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I am trying to pick some Scala and among the interesting features I found the function with generic (input types)? particularly useful. However trying the following code,

def recFunc[A](xs: List[A], base : () => A) : A = if (xs.isEmpty) base() else xs.head + recFunc(xs.tail, base)

I get the annoying error written below:

<console>:8: error: type mismatch;
 found   : List[A]
 required: List[String]
   def recFunc[A](xs: List[A], base : () => A) : A = if (xs.isEmpty) base() else xs.head + recFunc(xs.tail.asInstanceOf[List[A]], base)

How on earth, the type inference system came up with A == String and throws this exception. Can it be that I got completely wrong the use of this construction?

Thx

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3 Answers 3

The Problem is that you invoke + for a generic type A. The compiler tries to infer something that uses + (like String) and you get the error. I also don't understand what you want to achieve with the +.

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I just wanted to write a recursive function that sums Strings or Ints or Doubles –  jdavid_1385 Oct 25 '13 at 18:18
    
So, how can I come up with such function? –  jdavid_1385 Oct 25 '13 at 18:19
    
Then you need to set a certain upper bound for A, meaning A needs to be a subclass of something so that + is defined for it. e.g [A <: Int] But to be honest i can't think of a way to do this for Int, String and Doubles at the same time. –  Kigyo Oct 25 '13 at 18:27
    
Don't worry. It is simply not a very useful feature anyway. Thanks for your answer, it was very enlightening! –  jdavid_1385 Oct 25 '13 at 18:43
    
You forgot to mention that I've got completely wrong the use of this construction ;) –  jdavid_1385 Oct 25 '13 at 18:45

You don't guarantee that the method + is available for type A. So, the compiler convert A into String.

One solution consist of using typeclasses.

trait Addable[A] {
    def plus(x: A, y: A): A
}

recFunc[A:Addable]…

You may take a look at spire, short intro here : http://typelevel.org/blog/2013/07/07/generic-numeric-programming.html

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What a fantastic answer! Thank you so much for your completeness. –  jdavid_1385 Oct 25 '13 at 18:51
    
def sum[A<:Addable[A]](xs: List[A], base : ()=>A) : A = if (xs.isEmpty) base() else xs.head + sum(xs.tail, base). Simply lovely! –  jdavid_1385 Oct 25 '13 at 18:55
    
@poissonbreaker Note that Scala standard library has Numeric, Integral and Fractional type classes, which provide basic arithmetic methods as well. No need to define Addable yourself. –  Daniel C. Sobral Oct 25 '13 at 19:23

You are calling the + method on A, but there's no guarantee that A has such a method. There are two ways to get around this: inheritance or type classes.

With inheritance, it would be a simple matter of finding a common ancestor to all desired classes that includes the methods you want, then you'd write [A <: CommonAncestor]. Unfortunately, as a result of the effort to make Scala interoperable with Java and general JVM restrictions, the numeric primitives share no such ancestor.

We are left, then, with type classes. The expression "type class" comes from Haskell, and the idea is that you can group different types into a class that share some common properties. The main difference between that and inheritance is that a type class is open to extension: you can easily add any type to such a class.

Scala does not have direct type class support. Instead, we use a "type class pattern" to simulate it. Basically, we create a class -- the type class -- that contains the methods we desire. Next, we create instances of that class for each type we desire to support. Finally, we pass those instances implicitly, which makes it the compiler's job to find the instance required.

In your example, we could do this:

// Our type class
class Addable[T] {
  def plus(a: T, b: T): T
}

// Or Int instance
object AddableInt {
  class AddableInt extends Addable[Int] {
    def plus(a: Int, b: Int): Int = a + b
  }
  implicit val addableInt = new AddableInt
}

// Make the implicit available
import AddableInt._

// Make recFunc use it
def recFunc[A](xs: List[A], base : () => A)(implicit addable: Addable[A]): A = 
  if (xs.isEmpty) base() else addable.plus(xs.head, recFunc(xs.tail, base))

// call recFunc
recFunc(List(1, 2, 3), () => 0)

There are many ways to improve this, such as using implicit class and context bounds. Please, see the Scala wiki on Stack Overflow for more information on implicits and context bounds (sessions 23 and 19, respectively).

Now, it happens that Scala already has context bounds for basic arithmetic, and even some extra tricks using view bounds to make it usage seamless. Here's how you can make it work with the standard library alone:

import scala.math.Numeric.Implicits._
def recFunc[A : Numeric](xs: List[A], base : ()=>A) : A = 
    if (xs.isEmpty) base() else xs.head + recFunc(xs.tail, base)

See also the Numeric scaladoc, though it's really low on examples.

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I wish something like this was possible: def recFunc[A <: { def + (value : A) : A }]... –  Lukas Eder Oct 25 '13 at 19:43
    
Also thought about Numeric but he wanted Strings as well. –  Kigyo Oct 25 '13 at 19:49

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