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Given something like:

class A {
  def f(x: X) = ...
  def g(y: Y, z: Z) = ...

How to (automatically) extract the function(s):

object A {
  val f' = (a: A, x: X) => a.f(x)  // do this automagically for any arbitrary f
  val g' = (a: A, y: Y, z: Z) => a.g(y, z) // and deal with arity > 1 too

With this exact type signature (first the object, then the parameter list). Let me state the problem very clearly:

"Given a method f(x1: X1, ..., xn: Xn) defined in the context of a class A, how to automatically extract a function f' that (i) receives an instance a of type A, and (ii) a parameter list that corresponds 1:1 to the parameter list of f, viz. x1: X, ... xn: Xn, which implementation is exactly a.f(x1: X1, ..., xn: Xn)"

Or even:

Capturing the concept of extensionality of lambda-calculus, such that you automatically extract an λx.(f x) from f whenever x does not appear free in f.

This could first be tackled by finding a way access the identifiers f, g, ... without having a specific a: A (one would have a specific A later, of course). We could simply write f' or g' by hand, but let's indulge DRYness.

P.S. Maybe this isn't possible without runtime reflection (albeit it may be possible with Scala 2.10+ macros), since I can't seem to find a way to refer to the identifiers of f or g without a specific instance (a: A) beforehand. But it would be something like the following, without having to resort to strings:

A.getMethod("f"): Function2[A, X, ...]

I also realize that practical uses of the question may help the participants to suggest alternatives, but I'm discussing this in an abstract sense. I'm not trying to solve other problem which I've reduced to this one. I'm trying to know if this one is possible :-) Here's a very nice article to actually understand the motivation behind this question, with rants over Eta-expansions on Scala.

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Using reflection for such purposes really is not a good idea. It will inevitably turn out to be an overcomplication, it will reduce the performance and it will destroy the whole point of using a static language, since all your method resolutions and invocations will be done in runtime. You should really consider different approaches to your problem, like, for instance, using implicits. Probably extending your question with appropriate info might help others help you with that. – Nikita Volkov Oct 7 '12 at 11:53
@NikitaVolkov I agree with you. Reflection is bad. But if it is solved at compile time, then there's no reason for reduced performance, nor lost of type-safeness. – Hugo S Ferreira Oct 7 '12 at 12:02
@NikitaVolkov Reflection is made of Introspection (to meta) and Reification (from meta). It is arguable if reflection is runtime-only (although wikipedia says so), so for the sake of the argument, let's call it compile-time meta-programming. – Hugo S Ferreira Oct 7 '12 at 13:38
Only to clarify, macros implementation uses compile-time reflection, so that the macro implementers can in fact query the structure of the program being compiled. But there are various limitations to what can be done with macros. – pedrofurla Oct 7 '12 at 16:27
@PaulButcher my observation is that reflection doesn't necessarily happen at runtime. There has been several prior literature talking about compile-time reflection, so I'm a little surprised that you guys are surprised :-) – Hugo S Ferreira Oct 7 '12 at 16:54

3 Answers 3

You certainly could do this at compile time with macros - I do something very like this in the preview release of ScalaMock 3 - mock objects are instances of anonymous classes where each member is implemented by an instance of a mock function. You may well be able to use it as a starting point for what you're trying to do.

Warning: ScalaMock 3 currently only works with Scala 2.10.0-M6. It doesn't work with M7 or the current development version due to breaking changes in the macro API that I haven't (yet!) had a chance to address.

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Thanks for the feedback! Could you give use some hints? :-) – Hugo S Ferreira Oct 7 '12 at 16:55
I'm not sure that I can really say much more that's very helpful I'm afraid. I'm certain that what you're trying to do is possible, but it's not going to be trivial. I suspect that, as I've had to do in ScalaMock, you're probably going to have to construct the tree you want "by hand", and you're going to run into many of the same complications I have related to handling type-parameterised and overloaded methods. The source file to look at is… - I suspect that you could use it as a starting point. – Paul Butcher Oct 8 '12 at 11:32
You should also be aware that this area is very much in flux at the moment. The code I just pointed you at works against M6, but is comprehensively broken against M7 (and even more broken against the current development version of 2.10). – Paul Butcher Oct 8 '12 at 11:34

This feels similar to Lensed project that creates lenses for Scala case classes. I believe it would be possible to modify it to create the methods you describe instead of lenses.

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Unfortunately Lensed uses a compiler plugin. As I know from bitter experience with ScalaMock 2, there are significant limitations with compiler plugins (which is why ScalaMock 3 is moving to using macros) – Paul Butcher Oct 8 '12 at 11:24

I know it's not a particularly beautiful solution, but you if you can't use macros, you could generate source code for a companion object you need and compile it in a separate build step.

def generateCompanionObject(clazz: Class[_]) = {
     val className = clazz.getName.split("\\.").last
     val firstMethod = clazz.getMethods.head//for simplicity
     val methodName = firstMethod.getName
     val parametersClasses =

     val objectDefinition = "object " + className + " {\n" +
         generateMethodDefinition(className, methodName, parametersClasses) +


 def generateMethodDefinition(className: String, methodName: String, parameterClasses: Seq[String]) = {
     val newMethodName: String = "   def invoke" + methodName.capitalize + "On"

     val parameterList: String = "(o:" + className + ", " + {
         case (argClassName, index) => "arg" + index + ": " + argClassName
     }.mkString(", ") + ")"

     val generateOldMethodCall: String = "o." + methodName + {
         case (argClassName, index) => "arg" + index
     }.mkString("(", ",", ")")

     newMethodName + parameterList + " = " + generateOldMethodCall

for class

class A {
   def foo(x: String, y: String) = x + y

it will generate

object A {
   def invokeFooOn(o:A, arg0: java.lang.String, arg1: java.lang.String) =,arg1)
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