# Scala int value of String characters

I just want to sum the digits of a BigInt. I can do

``````scala> "1 2 3".split(" ").map(_.toInt).sum
res23: Int = 6
``````

So I tried

``````scala> BigInt(123).toString().map(_.toInt).sum
res24: Int = 150
``````

This doesn't work because it maps the characters to their Unicode values.

Both the following work, but is there a more elegant way than using the Java static method or an extra toString conversion?

``````BigInt(123).toString().map(Character.getNumericValue(_)).sum
BigInt(123).toString().map(_.toString.toInt).sum
``````

(I've also done it using a recursive function, sidestepping strings altogether, but I'm interested here in a concise 1-liner.)

-

Wow... these answers are all over the place! Here, do this:

``````BigInt(123).toString().map(_.asDigit).sum
``````
-
Nice to see another way. It's the same in terms of performance and conciseness as `BigInt(123).toString().map(_.getNumericValue).sum` (well, the name is a bit shorter), and seems to do the same thing. –  Luigi Plinge Jun 6 '11 at 22:09
@Luigi The fastest way is probably `map(_ - '0')`. –  Daniel C. Sobral Jun 6 '11 at 23:03

How about not using Strings at all?

``````def sumDigits(b:BigInt):BigInt = {
if (b < 10) b else b%10 + sumDigits(b/10)
}
``````
-
+1: Definitely preferable in real world, though it may be the "recursive function, sidestepping strings altogether" mentioned in the question. –  Don Roby Jun 4 '11 at 18:00
the OP also says he is interested in a "concise 1-liner", indicating that his "recursive function, sidestepping strings altogether" wasn't as concise. –  Kim Stebel Jun 4 '11 at 18:03
Thanks, yep I'd got something similar already, but nice to know that this is the real-world way to go! –  Luigi Plinge Jun 4 '11 at 20:50
This, it turns out, is a horrible answer in disguise! (I initially though it looked good.) It is not tail recursive and uses `O(N^2)` memory where `N` is the number of binary digits! If you avoid this horrible fate by making it tail recursive, it still takes an order of magnitude longer than `.toString`. –  Rex Kerr Jun 4 '11 at 21:18
@Rex Kerr: Interesting point, and you're right... I guess I shouldn't prefer this in the real world as previously noted! I'll leave my upvote though. –  Don Roby Jun 4 '11 at 21:32

This is not short, and certainly not efficient, but it is another way to go:

``````scala> Iterator.iterate(BigInt(123))(_/10).takeWhile(_>0).map(_%10).sum
res1: scala.math.BigInt = 6
``````

(and you probably want an `Int`, which is faster anyway but requires `.map(i=>(i%10).toInt)`.)

The problem with this method (and straightforward recursion) is that you have to compute as many divisions as digits. (You could use `/%` to speed things up by a factor of 2, but that's still a problem.) Converting to a string is much faster because all those explicit `BigInt` creations can be avoided.

If you actually want something that works fast (not what you asked for, I know), you need a divide-and-conquer approach:

``````def fastDigitSum(b: BigInt): Int = {
val bits = b.bitLength
if (bits < 63) math.abs(b.toLong).toString.map(_-'0').sum
else {
val many = 256
val zeros = math.ceil(bits*0.150515).toInt // constant is 0.5*log(2)/log(10)
val root = (
if (zeros<many) BigInt("1" + "0"*zeros)
else {
Iterator.iterate((BigInt("1"+"0"*many),many))(x => (x._1 * x._1, 2*x._2)).
find(_._2 > zeros/2).get._1
}
)
val (q,r) = b /% root
fastDigitSum(q) + fastDigitSum(r)
}
}
``````

Edit: If you want really fast conversions at all sizes, I've modified my scheme as follows. There are some not-entirely-functional bits due largely to a lack of a `takeTo` method. This should be faster than everything else at all sizes (though it asymptotes to `fastDigitSum` performance for very large BigInts).

Probably will run better on 64 bit machines than 32.

No strings were harmed in the making of this function.

``````object DigitSum {
val memend = BigInt(10000000000000000L) :: BigInt(100000000) :: Nil

def longSum(l: Long, sum: Int = 0): Int = {
if (l==0) sum else longSum(l/10, sum + (l%10).toInt)
}

def bigSum(b: BigInt, memo: List[BigInt] = Nil): Int = {
val bits = b.bitLength
if (bits < 64) longSum(b.toLong)
else {
val mem = (
if (memo.isEmpty) {
var xs = memend
while (xs.head.bitLength*4 <= bits) xs = it.next :: xs
xs
}
else memo.dropWhile(_.bitLength > bits/2)
)
val (q,r) = b /% mem.head
bigSum(q,memo) + bigSum(r,memo)
}
}
}
``````

(Okay--this is ending up sort of like code golf at this point.)

-
+1 for interesting technique –  Luigi Plinge Jun 4 '11 at 20:56
I did a benchmark - see post below –  Luigi Plinge Jun 4 '11 at 23:36

I don't think it's much better than the ones you've already got, but

``````BigInt(123).toString().split("").tail.map(_.toInt).sum
``````

also works.

