case class copy 'method' with superclass

Question

I want to do something like this:

sealed abstract class Base(val myparam:String)

case class Foo(override val mypar         


        

Answer 1

This works fine for me:

sealed abstract class Base { def copy(myparam: String): Base }

case class Foo(myparam:String) extends Base {
  override def copy(x: String = myparam) = Foo(x)
}

def copyBase(x: Base) = x.copy("changed")

copyBase(Foo("abc")) //Foo(changed)

Answer 2

I think this is what extension methods are for. Take your pick of implementation strategies for the copy method itself.

I like here that the problem is solved in one place.

It's interesting to ask why there is no trait for caseness: it wouldn't say much about how to invoke copy, except that it can always be invoked without args, copy().

sealed trait Base { def p1: String }

case class Foo(val p1: String) extends Base
case class Bar(val p1: String, p2: String) extends Base
case class Rab(val p2: String, p1: String) extends Base
case class Baz(val p1: String)(val p3: String = p1.reverse) extends Base

object CopyCase extends App {

  implicit class Copy(val b: Base) extends AnyVal {
    def copy(p1: String): Base = b match {
      case foo: Foo => foo.copy(p1 = p1)
      case bar: Bar => bar.copy(p1 = p1)
      case rab: Rab => rab.copy(p1 = p1)
      case baz: Baz => baz.copy(p1 = p1)(p1.reverse)
    }
    //def copy(p1: String): Base = reflect invoke
    //def copy(p1: String): Base = macro xcopy
  }

  val f = Foo("param1")
  val g = f.copy(p1="param2") // normal
  val h: Base = Bar("A", "B")
  val j = h.copy("basic")     // enhanced
  println(List(f,g,h,j) mkString ", ")

  val bs = List(Foo("param1"), Bar("A","B"), Rab("A","B"), Baz("param3")())
  val vs = bs map (b => b copy (p1 = b.p1 * 2))
  println(vs)
}

Just for fun, reflective copy:

  // finger exercise in the api
  def copy(p1: String): Base = {
    import scala.reflect.runtime.{ currentMirror => cm }
    import scala.reflect.runtime.universe._
    val im = cm.reflect(b)
    val ts = im.symbol.typeSignature
    val copySym = ts.member(newTermName("copy")).asMethod
    def element(p: Symbol): Any = (im reflectMethod ts.member(p.name).asMethod)()
    val args = for (ps <- copySym.params; p <- ps) yield {
      if (p.name.toString == "p1") p1 else element(p)
    }
    (im reflectMethod copySym)(args: _*).asInstanceOf[Base]
  }

Answer 3

Its an old problem, with an old solution,

https://code.google.com/p/scala-scales/wiki/VirtualConstructorPreSIP

made before the case class copy method existed.

So in reference to this problem each case class MUST be a leaf node anyway, so define the copy and a MyType / thisType plus the newThis function and you are set, each case class fixes the type. If you want to widen the tree/newThis function and use default parameters you'll have to change the name.

as an aside - I've been waiting for compiler plugin magic to improve before implementing this but type macros may be the magic juice. Search in the lists for Kevin's AutoProxy for a more detailed explanation of why my code never went anywhere

Answer 4

If the two case classes would diverge over time so that they have different fields, then the shared copy approach would cease to work.

It is better to define an abstract def withMyParam(newParam: X): Base. Even better, you can introduce an abstract type to retain the case class type upon return:

scala> trait T {
     |   type Sub <: T
     |   def myParam: String
     |   def withMyParam(newParam: String): Sub
     | }
defined trait T

scala> case class Foo(myParam: String) extends T {
     |   type Sub = Foo
     |   override def withMyParam(newParam: String) = this.copy(myParam = newParam)
     | }
defined class Foo

scala>

scala> case class Bar(myParam: String) extends T {
     |   type Sub = Bar
     |   override def withMyParam(newParam: String) = this.copy(myParam = newParam)
     | }
defined class Bar

scala> Bar("hello").withMyParam("dolly")
res0: Bar = Bar(dolly)

Answer 5

This is old answer, before the question was changed.

Strongly typed programming languages prevent what you are trying to do. Let's see why.

The idea of a method with the following signature:

def getIt( a:Base ) : Unit

Is that the body of the method will be able to access a properties visible through Base class or interface, i.e. the properties and methods defined only on the Base class/interface or its parents. During code execution, each specific instance passed to the getIt method might have a different subclass but the compile type of a will always be Base

One can reason in this way:

Ok I have a class Base, I inherit it in two case classes and I add a property with the same name, and then I try to access the property on the instance of Base.

