# Problems with Scala Numeric[T]

I have a numeric solving function (`Double => Double`) where I tried to be clever and use the `Numeric[T]` for keeping the two kinds of numbers apart.

This did not turn out to be easy. The remaining problems are:

• how to do division; `Numeric[T]` only has plus, minus etc. operators.
• why doesn't the compiler find the `implicit evidence\$1: Numeric[Double]` functions (see compiler output below)

Ideally, I'd like to say, "`A` and `B` are both `Double`, but tell me if I mix them with each other".

Here's the code:

``````import scala.annotation.tailrec

class Sweep[A: Numeric, B: Numeric]( fDiff: A => B, initialSeed: A, initialStep: A, bEps: B )
{
val anum= evidence\$1
val bnum= evidence\$2

assert( anum.signum(initialStep) > 0 )
assert( bnum.lt( fDiff(initialSeed), fDiff( anum.plus(initialSeed,initialStep) )) )   // check that it's an increasing function

@tailrec
private def sweep( seed: A, step: A ): A = {
val bDiff= fDiff(seed)

if ( bnum.lt( bnum.abs(bDiff), bEps) ) {  // done
seed
} else if ( bnum.signum(bDiff) != anum.signum(step) ) {
sweep( anum.plus(seed,step), step )   // continue, same step and direction ('bDiff' should go smaller)
} else {
val newStep = anum.toDouble(step) / -2.0
sweep( anum.minus(seed,newStep), newStep )    // reverse, smaller step
}
}

// Make sure we take the initial step in the right direction
//
private lazy val stepSign= -bnum.signum( fDiff(initialSeed) )

def apply: A = sweep( initialSeed, stepSign * initialStep )
}

object TestX extends App {

val t= new Sweep( (a: Double) => (a*a)-2, 1.0, 0.5, 1e-3 )()

println( t, math.sqrt(2.0) )
}
``````

I've tried it also with the older `(implicit anum: Numeric[A])` parameters, but was unable to have two such (both for `A` and `B`).

Here's what the compiler says (Scala 2.9):

``````fsc -deprecation -d out-make -unchecked src/xxx.scala
src/xxx.scala:25: error: type mismatch;
found   : newStep.type (with underlying type Double)
required: A
sweep( anum.minus(seed,newStep), newStep )    // reverse, smaller step
^
src/xxx.scala:33: error: overloaded method value * with alternatives:
(x: Double)Double <and>
(x: Float)Float <and>
(x: Long)Long <and>
(x: Int)Int <and>
(x: Char)Int <and>
(x: Short)Int <and>
(x: Byte)Int
cannot be applied to (A)
def apply: A = sweep( initialSeed, stepSign * initialStep )
^
src/xxx.scala:38: error: not enough arguments for constructor Sweep: (implicit evidence\$1: Numeric[Double], implicit evidence\$2: Numeric[Double])Sweep[Double,Double].
Unspecified value parameters evidence\$1, evidence\$2.
val t= new Sweep( (a: Double) => (a*a)-2, 1.0, 0.5, 1e-3 )()
^
three errors found
``````

Thanks for any ideas.

-

You want to be working with `Fractional` instead of `Numeric`. The following compiles for me:

``````import scala.annotation.tailrec
import math.Fractional.Implicits._
import Ordering.Implicits._

class Sweep[A: Fractional, B: Fractional](fDiff: A => B, initialSeed: A, initialStep: A, bEps: B) {
val aFractional = implicitly[Fractional[A]]

assert(initialStep.signum > 0)
assert(fDiff(initialSeed) < fDiff(initialSeed + initialStep))

@tailrec
private def sweep(seed: A, step: A): A = {
val bDiff = fDiff(seed)
if (bDiff.abs < bEps) {
seed
} else if (bDiff.signum != step.signum) {
sweep(seed + step, step)
} else {
val one = aFractional.one
val newStep = step / aFractional.fromInt(-2)
sweep(seed - newStep, newStep)
}
}

private lazy val stepSign = aFractional.fromInt(-fDiff(initialSeed).signum)
def apply: A = sweep(initialSeed, stepSign * initialStep)
}

val sweep = new Sweep((a: Double) => (a*a)-2, 1.0, 0.5, 1e-3)
println(sweep.apply, math.sqrt(2.0))
``````

Note that to get things like `-2.0` in type `A`, you'll need to assemble them manually from `Fractional.one` or use `Fractional.fromInt`.

The other thing worth pointing out is the use of `math.Fractional.Implicits` and `Ordering.Implicits` which will allow you to use normal math syntax (+, <, /, etc.) instead of calling functions like `plus` and `div`.