Also

``````BigInt(123).toString().map(_.toInt - '0'.toInt).sum
``````

and per Rex Kerr's comment, this can be simplified to

``````BigInt(123).toString().map(_-'0').sum
``````
-
You've got it--the `.toInt`s are unnecessary since all math converts to integers. You just need `map(_ - '0')`! –  Rex Kerr Jun 4 '11 at 21:02

I just noticed that the RichChar class has a getNumericValue method, so the answer would be

``````BigInt(123).toString().map(_.getNumericValue).sum
``````
-
This is actually longer than `.toString.toInt`. This doesn't sound like a very good answer unless you wanted something that you didn't specify. Roby's got the shortest answer (with my suggestion). –  Rex Kerr Jun 4 '11 at 21:07
@Rex I'm not too worried about how many letters there are in a method name - for me conciseness means fewer operations –  Luigi Plinge Jun 4 '11 at 22:10

This in not an answer to the question but a speed test of the suggestions. I ran the tests several times to ensure the VM was warmed up and results were consistent: these results are representative and are for 10000 iterations. See code for definitions of what these methods are.

For 10-digit BigInts

``````fastDigitSum: 0.020618047 seconds
stringSum:    0.023708908 seconds
stringSum2:   0.02940999 seconds
stringSum3:   0.021641507 seconds
division:     0.052856631 seconds
``````

For 50-digit BigInts

``````fastDigitSum: 0.183630732 seconds
stringSum:    0.110235062 seconds
stringSum2:   0.134900857 seconds
stringSum3:   0.096670394 seconds
division:     0.317359989 seconds
``````

For 100-digit BigInts

``````fastDigitSum: 0.427543476 seconds
stringSum:    0.228062302 seconds
stringSum2:   0.277711389 seconds
stringSum3:   0.20127497 seconds
division:     0.811950252 seconds
``````

For 100,000-digit BigInts (1 iteration)

``````fastDigitSum: 0.581872856 seconds
stringSum:    2.642719635 seconds
stringSum2:   2.629824347 seconds
stringSum3:   2.61327453 seconds
division:     30.089482042 seconds
``````

So it seems `BigInt(123).toString().map(_-'0').sum` is the winner for speed and conciseness for smaller BigInts, but Rex Kerr's method is good if your BigInts are huge.

Benchmark code:

``````object Benchmark extends App{
def fastDigitSum(b: BigInt): Int = {
val bits = b.bitLength
if (bits < 63) math.abs(b.toLong).toString.map(_-'0').sum
else {
val many = 256
val zeros = math.ceil(bits*0.150515).toInt // constant is 0.5*log(2)/log(10)
val root = (
if (zeros<many) BigInt("1" + "0"*zeros)
else {
Iterator.iterate((BigInt("1"+"0"*many),many))(x => (x._1 * x._1, 2*x._2)).
find(_._2 > zeros/2).get._1
}
)
val (q,r) = b /% root
fastDigitSum(q) + fastDigitSum(r)
}
}

def stringSum(b: BigInt) = b.toString.map(_.getNumericValue).sum
def stringSum2(b: BigInt) = b.toString.map(_.toString.toInt).sum
def stringSum3(b: BigInt) = b.toString.map(_ - '0').sum

def division(b: BigInt) = sumDig(b, 0)
def sumDig(b: BigInt, sum: Int):Int = {
if (b == 0) sum
else sumDig(b / 10, sum + (b % 10).toInt)
}

def testMethod(f: BigInt => Int):Double = {
val b = BigInt("12345678901234567890123456789012345678901234567890")
val b2 = BigInt("1234567890")
val b3 = BigInt("1234567890123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890")
val t0 = System.nanoTime()
var i = 0
while(i < 10000){
f(b3)
i += 1
}
(System.nanoTime().toDouble - t0)/1e9
}

def runTest(){
var i = 0
while (i < 5) {
println("fastDigitSum: " + testMethod ({fastDigitSum}) + " seconds")
println("stringSum:    " + testMethod ({stringSum}) + " seconds")
println("stringSum2:   " + testMethod ({stringSum2}) + " seconds")
println("stringSum3:   " + testMethod ({stringSum3}) + " seconds")
println("division:     " + testMethod ({division}) + " seconds")
i += 1
}
}

runTest()
}
``````
-
Why don't you try a BigInt with 100,000 digits? (Just one run is enough to time, you don't need to do it 10k times.) –  Rex Kerr Jun 5 '11 at 0:39
@Rex - indeed, then your method wins. I have updated the results. –  Luigi Plinge Jun 5 '11 at 0:58
My method wins for more sizes on my machine, but anyway, I've updated it so it should win everywhere all the time :) –  Rex Kerr Jun 5 '11 at 4:03
@Rex yep, your new version is 2-3 times faster than anything else, definitely the way to go if speed is the prime consideration. Congrats! –  Luigi Plinge Jun 6 '11 at 22:14