A simple example shows why this is unsafe:

sealed abstract class Base
case class Foo(myparam:String) extends Base
case class Bar(myparam:String) extends Base
case class Evil(myEvilParam:String) extends Base

def getIt( a:Base ) = a.copy(myparam="changed")

In the following case, if the compiler didn't throw an error at compile time, it means the code would try to access a property that does not exist at runtime. This is not possible in strictly typed programming languages: you have traded restrictions on the code you can write for a much stronger verification of your code by the compiler, knowing that this reduces dramatically the number of bugs your code can contain

---

This is the new answer. It is a little long because few points are needed before getting to the conclusion

Unluckily, you can't rely on the mechanism of case classes copy to implement what you propose. The way the copy method works is simply a copy constructor which you can implement yourself in a non-case class. Let's create a case class and disassemble it in the REPL:

scala>  case class MyClass(name:String, surname:String, myJob:String)
defined class MyClass

scala>  :javap MyClass
Compiled from "<console>"
public class MyClass extends java.lang.Object implements scala.ScalaObject,scala.Product,scala.Serializable{
    public scala.collection.Iterator productIterator();
    public scala.collection.Iterator productElements();
    public java.lang.String name();
    public java.lang.String surname();
    public java.lang.String myJob();
    public MyClass copy(java.lang.String, java.lang.String, java.lang.String);
    public java.lang.String copy$default$3();
    public java.lang.String copy$default$2();
    public java.lang.String copy$default$1();
    public int hashCode();
    public java.lang.String toString();
    public boolean equals(java.lang.Object);
    public java.lang.String productPrefix();
    public int productArity();
    public java.lang.Object productElement(int);
    public boolean canEqual(java.lang.Object);
    public MyClass(java.lang.String, java.lang.String, java.lang.String);
}

In Scala, the copy method takes three parameter and can eventually use the one from the current instance for the one you haven't specified ( the Scala language provides among its features default values for parameters in method calls)

Let's go down in our analysis and take again the code as updated:

sealed abstract class Base(val myparam:String)

case class Foo(override val myparam:String) extends Base(myparam)
case class Bar(override val myparam:String) extends Base(myparam)

def getIt( a:Base ) = a.copy(myparam="changed")

Now in order to make this compile, we would need to use in the signature of getIt(a:MyType) a MyType that respect the following contract:

Anything that has a parameter myparam and maybe other parameters which have default value

All these methods would be suitable:

  def copy(myParam:String) = null
  def copy(myParam:String, myParam2:String="hello") = null
  def copy(myParam:String,myParam2:Option[Option[Option[Double]]]=None) = null

There is no way to express this contract in Scala, however there are advanced techniques that can be helpful.

The first observation that we can do is that there is a strict relation between case classes and tuples in Scala. In fact case classes are somehow tuples with additional behaviour and named properties.

The second observation is that, since the number of properties of your classes hierarchy is not guaranteed to be the same, the copy method signature is not guaranteed to be the same.

In practice, supposing AnyTuple[Int] describes any Tuple of any size where the first value is of type Int, we are looking to do something like that:

def copyTupleChangingFirstElement(myParam:AnyTuple[Int], newValue:Int) = myParam.copy(_1=newValue)

This would not be to difficult if all the elements were Int. A tuple with all element of the same type is a List, and we know how to replace the first element of a List. We would need to convert any TupleX to List, replace the first element, and convert the List back to TupleX. Yes we will need to write all the converters for all the values that X might assume. Annoying but not difficult.

In our case though, not all the elements are Int. We want to treat Tuple where the elements are of different type as if they were all the same if the first element is an Int. This is called

"Abstracting over arity"

i.e. treating tuples of different size in a generic way, independently of their size. To do it, we need to convert them into a special list which supports heterogenous types, named HList

---

Conclusion

Case classes inheritance is deprecated for very good reason, as you can find out from multiple posts in the mailing list: http://www.scala-lang.org/node/3289

You have two strategies to deal with your problem:

1. If you have a limited number of fields you require to change, use an approach such as the one suggested by @Ron, which is having a copy method. If you want to do it without losing type information, I would go for generifying the base class

   sealed abstract class Base[T](val param:String){
     def copy(param:String):T
   }
   
   class Foo(param:String) extends Base[Foo](param){
     def copy(param: String) = new Foo(param)
   }
   
   def getIt[T](a:Base[T]) : T = a.copy("hello")
   
   scala>  new Foo("Pippo")
   res0: Foo = Foo@4ab8fba5
   
   scala>  getIt(res0)
   res1: Foo = Foo@5b927504
   
   scala>  res1.param
   res2: String = hello
   

2. If you really want to abstract over arity, a solution is to use a library developed by Miles Sabin called Shapeless. There is a question here which has been asked after a discussion : Are HLists nothing more than a convoluted way of writing tuples? but I tell you this is going to give you some headache

Answer 6

There is a very comprehensive explanation of how to do this using shapeless at http://www.cakesolutions.net/teamblogs/copying-sealed-trait-instances-a-journey-through-generic-programming-and-shapeless ; in case the link breaks, the approach uses the copySyntax utilities from shapeless, which should be sufficient to find more details.