# Is it possible to have an Array which evaluates its elements lazily?

Consider this BigInt class, which should cache some common values in `smallValues`:

``````object BigInt {
lazy val smallValues = Array(Zero, One, Two)
lazy val Zero = new BigInt(0, Array[Long]())
lazy val One = new BigInt(1, Array[Long](1))
lazy val Two = new BigInt(1, Array[Long](2))

private lazy val cacheSize = smallValues.length

def apply(num: Long): BigInt = {
// Is the number cached?
if (0 <= num && num < cacheSize) smallValues(num.toInt)
// Figure out the sign and make the number positive after that
else {
val (sign, value) = if (num < 0) (-1, num * -1) else (1, num)
new BigInt(sign, Array(value))
}
}
}

class BigInt private(val sign: Int, val num: Array[Long]) extends Ordered[BigInt] {
println("Constructing BigInt")
...
}
``````

The problem here is that accessing one element of the array forces the evaluation of all elements:

``````scala> BigInt.smallValues(0)
Constructing BigInt
Constructing BigInt
Constructing BigInt
res0: BigInt = BigInt@2c176570
``````

How could I solve that?

Edit: Looking at the proposed solutions I really wonder if it wouldn't be more efficient to just allocate them without further complication. What do you think?

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For the given example, the lazy allocation of three objects, amassing to maybe some 30 Bytes (no Idea about the exact number) seems a bit counter productive. The laziness is also causing overhead. –  ziggystar Jul 1 '11 at 19:20
Yes, that's what I'm thinking too. The cache might hold 33 entries (16 negative, 0 and 16 positive), I'm strating to think the strict way might work, too. –  soc Jul 1 '11 at 19:49
I thought this was a toy example. If it's meant to be realistic then yes being lazy makes no sense. The objects are bigger in the lazy version than the strict version. –  James Iry Jul 1 '11 at 20:06

Editing my answer because I thought this was a toy example of what you want to do and that your real objects were so expensive to build that laziness bought you something. If the question shows something more like real code then laziness makes no sense. The lazy object are bigger and more expensive to create than the strict ones are. Still, I'm keeping the following code because it does show how create a lazy wrapper and that it does "work" (in the sense that it's functionally correct) even if it doesn't "work" in the sense of being a good idea for your use case.

``````class Lazy[T] (expr : => T) {lazy val ! = expr}
object Lazy{def apply[T](expr : => T) = new Lazy({expr})}

class BigInt (val sign: Int, val num: Array[Long]) {
println("Constructing BigInt")
}

object BigInt {
val smallValues = Array(
Lazy(new BigInt(0, Array[Long]())),
Lazy(new BigInt(1, Array[Long](1))),
Lazy(new BigInt(1, Array[Long](2)))
)

private val cacheSize = smallValues.length.toLong

def apply(num: Long): BigInt = {
// Is the number cached?
if (0 <= num && num < cacheSize) smallValues(num.toInt)!
// Figure out the sign and make the number positive after that
else {
val (sign, value) = if (num < 0) (-1, num * -1) else (1, num)
new BigInt(sign, Array(value))
}
}
}

scala> BigInt(1)
Constructing BigInt
res0: BigInt = BigInt@c0dd841

scala> BigInt(1)
res1: BigInt = BigInt@c0dd841

scala> BigInt(2)
Constructing BigInt
res2: BigInt = BigInt@4a6a00ca

scala> BigInt(2)
res3: BigInt = BigInt@4a6a00ca
``````
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Create your own lazy wrapper, possibly with an implicit to convert away from it so you don't notice you're using it:

``````class Lazy[A](a0: => A) { lazy val value = a0 }
implicit def lazy_to_actual[a](lz: Lazy[A]) = lz.value
``````

Then:

``````lazy val smallValues = Array(
new Lazy(new BigInt(0, new Array[Long]())),
new Lazy(new BigInt(1, new Array[Long](1))),
new Lazy(new BigInt(2, new Array[Long](2)))
)
``````

though if I were you, I'd probably use a map instead.

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