# Scala recursion vs loop: performance and runtime considerations

I've wrote a naïve test-bed to measure the performance of three kinds of factorial implementation: loop based, non tail-recursive and tail-recursive.

Surprisingly to me the worst performant was the loop ones («while» was expected to be more efficient so I provided both) that cost almost twice than the tail recursive alternative.

ANSWER: fixing the loop implementation avoiding the *= operator wich outperform worst with BigInt due to its internals «loops» became fastest as expected

Another «woodoo» behaviour I've experienced was the StackOverflow exception which wasn't thrown sistematically for the same input in the case of non-tail recursive implementation. I can circumvent the StackOverlow by progressively call the function with larger and larger values… I feel crazy :) Answer: JVM require to converge during startup, then behaviour is coherent and systematic

This is the code:

``````final object Factorial {
type Out = BigInt

def calculateByRecursion(n: Int): Out = {
require(n>0, "n must be positive")

n match {
case _ if n == 1 => return 1
case _ => return n * calculateByRecursion(n-1)
}
}

def calculateByForLoop(n: Int): Out = {
require(n>0, "n must be positive")

var accumulator: Out = 1
for (i <- 1 to n)
accumulator = i * accumulator
accumulator
}

def calculateByWhileLoop(n: Int): Out = {
require(n>0, "n must be positive")

var accumulator: Out = 1
var i = 1
while (i <= n) {
accumulator = i * accumulator
i += 1
}
accumulator
}

def calculateByTailRecursion(n: Int): Out = {
require(n>0, "n must be positive")

@tailrec def fac(n: Int, acc: Out): Out = n match {
case _ if n == 1 => acc
case _ => fac(n-1, n * acc)
}

fac(n, 1)
}

def calculateByTailRecursionUpward(n: Int): Out = {
require(n>0, "n must be positive")

@tailrec def fac(i: Int, acc: Out): Out = n match {
case _ if i == n => n * acc
case _ => fac(i+1, i * acc)
}

fac(1, 1)
}

def comparePerformance(n: Int) {
def showOutput[A](msg: String, data: (Long, A), showOutput:Boolean = false) =
showOutput match {
case true => printf("%s returned %s in %d ms\n", msg, data._2.toString, data._1)
case false => printf("%s in %d ms\n", msg, data._1)
}
def measure[A](f:()=>A): (Long, A) = {
val start = System.currentTimeMillis
val o = f()
(System.currentTimeMillis - start, o)
}
showOutput ("By for loop", measure(()=>calculateByForLoop(n)))
showOutput ("By while loop", measure(()=>calculateByWhileLoop(n)))
showOutput ("By non-tail recursion", measure(()=>calculateByRecursion(n)))
showOutput ("By tail recursion", measure(()=>calculateByTailRecursion(n)))
showOutput ("By tail recursion upward", measure(()=>calculateByTailRecursionUpward(n)))
}
}
``````

What follows is some output from sbt console (Before «while» implementation):

``````scala> example.Factorial.comparePerformance(10000)
By loop in 3 ns
By non-tail recursion in >>>>> StackOverflow!!!!!… see later!!!
........

scala> example.Factorial.comparePerformance(1000)
By loop in 3 ms
By non-tail recursion in 1 ms
By tail recursion in 4 ms

scala> example.Factorial.comparePerformance(5000)
By loop in 105 ms
By non-tail recursion in 27 ms
By tail recursion in 34 ms

scala> example.Factorial.comparePerformance(10000)
By loop in 236 ms
By non-tail recursion in 106 ms     >>>> Now works!!!
By tail recursion in 127 ms

scala> example.Factorial.comparePerformance(20000)
By loop in 977 ms
By non-tail recursion in 495 ms
By tail recursion in 564 ms

scala> example.Factorial.comparePerformance(30000)
By loop in 2285 ms
By non-tail recursion in 1183 ms
By tail recursion in 1281 ms
``````

What follows is some output from sbt console (After «while» implementation):

``````scala> example.Factorial.comparePerformance(10000)
By for loop in 252 ms
By while loop in 246 ms
By non-tail recursion in 130 ms
By tail recursion in 136 ns

scala> example.Factorial.comparePerformance(20000)
By for loop in 984 ms
By while loop in 1091 ms
By non-tail recursion in 508 ms
By tail recursion in 560 ms
``````