-
Precisely. Thanks. And I can even use normal operators! One bug in my original code: "- newStep" should be "+ newStep" (makes the result come sooner). –  akauppi Dec 12 '12 at 12:49

If you want the compiler to tell you when the type parameters `A` and `B` are not the same, just use one type parameter:

``````class Sweep[A: Numeric]( fDiff: A => A, initialSeed: A, initialStep: A, bEps: A )
``````
-
Let me rephrase. The types may be the same, but the numbers mean different things. So I wish to hear if I do 'a+b' for example. To get the code working, I could skip all this, but I also try to understand Scala for real. :) –  akauppi Dec 12 '12 at 12:13
I'm not sure that I understand you. You wish two types to be the same type: so use one type –  oxbow_lakes Dec 13 '12 at 11:51
The A type usually means seconds, and B something else (i.e. speed). Thus they both are Double for the compiler, but cannot conceptually be counted together. –  akauppi Jun 16 '13 at 19:50

The issue seems to be that you use `Double` here ...

``````val newStep = anum.toDouble(step) / -2.0
``````

... although you want to use `Numeric` and actually use it that way in the next line.

For division, have a look at `Numeric`'s subtypes `Integral` and `Fractional`.

The compiler doesn't find an implicit evidence, because you explicitly pass none:

``````new Sweep((a: Double) => (a*a)-2, 1.0, 0.5, 1e-3)()
``````

Removing the explicit empty parameter list fixes that:

``````new Sweep((a: Double) => (a*a)-2, 1.0, 0.5, 1e-3)
``````

I'm not sure about the requirement of not mixing `A` and `B`, because you do that in multiple places in your code already.

I'm not sure this is what you want, but the following code works:

``````import scala.annotation.tailrec

class Sweep[A: Fractional](fDiff: A => A, initialSeed: A, initialStep: A, bEps: A) {
val num = implicitly[Fractional[A]]

assert(num.signum(initialStep) > 0)
assert(num.lt(fDiff(initialSeed), fDiff(num.plus(initialSeed, initialStep)))) // check that it's an increasing function

@tailrec
private def sweep(seed: A, step: A): A = {
val bDiff = fDiff(seed)

if (num.lt(num.abs(bDiff), bEps)) { // done
seed
} else if (num.signum(bDiff) != num.signum(step)) {
sweeimport scala.annotation.tailrec

class Sweep[A: Fractional](fDiff: A => A, initialSeed: A, initialStep: A, bEps: A) {
val num = implicitly[Fractional[A]]

assert(num.signum(initialStep) > 0)
assert(num.lt(fDiff(initialSeed), fDiff(num.plus(initialSeed, initialStep)))) // check that it's an increasing function

@tailrec
private def sweep(seed: A, step: A): A = {
val bDiff = fDiff(seed)

if (num.lt(num.abs(bDiff), bEps)) { // done
seed
} else if (num.signum(bDiff) != num.signum(step)) {
sweep(num.plus(seed, step), step) // continue, same step and direction ('bDiff' should go smaller)
} else {
val newStep = num.div(step, num.fromInt(-2))
sweep(num.minus(seed, newStep), newStep) // reverse, smaller step
}
}

// Make sure we take the initial step in the right direction
private lazy val stepSign = -num.signum(fDiff(initialSeed))

def apply: A = sweep(initialSeed, num.times(num.fromInt(stepSign), initialStep))
}

object TestX extends App {

val t = new Sweep((a: Double) => (a * a) - 2, 1.0, 0.5, 1e-3)

println(t, math.sqrt(2.0))
}

p(num.plus(seed, step), step) // continue, same step and direction ('bDiff' should go smaller)
} else {
val newStep = num.div(step, num.fromInt(-2))
sweep(num.minus(seed, newStep), newStep) // reverse, smaller step
}
}

// Make sure we take the initial step in the right direction
private lazy val stepSign = -num.signum(fDiff(initialSeed))

def apply: A = sweep(initialSeed, num.times(num.fromInt(stepSign), initialStep))
}

object TestX extends App {

val t = new Sweep((a: Double) => (a * a) - 2, 1.0, 0.5, 1e-3)

println(t, math.sqrt(2.0))
}
``````
-
Yes, but since 'Numeric[T]' does not have division, I'm forced to. And there seems to be no way back from Double to A? –  akauppi Dec 12 '12 at 12:13
Did you read the code? –  soc Dec 12 '12 at 13:49