I am trying to create a Vector class that is generic for all numeric types. my original attempt was to write a class for all Types like this:

class Vector3f(val x:Float, val y:Float, val z:Float)

since scala supports the specialised annotation I could use this to generate me these classes for all numeric types

class Vector3[A <: What?](val x:A,val y:A, val z:A)

but everything I found as a super type for numbers was AnyVal, but AnyVal does not support + - * /. So what is the right way to do this, but without sacrificing the performance of unboxed number types?


3 Answers 3


You can't. Not right now. Maybe when, and if, Numeric gets specialized.

Say you get the simplest parameterized class possible:

class Vector3[@specialized T](val x: T, val y: T, val z: T)(implicit num: Numeric[T]) {
    def +(other: Vector3[T]) = new Vector3(num.plus(x, other.x), num.plus(y, other.y), num.plus(z, other.z))

The method + will compile into something roughly like this:

override <specialized> def +$mcD$sp(other: Vector3): Vector3 = new Vector3$mcD$sp(

That's scalac -optimize -Xprint:jvm output. Now there are even subclasses for each specialized type, so that you can initialize a Vector3 without boxing, but as long as Numeric is not specialized, you can't go further.

Well... you can write your own Numeric and specialize that, but, at that point, I'm not sure what you are gaining by making the class parameterized in first place.


The short answer is: you can't get full performance. Or at least I haven't found anything that gives full performance. (And I have tried for a while in exactly this use case; I gave up and wrote a code generator instead, especially since you can't handle different vector sizes generically either.)

I'd be delighted to be shown otherwise, but thus far everything I've tried has had a small (30%) to vast (900%) increase in runtime.

Edit: here's a test showing what I mean.

object Specs {
  def ptime[T](f: => T): T = {
    val t0 = System.nanoTime
    val ans = f
    printf("Elapsed: %.3f s\n",(System.nanoTime-t0)*1e-9)
  def lots[T](n: Int, f: => T): T = if (n>1) { f; lots(n-1,f) } else f

  sealed abstract class SpecNum[@specialized(Int,Double) T] {
    def plus(a: T, b: T): T

  implicit object SpecInt extends SpecNum[Int] {
    def plus(a: Int, b: Int) = a + b

  final class Vek[@specialized(Int,Double) T](val x: T, val y: T) {
    def +(v: Vek[T])(implicit ev: SpecNum[T]) = new Vek[T](ev.plus(x,v.x), ev.plus(y,v.y))

  final class Uek[@specialized(Int,Double) T](var x: T, var y: T) {
    def +=(u: Uek[T])(implicit ev: SpecNum[T]) = { x = ev.plus(x,u.x); y = ev.plus(y,u.y); this }

  final class Veq(val x: Int, val y: Int) {
    def +(v: Veq) = new Veq(x + v.x, y + v.y)

  final class Ueq(var x: Int, var y: Int) {
    def +=(u: Ueq) = { x += u.x; y += u.y; this }

  def main(args: Array[String]) {
    for (i <- 1 to 6) {
      ptime(lots(1000000,{val v = new Vek[Int](3,5); var u = new Vek[Int](0,0); var i=0; while (i<100) { u = (u+v); i += 1 }; u}))
      ptime(lots(1000000,{val v = new Veq(3,5); var u = new Veq(0,0); var i=0; while (i<100) { u = (u+v); i += 1 }; u}))
      ptime(lots(1000000,{val v = new Uek[Int](3,5); val u = new Uek[Int](0,0); var i=0; while (i<100) { u += v; i += 1 }; u}))
      ptime(lots(1000000,{val v = new Ueq(3,5); val u = new Ueq(0,0); var i=0; while (i<100) { u += v; i += 1 }; u}))

and the output:

Elapsed: 0.939 s
Elapsed: 0.535 s
Elapsed: 0.077 s
Elapsed: 0.075 s
Elapsed: 0.947 s
Elapsed: 0.352 s
Elapsed: 0.064 s
Elapsed: 0.063 s
Elapsed: 0.804 s
Elapsed: 0.360 s
Elapsed: 0.064 s
Elapsed: 0.062 s
Elapsed: 0.521 s  <- Immutable specialized with custom numeric
Elapsed: 0.364 s  <- Immutable primitive type
Elapsed: 0.065 s  <- Mutable specialized with custom numeric
Elapsed: 0.065 s  <- Mutable primitive type
  • Not in 2.8.1. Earlier in 2.8 (late 2.8.0 RC, IIRC) there was some problem which I no longer remember that kept performance at somewhat unimpressive levels. I guess I should try again.
    – Rex Kerr
    Jan 21, 2011 at 11:51
  • Just tried again. It seems okay for mutable operations with the Sun JVM, but once you need to create new objects, there's a ~2x penalty. (The JRockit JVM shows the same trend but all timings are 2-3x worse, usually, and can only sometimes make the mutable specialized case work.)
    – Rex Kerr
    Jan 21, 2011 at 14:22
  • 1
    I benchmarked this code on Scala 2.9 and get roughly the same results. Interestingly, the "-optimize" flag makes the first case (Immutable specialized) about twice as slow. Apparently, one should avoid -optimize! Also, the "-server" JVM option helps the first two cases (Immutable) by about 20%. Jul 4, 2011 at 17:06
  • It should also be mentioned that the @specialized annotations do help. If they are removed, then both the 1st and 3rd cases both become slow, about 1.0s Jul 4, 2011 at 17:28

You probably want to use the typeclass pattern as described here: http://dcsobral.blogspot.com/2010/06/implicit-tricks-type-class-pattern.html

Or, you can indirectly use by by using the Numeric trait http://www.scala-lang.org/api/current/scala/math/Numeric.html

  • 1
    It's a little funny that the blog post linked in this answer was written by the guy who provided a more comprehensive but lower scored answer to this same question. :) Jan 21, 2011 at 6:09
  • Yes I also noticed the dcsobral in the blog link and had already seen Daniel's answer above. Jul 4, 2016 at 16:02

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