What follows is some output from sbt console (after «upward» tail recursion implementation) the world come back sane:

``````scala> example.Factorial.comparePerformance(10000)
By for loop in 259 ms
By while loop in 229 ms
By non-tail recursion in 114 ms
By tail recursion in 119 ms
By tail recursion upward in 105 ms

scala> example.Factorial.comparePerformance(20000)
By for loop in 1053 ms
By while loop in 957 ms
By non-tail recursion in 513 ms
By tail recursion in 565 ms
By tail recursion upward in 470 ms
``````

What follows is some output from sbt console after fixing BigInt multiplication in «loops»: the world is totally sane:

``````    scala> example.Factorial.comparePerformance(20000)
By for loop in 498 ms
By while loop in 502 ms
By non-tail recursion in 521 ms
By tail recursion in 611 ms
By tail recursion upward in 503 ms
``````

BigInt overhead and a stupid implementation by me masked the expected behaviour.

Thanks guys

PS.: In the end I should re-title this post to «A lernt lesson on BigInts»

-
what is the question? –  Dan Feb 28 '13 at 15:01
"Loops should be avoided" This is misleading, for-loops are generally far slower than equivalent while loops in scala. Tail recursion is usually faster than non-tail recursion, I'm going to go out on a limb and say it's slower because of the closure you're creating before the function starts. –  Score_Under Feb 28 '13 at 15:03
Who can help me understand this behaviour pointing me to an authoritative reference. –  Lord of the Goo Feb 28 '13 at 15:03
@Score_Under: I dont' see any closure in act in the tail recursive implementation, which one do you mean? –  Lord of the Goo Feb 28 '13 at 15:06
Rex nailed the main issues, but you should research benchmark on the JVM, because you are doing it wrong. It is very, very hard to properly do benchmarks on the JVM, and it's hard to extrapolate anything useful from their results (what applies to microbenchmarks does not apply in a larger context). Of note here, you are not garbage collecting before starting the tests, which is bound to produce large variations. –  Daniel C. Sobral Feb 28 '13 at 15:13

For loops are not actually quite loops; they're for comprehensions on a range. If you actually want a loop, you need to use `while`. (Actually, I think the `BigInt` multiplication here is heavyweight enough so it shouldn't matter. But you'll notice if you're multiplying `Int`s.)

Also, you have confused yourself by using `BigInt`. The bigger your `BigInt` is, the slower your multiplication. So your non-tail loop counts up while your tail recursion loop counds down which means that the latter has more big numbers to multiply.

If you fix these two issues you will find that sanity is restored: loops and tail recursion are the same speed, with both regular recursion and `for` slower. (Regular recursion may not be slower if the JVM optimization makes it equivalent)

(Also, the stack overflow fix is probably because the JVM starts inlining and may either make the call tail-recursive itself, or unrolls the loop far enough so that you don't overflow any longer.)

Finally, you're getting poor results with for and while because you're multiplying on the right rather than the left with the small number. It turns out that the Java's BigInt multiplies faster with the smaller number on the left.

-
I'm confused. By looking at the code I would say that both count down. Is it due to tail recursion that the order has somehow changed? –  bluenote10 Feb 28 '13 at 15:13
I've just add a «while» implementation that outperform as the «for»… gimme 1' to integrate your perl! –  Lord of the Goo Feb 28 '13 at 15:14
@bluenote10 - Regular recursion calculates the deepest value first. Tail recursion does the opposite, as written. Write out a few terms and you'll see it. –  Rex Kerr Feb 28 '13 at 15:15
And what your opinion about missing of determinism in throwing StackOverflow exceptions?… I'm still of the opinion that some kind of memoization works under the hood –  Lord of the Goo Feb 28 '13 at 15:17
@LordoftheGoo - I added that to the answer. It's hard to know for sure without a JVM kitted out to print the assembly during inlining. –  Rex Kerr Feb 28 '13 at 15:18