How do I implement a generic mathematical function in Scala

I'm just getting started with Scala and something which I think should be easy is hard to figure out. I am trying to implement the following function:

`def square(x:Int):Int = { x * x }`

This works just fine, but if I want to try to make this function work for any kind of number I would like to be able to do the following:

`def square[T <: Number](x : T):T = { x * x }`

This complains and says: error: value * is not a member of type parameter T

Okay, do I need to implement a trait for this? Thanks. jim

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For posterity it might be useful to give this question a more specific title like "How do I implement a generic mathematical function in Scala?" –  Aaron Novstrup Oct 30 '10 at 17:25
Agreed, thanks. –  jimmyb May 5 '11 at 15:49

That was one of my first questions in Stack Overflow or about Scala. The problem is that Scala maintains compatibility with Java, and that means its basic numeric types are equivalent to Java's primitives.

The problem arises in that Java primitives are not classes, and, therefore, do not have a class hierarchy which would allow a "numeric" supertype.

To put it more plainly, Java, and, therefore, Scala, does not see any common grounds between a `Double`'s `+` and a an `Int`'s `+`.

The way Scala finally got around this restriction was by using `Numeric`, and its subclasses `Fractional` and `Integral`, in the so-called typeclass pattern. Basically, you use it like this:

``````def square[T](x: T)(implicit num: Numeric[T]): T = {
import num._
x * x
}
``````

Or, if you do not need any of the numeric operations but the methods you call do, you can use the context bound syntax for type declaration:

``````def numberAndSquare[T : Numeric](x: T) = x -> square(x)
``````

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Nice explanation. I had to google for the Typeclass Pattern - didn't know that existed. Thanks. –  Collin Oct 30 '10 at 14:35

You can define `square` as:

``````def square[T: Numeric](x: T): T = implicitly[Numeric[T]].times(x,x)
``````

This approach has the advantage that it will work for any type T that has an implicit conversion to Numeric[T] (i.e. Int, Float, Double, Char, BigInt, ..., or any type for which you supply an implicit conversion).

Edit: Unfortunately, you'll run into trouble if you try something like `List(1,2,3).map(square)` (specifically, you'll get a compile error like "could not find implicit value for evidence parameter of type Numeric[T]". To avoid this issue, you can overload `square` to return a function:

``````object MyMath {
def square[T: Numeric](x: T) = implicitly[Numeric[T]].times(x,x)
def square[T: Numeric]: T => T = square(_)
}
``````

Hopefully someone with a better understanding of the type inferencer will explain why that is.

Alternatively, one can call `List(1,2,3).map(square(_))`, as Derek Williams pointed out in the scala-user mailing list thread.

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