Levenshtein distance/Alignment

The Levenshtein distance algorithm returns the number of atomic operations (insertion, deletion or edition) that must be performed on a string in order to obtain an other one, but it does not say anything about the actual operations used or their order.

An alignment is a notation used to describe the operations used to turn a string into an other. At some point in the strings, the minus character ('-') is placed in order to signify that a character must be added at this very place. For instance, an alignment between the words 'place' and 'palace' is:

P-LACE
PALACE

Task

Write a function that shows the alignment of two strings for the corresponding levenshtein distance.

As an example, use the words "rosettacode" and "raisethysword".

You can either implement an algorithm, or use a dedicated library (thus showing us how it is named in your language).

C

<lang c>#include <stdio.h>

include <stdlib.h>
include <string.h>

typedef struct edit_s edit_t, *edit; struct edit_s { char c1, c2; int n; edit next; };

void leven(char *a, char *b) { int i, j, la = strlen(a), lb = strlen(b); edit *tbl = malloc(sizeof(edit) * (1 + la)); tbl[0] = calloc((1 + la) * (1 + lb), sizeof(edit_t)); for (i = 1; i <= la; i++) tbl[i] = tbl[i-1] + (1+lb);

for (i = la; i >= 0; i--) { char *aa = a + i; for (j = lb; j >= 0; j--) { char *bb = b + j; if (!*aa && !*bb) continue;

edit e = &tbl[i][j]; edit repl = &tbl[i+1][j+1]; edit dela = &tbl[i+1][j]; edit delb = &tbl[i][j+1];

e->c1 = *aa; e->c2 = *bb; if (!*aa) { e->next = delb; e->n = e->next->n + 1; continue; } if (!*bb) { e->next = dela; e->n = e->next->n + 1; continue; }

e->next = repl; if (*aa == *bb) { e->n = e->next->n; continue; }

if (e->next->n > delb->n) { e->next = delb; e->c1 = 0; } if (e->next->n > dela->n) { e->next = dela; e->c1 = *aa; e->c2 = 0; } e->n = e->next->n + 1; } }

edit p = tbl[0]; printf("%s -> %s: %d edits\n", a, b, p->n);

while (p->next) { if (p->c1 == p->c2) printf("%c", p->c1); else { putchar('('); if (p->c1) putchar(p->c1); putchar(','); if (p->c2) putchar(p->c2); putchar(')'); }

p = p->next; } putchar('\n');

free(tbl[0]); free(tbl); }

int main(void) { leven("raisethysword", "rosettacode"); return 0; }</lang>

Output:

raisethysword -> rosettacode: 8 edits
r(a,o)(i,)set(h,t)(y,a)(s,c)(w,)o(r,d)(d,e)

D

Using the standard library. <lang d>void main() {

   import std.stdio, std.algorithm;

   immutable s1 = "rosettacode";
   immutable s2 = "raisethysword";

   string s1b, s2b;
   size_t pos1, pos2;

   foreach (immutable c; levenshteinDistanceAndPath(s1, s2)[1]) {
       final switch (c) with (EditOp) {
           case none, substitute:
               s1b ~= s1[pos1++];
               s2b ~= s2[pos2++];
               break;
           case insert:
               s1b ~= "_";
               s2b ~= s2[pos2++];
               break;
           case remove:
               s1b ~= s1[pos1++];
               s2b ~= "_";
               break;
       }
   }

   writeln(s1b, "\n", s2b);

}</lang>

Output:

r_oset_tacode
raisethysword

Eiffel

<lang eiffel> distance (source, target: STRING): INTEGER -- Minimum number of operations to turn `source' into `target'. local l_distance: ARRAY2 [INTEGER] del, ins, subst: INTEGER do create l_distance.make (source.count, target.count) ⟳ ic:(1 |..| source.count) ¦ l_distance [ic, 1] := ic - 1 ⟲ ⟳ ij:(1 |..| target.count) ¦ l_distance [1, ij] := ij - 1 ⟲ ⟳ ic:(1 |..| source.count) ¦ ⟳ jc:(1 |..| target.count) ¦ if ic > 1 and jc > 1 then if source [ic] = target [jc] then l_distance [ic, jc] := l_distance [ic - 1, jc - 1] else del := l_distance [ic - 1, jc] ins := l_distance [ic, jc - 1] subst := l_distance [ic - 1, jc -1] l_distance [ic, jc] := del.min (ins.min (subst)) + 1 end end ⟲ ⟲ Result:= l_distance [source.count, target.count] end

</lang>

Output:

Result = 8

The ⟳ ¦ ⟲ represents the "symbolic form" of an Eiffel across loop. In the case above, we use two ⟳ (loops) to set the `l_distance' array elements, and then two nested ⟳ (loops) to walk the distance computation.

