Suppose I am writing diff(s1: String, s2: String): List[String] to check if s1 == s2 and return a list of errors :

  • s1[i] != s2[i] the error is s1[i] != s2[i]
  • s1[i] if i >= s2.length the error is s1[i] is undefined
  • s2[i] if i >= s1.length the error is s2[i] is missing

for example:

diff("a", "a")     // returns Nil
diff("abc", "abc") // Nil
diff("xyz", "abc") // List("x != a", "y != b", "z != c")
diff("abcd", "ab") // List("c is undefined", "d is undefined")
diff("ab", "abcd") // List("c is missing", "d is missing")
diff("", "ab")     // List("a is missing", "b is missing")  
diff("axy", "ab")  // List("x != b", "y is undefined") 

How would you write it ?

P.S. I am writing diff like that:

def compare(pair: (Option[Char], Option[Char])) = pair match { 
  case (Some(x), None)    => Some(s"$x is undefined")
  case (None, Some(y))    => Some(s"$y is missing")
  case (Some(x), Some(y)) => if (x != y) Some(s"$x != $y") else None 
  case _ => None

def diff(s1: String, s2: String) = {
  val os1 = s1.map(Option.apply)
  val os2 = s2.map(Option.apply)
  os1.zipAll(os2, None, None).flatMap(compare)
  • 4
    Are you prioritizing clarity and correctness? If so your implementation looks pretty good to me. If you will be applying it to very large strings or you care about performance, though, it's not at all what you want. – Travis Brown Feb 16 at 17:25
  • Thank you for the reply ! I am prioritizing clarity but now I am slowly realizing that traversing the strings three times is clearly suboptimal. I will think how to improve it. – Michael Feb 16 at 17:44
  • 2
    If you're looking for general improvements to your code, codereview.stackexchange.com might be a better site. – Brian McCutchon Feb 16 at 18:07
  • Thanks, maybe I will post this question there. – Michael Feb 16 at 18:09

A little more concise

First of all, here's how I'd implement this method off the top of my head:

def diff(s1: String, s2: String): List[String] =
  (s1, s2).zipped.collect {
    case (x, y) if x != y => s"$x != $y"
  }.toList ++
    s1.drop(s2.length).map(x => s"$x is undefined") ++
    s2.drop(s1.length).map(y => s"$y is missing")

It's about half as many characters as your original implementation, and to my eye it's at least as readable. You could argue that the drop trick is a little too clever, and you'd probably be right, but I think it reads nicely once you get it.

A little more efficient

A method like this is self-contained and easy to test, and if there's any chance it's likely to be used in situations where performance is important, an imperative implementation is worth considering. Here's a quick sketch of how I'd do it:

def diffFast(s1: String, s2: String): IndexedSeq[String] = {
  val builder = Vector.newBuilder[String]

  def diff(short: String, long: String, status: String) = {
    var i = 0

    while (i < short.length) {
      val x = s1.charAt(i)
      val y = s2.charAt(i)
      if (x != y) builder += s"$x != $y"
      i += 1

    while (i < long.length) {
      val x = long.charAt(i)
      builder += s"$x is $status"
      i += 1

  if (s1.length <= s2.length) diff(s1, s2, "missing")
    else diff(s2, s1, "undefined")


You might be able to make this a little faster by hinting the size, etc. [update: I went ahead and added this], but this version is probably pretty close to optimal, and I also find it quite readable—it's not as clear to my eye as either my short implementation above or your original, but I find it much nicer than the recursive implementation in the other answer.

Note that this returns an IndexedSeq, not a List. In this it follows your original implementation, not the signature in your first sentence. If you need a List you can just change Vector.newBuilder to List.newBuilder, but the vector version is likely to be a little faster for most cases.


We could speculate about performance all day, but it's so easy to run some quick JMH microbenchmarks that we might as well do that instead (full source here). I'll take the following pair of strings as a simple example:

val example1: String = "a" * 1000
val example2: String = "ab" * 100

We can measure throughput for this input for your original version (both as it is and returning a List), my concise version, my fast version (returning both IndexedSeq and List), and Tim's recursive version:

Benchmark                 Mode  Cnt       Score     Error  Units
DiffBench.checkConcise   thrpt   20   47412.127 ± 550.693  ops/s
DiffBench.checkFast      thrpt   20  108661.093 ± 371.827  ops/s
DiffBench.checkFastList  thrpt   20   91745.269 ± 157.128  ops/s
DiffBench.checkOrig      thrpt   20    8129.848 ±  59.989  ops/s
DiffBench.checkOrigList  thrpt   20    7916.637 ±  15.736  ops/s
DiffBench.checkRec       thrpt   20   62409.682 ± 580.529  ops/s

So in short: your original implementation is really pretty poor as far as performance is concerned (I'd guess more because of all the allocations than the multiple traversals), my concise implementation is competitive with the (arguably less readable) recursive one and gets about six times more throughput than the original, and the imperative implementation is close to twice as fast as any of the others.

