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I am hitting a compiler problem when the compiler needs to solve a manifest for a class with an abstract type parameter. The following snippet show the issue

trait MyStuff

trait SecurityMutatorFactory[X]{
  def apply(x1:X,x2:X)

object Example{

  trait LEdge[N]
    type L1
  type MyEdge[X] = LEdge[X] { type L1 = SecurityMutatorFactory[X]}

  val a:Manifest[MyEdge[MyStuff]] = implicitly[Manifest[MyEdge[MyStuff]]]


As a result, the compiler throws the following type error:

type mismatch;
 found   : scala.reflect.Manifest[LEdge[MyStuff]]
 required: Manifest[MyEdge[MyStuff]]
Note: LEdge[MyStuff] >: MyEdge[MyStuff], but trait Manifest is invariant in type T.
You may wish to investigate a wildcard type such as `_ >: MyEdge[MyStuff]`. (SLS 3.2.10)
  val a:Manifest[MyEdge[MyStuff]] = implicitly[Manifest[MyEdge[MyStuff]]]

What is happening at compiler level? ^

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By the way, you may safely remove SecurityMutatorFactory at all, and replace L1 = Int (or anything). It is not relevant to problem. –  dmitry Sep 6 '13 at 13:19
Also, if you replace type MyEdge[X] = LEdge[X] { type L1 = SecurityMutatorFactory[X]} by (equivalent?) trait MyEdge[X] extends LEdge[X] { type L1 = whatever } - it compiles. –  dmitry Sep 6 '13 at 13:20
Given two facts above, I feel the mistery is in the line type MyEdge[X] = LEdge[X] { type L1 = SecurityMutatorFactory[X]}, what does it exactly mean for compiler, that's the question. –  dmitry Sep 6 '13 at 13:24
The problem is that, as you can imagine, the edge has two nodes of type X. I want the label to be a function I can apply to both nodes... –  Edmondo1984 Sep 6 '13 at 13:58
regarding the labels and edges - it's not relevant for the type mismatch at all. You could refine the code that illustrates the problem to near the couple of lines: object Example { trait A[T] { type L1 } type B[T] = A[T] { type L1 = Any } val a: Manifest[B[Int]] = implicitly[Manifest[B[Int]]] }. It produces the same type mismatch and notice about type invariance in Manifest. –  dmitry Sep 6 '13 at 14:29
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2 Answers

up vote 3 down vote accepted

As others have suggested the problem comes from

type MyEdge[X] = LEdge[X] { type L1 = SecurityMutatorFactory[X] }

Declarations of the form type F[X] = ... introduce type synonyms, ie new names for existing types. They do not construct new traits or classes. However, LEdge[X] { type L1 = SecurityMutatorFactory[X] } is constructing a new anonymous class. So your example is approximatelly equivalent to

trait MyEdge[X] extends LEdge[X] { type L1 = SecurityMutatorFactory[X] }

(which is what you most probably want) but the original definition in the example is defining a synonym for an anonymous class instead of defining a new class MyEdge[X]. So in the example the new class is not actually called MyEdge. When constructing the implicit manifest, the compiler replaces the type synonym with the underlying type, but fails to construct a manifest for that because that type is anonymous.

Replacing the MyEdge declaration with either a normal extension definition:

trait MyEdge[X] extends LEdge[X] { type L1 = SecurityMutatorFactory[X] }

or with an ordinary type synonym:

type MyEdge[X] = LEdge[X]

both compile successfully.


Here is the specific reason why generating implicit manifests for anonymous classes fails. In the language specification type expessions of the form BaseType { ... } are called refined types. According to the language specification, the manifest for a refined type is just the manifest of its base class. This however fails to typecheck, because you asked for a Manifest[LEdge[MyStuff]{ type L1 = SecurityMutatorFactory[X] }], but the algorithm is returning Manifest[LEdge[MyStuff]]. This means that you can only construct implicit manifests for types with refined types only in contravariant positions. For example using:

type MyEdge[X] = LEdge[X] { type L1 = SecurityMutatorFactory[X] } => AnyRef

in your example allows it to compile, though it is clearly not what you are after.

The full algorithm for constructing implicit manifests is given at the end of section 7.5 of the language specification. This question is covered by clause 6:

6) If T is a refined type T'{R}, a manifest is generated for T'. (That is, refinements are never reflected in manifests).

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+100 for quoting the language specification. –  Edmondo1984 Sep 16 '13 at 7:08
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Well, I'm not so familiar with that kind of pattern:

type MyEdge[X] = LEdge[X] { type L1 = SecurityMutatorFactory[X]}

but I tend to consider types defined with the type keyword as aliases (concepts) rather than a guarantee about the implementation (EDIT more precisely, I believe that type provides guarantees in terms of prototyping/specifying but that no AST/code is generated until there's an actual need to replace the alias with the traits/classes it's based upon). So even if the compiler claims, in its error message:

LEdge[MyStuff] >: MyEdge[MyStuff]

I'm not sure that, at the bytecode level, it implements MyEdge accordingly, with interfaces/methods/etc. Thus, it might not recognize the wanted relationship between LEdge and MyEdge, eventually:

found   : scala.reflect.Manifest[LEdge[MyStuff]]
required: Manifest[MyEdge[MyStuff]]

(and, is the absence of package scala.reflect. a hint? (1))

About your code, how do you use a? Anyway, if the following is your intent, with:

trait MyEdge[X] extends LEdge[X] {
   type L1 = SecurityMutatorFactory[X]

instead, it does compile (scala 2.10)... (EDIT I just noticed now that dmitry already told that) ...what that does during runtime, I don't know!

As an item of note, Manifest is deprecated after scala 2.9; so you may prefer to use TypeTag[T] as described in the scaladoc.

(1) I suspect that the following happens:
- at the syntactic analysis phase, the compiler registers literally what you specified, that is, the implicitly method shall return a Manifest[MyEdge[MyStuff]].
- by the code generation phase, the aliases are "reconciled" to their nearest classes or traits; in the case of implicitly the result's type Manifest[MyEdge[MyStuff]] becomes trait scala.reflect.Manifest[LEdge[MyStuff]]]
- due to some limitations of type inference involved in Manifest and type "aliasing" within type parameters, however, somehow the specified requirement Manifest[MyEdge[MyStuff]] remains under its raw shape
- (this is pure conjecture, because I've not read the Scala compiler source code for this answer) the compiler would have the proper AST/code on the one hand, but a method prototype/spec that is still under its raw/literal shape on the other hand; that doesn't fit in so it emits an error.

Hoping that helps...

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