Also—the `ic' is this programmers shorthand for ITERATION_CURSOR. Therefore, in the nested loops, the `ic' is the iteration cursor following `i' and the `ij' is following `j' as indexes on the source, target, and l_distance.

Go

Library: biogo

Alignment computed by the Needleman-Wunch algorithm, which is used in bioinformatics. <lang go>package main

import (

   "fmt"

   "github.com/biogo/biogo/align"
   ab "github.com/biogo/biogo/alphabet"
   "github.com/biogo/biogo/feat"
   "github.com/biogo/biogo/seq/linear"

)

func main() {

   // Alphabets for things like DNA are predefined in biogo, but we
   // define our own here.
   lc := ab.Must(ab.NewAlphabet("-abcdefghijklmnopqrstuvwxyz",
       feat.Undefined, '-', 0, true))
   // Construct scoring matrix for Needleman-Wunch algorithm.
   // We leave zeros on the diagonal for the Levenshtein distance of an
   // exact match and put -1s everywhere else for the Levenshtein distance
   // of an edit.
   nw := make(align.NW, lc.Len())
   for i := range nw {
       r := make([]int, lc.Len())
       nw[i] = r
       for j := range r {
           if j != i {
               r[j] = -1
           }
       }
   }
   // define input sequences
   a := &linear.Seq{Seq: ab.BytesToLetters([]byte("rosettacode"))}
   a.Alpha = lc
   b := &linear.Seq{Seq: ab.BytesToLetters([]byte("raisethysword"))}
   b.Alpha = lc
   // perform alignment
   aln, err := nw.Align(a, b)
   // format and display result
   if err != nil {
       fmt.Println(err)
       return
   }
   fa := align.Format(a, b, aln, '-')
   fmt.Printf("%s\n%s\n", fa[0], fa[1])
   aa := fmt.Sprint(fa[0])
   ba := fmt.Sprint(fa[1])
   ma := make([]byte, len(aa))
   for i := range ma {
       if aa[i] == ba[i] {
           ma[i] = ' '
       } else {
           ma[i] = '|'
       }
   }
   fmt.Println(string(ma))

}</lang>

Output:

The lines after the alignment point out the 8 edits.

r-oset-tacode
raisethysword
 ||   |||| ||

Java

<lang java>public class LevenshteinAlignment {

   public static String[] alignment(String a, String b) {
       a = a.toLowerCase();
       b = b.toLowerCase();
       // i == 0
       int[][] costs = new int[a.length()+1][b.length()+1];
       for (int j = 0; j <= b.length(); j++)
           costs[0][j] = j;
       for (int i = 1; i <= a.length(); i++) {
           costs[i][0] = i;
           for (int j = 1; j <= b.length(); j++) {
               costs[i][j] = Math.min(1 + Math.min(costs[i-1][j], costs[i][j-1]), a.charAt(i - 1) == b.charAt(j - 1) ? costs[i-1][j-1] : costs[i-1][j-1] + 1);
           }
       }

// walk back through matrix to figure out path StringBuilder aPathRev = new StringBuilder(); StringBuilder bPathRev = new StringBuilder(); for (int i = a.length(), j = b.length(); i != 0 && j != 0; ) { if (costs[i][j] == (a.charAt(i - 1) == b.charAt(j - 1) ? costs[i-1][j-1] : costs[i-1][j-1] + 1)) { aPathRev.append(a.charAt(--i)); bPathRev.append(b.charAt(--j)); } else if (costs[i][j] == 1 + costs[i-1][j]) { aPathRev.append(a.charAt(--i)); bPathRev.append('-'); } else if (costs[i][j] == 1 + costs[i][j-1]) { aPathRev.append('-'); bPathRev.append(b.charAt(--j)); } }

       return new String[]{aPathRev.reverse().toString(), bPathRev.reverse().toString()};
   }

   public static void main(String[] args) {

String[] result = alignment("rosettacode", "raisethysword"); System.out.println(result[0]); System.out.println(result[1]);

