keep in mind that uninitialized vars are part of "and so on": class Defaulting[U]{ var u: U = _ } allows you to def f[T](t: T) = { (new Defaulting[T]).u } – Rex Kerr Nov 26 '12 at 16:09

Since nobody's answered the other part of the question yet:

In general, this property is called parametricity, and the guarantees you get from it are called free theorems. This only holds, by the way, if you ignore typecase (and unmarked side effects), so a huge part of Scala doesn't count.

share|improve this answer
... that sounds like what I was looking for. I guess in Scala (with its support for 'impure' style too) once could make use of parametricity if one is in control of the code base. Thanks, I'll see what I can find to read re parametricity. – involuntary Nov 26 '12 at 17:04

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