  • Your implementation is not exactly the same as the original one (there is a difference between "is undefined" and "is missing" when the character is missing in the left/right string). It does not diminish the relevance of the optimized version :) – Julien Lafont Feb 17 at 14:53
  • Thanks a lot, Travis ! I liked both the concise implementation and benchmarks. Just did not find how you handle the "missing" case. – Michael Feb 17 at 15:13
  • @Michael If you want to handle the missing characters asymmetrically, then map the two lists with the dropped prefix separately: def diff(s1: String, s2: String): List[String] = (s1, s2).zipped.collect { case (x, y) if x != y => s"$x != $y" }.toList ++ s1.drop(s2.length).map(_ + " is undefined") ++ s2.drop(s1.length).map(_ + " is missing"). In the optimized imperative version, you could pass the error message as third argument to diff in the if-else, this shouldn't change the results of the benchmarks significantly. – Andrey Tyukin Feb 17 at 17:12
  • @AndreyTyukin Got it :) Thanks. – Michael Feb 17 at 19:04
  • 1
    Thanks for noting the problem with the message—I've updated the answer and am rerunning the benchmarks now. – Travis Brown Feb 17 at 21:01

[ See below for original answer ]

This can be done with a recursive algorithm:

def diff(a: String, b: String): List[String] = {
  def loop(l: List[Char], r: List[Char], res: List[String]): List[String] =
    (l, r) match {
      case (Nil, Nil) =>
      case (undef, Nil) =>
        res.reverse ++ undef.map(c => s"$c is undefined")
      case (Nil, miss) =>
        res.reverse ++ miss.map(c => s"$c is missing")
      case (lh :: lt, rh :: rt) if lh != rh =>
        loop(lt, rt, s"$lh != $rh" +: res)
      case (_ :: lt, _ :: rt) =>
        loop(lt, rt, res)

  loop(a.toList, b.toList, Nil)

Personally I find this more obvious than using Option/zipAll/flatMap, but this is clearly a matter of taste and what you happen to be familiar with. I think this is more flexible because, for example, it can be easily modified to generate a single error string for all the undefined/missing characters.

If efficiency is important then this version uses Iterator to avoid creating temporary lists, and uses nested if/else rather than match:

def diff(a: String, b: String): List[String] = {
  val l = a.toIterator
  val r = b.toIterator

  def loop(res: List[String]): List[String] =
    if (l.isEmpty) {
      res.reverse ++ r.map(c => s"$c is missing")
    } else {
      if (r.isEmpty) {
        res.reverse ++ l.map(c => s"$c is undefined")
      } else {
        val lhead = l.next()
        val rhead = r.next()

        if (lhead == rhead) {
        } else {
          loop(s"$lhead != $rhead" +: res)


Thanks to Brian McCutchon for pointing out the problem with using String rather than List[Char], and Andrey Tyukin for encouraging me to post a more efficient solution.

Original answer

A recursive implementation isn't too scary:

def diff(a: String, b: String): List[String] = {
  def loop(l: String, r: String, res: List[String]) : List[String] = (l, r) match {
    case ("", "") =>
    case (lrem, "") =>
      res ++ lrem.map(c => s"$c is undefined")
    case ("", rrem) =>
      res ++ rrem.map(c => s"$c is missing")
    case _ if l.head != r.head =>
      loop(l.tail, r.tail, res :+ s"${l.head} != ${r.head}")
    case _ =>
      loop(l.tail, r.tail, res)

 loop(a, b, Nil)

This should perform OK unless there are a lot of errors in which case appending to res will get expensive. You can fix this by prepending to res and then reversing at the end if necessary, but it makes the code less clear.

  • 4
    Who cares about "less clear" if this thing has the wrong asymptotic behavior? If you feed a medium sized source code file to it (50000 characters, between 1000 and 1500 lines, say), it unexpectedly hangs for over a minute. I assume that if you give it a short story with around 150000 characters, it will never return. Even worse: it might "look OK" during tests, but then simply die in production, because no one would expect a O(n^2) algorithm for an obviously O(n) problem. – Andrey Tyukin Feb 16 at 18:44
  • 1
    Your code is O(n^2) even if you fix the problem of appending to List and even if there are no errors, since you are repeatedly calling tail on strings. You could solve this by converting the strings to lists first. Overall, though, this solution is both less clear (IMO) and less efficient than the OP's code. – Brian McCutchon Feb 16 at 22:51
  • @BrianMcCutchon Thanks for your comments, I was thinking of lists and had missed the point about the cost of tail on a String. As to which is clearer I guess it is just a matter of opinion :). Since the output is clearly human-readable I was under the impression that this was not going to be used to generate large numbers of errors, and therefore the cost of the append would not be important. – Tim Feb 16 at 23:06
  • @AndreyTyukin I wrote the full version using reverse and it is more than just eight extra characters, so I opted for the simpler but less efficient version as a way of presenting a different approach to the problem. – Tim Feb 16 at 23:16
  • @Tim, thank you for the detailed and thoughtful answer. – Michael Feb 17 at 8:07

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