}</lang>

Output:

r-oset-tacode
raisethysword

Julia

Works with: Julia version 0.6

Translation of: Java

<lang julia>function levenshteinalign(a::AbstractString, b::AbstractString)

   a = lowercase(a)
   b = lowercase(b)
   len_a = length(a)
   len_b = length(b)

   costs = Matrix{Int}(len_a + 1, len_b + 1)
   costs[1, :] .= 0:len_b
   @inbounds for i in 2:(len_a + 1)
       costs[i, 1] = i
       for j in 2:(len_b + 1)
           tmp = ifelse(a[i-1] == b[j-1], costs[i-1, j-1], costs[i-1, j-1] + 1)
           costs[i, j] = min(1 + min(costs[i-1, j], costs[i, j-1]), tmp)
       end
   end

   apathrev = IOBuffer()
   bpathrev = IOBuffer()
   local i = len_a + 1
   local j = len_b + 1
   @inbounds while i != 1 && j != 1
       tmp = ifelse(a[i-1] == b[j-1], costs[i-1, j-1], costs[i-1, j-1] + 1)
       if costs[i, j] == tmp
           i -= 1
           j -= 1
           print(apathrev, a[i])
           print(bpathrev, b[j])
       elseif costs[i, j] == 1 + costs[i-1, j]
           i -= 1
           print(apathrev, a[i])
           print(bpathrev, '-')
       elseif costs[i, j] == 1 + costs[i, j-1]
           j -= 1
           print(apathrev, '-')
           print(bpathrev, b[j])
       end
   end

   return reverse(String(take!(apathrev))), reverse(String(take!(bpathrev)))

end

foreach(println, levenshteinalign("rosettacode", "raisethysword")) foreach(println, levenshteinalign("place", "palace"))</lang>

Output:

r-oset-tacode
raisethysword
p-lace
palace

Kotlin

Translation of: Java

<lang scala>// version 1.1.3

fun levenshteinAlign(a: String, b: String): Array<String> {

   val aa = a.toLowerCase()
   val bb = b.toLowerCase()
   val costs = Array(a.length + 1) { IntArray(b.length + 1) }
   for (j in 0..b.length) costs[0][j] = j
   for (i in 1..a.length) {
       costs[i][0] = i
       for (j in 1..b.length) {
           val temp = costs[i - 1][j - 1] + (if (aa[i - 1] == bb[j - 1]) 0 else 1) 
           costs[i][j] = minOf(1 + minOf(costs[i - 1][j], costs[i][j - 1]), temp)
       }
   }

   // walk back through matrix to figure out path
   val aPathRev = StringBuilder()
   val bPathRev = StringBuilder()
   var i = a.length
   var j = b.length
   while (i != 0 && j != 0) {
       val temp = costs[i - 1][j - 1] + (if (aa[i - 1] == bb[j - 1]) 0 else 1)
       when (costs[i][j]) {
           temp -> {
               aPathRev.append(aa[--i])
               bPathRev.append(bb[--j])
           }

           1 + costs[i-1][j] -> {
               aPathRev.append(aa[--i])
               bPathRev.append('-')
           }

           1 + costs[i][j-1] -> {
               aPathRev.append('-')
               bPathRev.append(bb[--j])
           }
       }
   }
   return arrayOf(aPathRev.reverse().toString(), bPathRev.reverse().toString())

}

fun main(args: Array<String>) {

   var result = levenshteinAlign("place", "palace")
   println(result[0])
   println(result[1])
   println()    
   result = levenshteinAlign("rosettacode","raisethysword")
   println(result[0])
   println(result[1])

}</lang>

Output:

p-lace
palace

r-oset-tacode
raisethysword

Mathematica / Wolfram Language

This example is incorrect. It does not accomplish the given task. Please fix the code and remove this message.

Works with: Mathematica version 7

<lang Mathematica>DamerauLevenshteinDistance["rosettacode", "raisethysword"]</lang>

Output:

Nim

Translation of: Kotlin

<lang Nim>import algorithm, sequtils, strutils

proc levenshteinAlign(a, b: string): tuple[a, b: string] =

 let a = a.toLower()
 let b = b.toLower()
 var costs = newSeqWith(a.len + 1, newSeq[int](b.len + 1))
 for j in 0..b.len: costs[0][j] = j
 for i in 1..a.len:
   costs[i][0] = i
   for j in 1..b.len:
     let tmp = costs[i - 1][j - 1] + ord(a[i - 1] != b[j - 1])
     costs[i][j] = min(1 + min(costs[i - 1][j], costs[i][j - 1]), tmp)

 # Walk back through matrix to figure out path.
 var aPathRev, bPathRev: string
 var i = a.len
 var j = b.len
 while i != 0 and j != 0:
   let tmp = costs[i - 1][j - 1] + ord(a[i - 1] != b[j - 1])
   if costs[i][j] == tmp:
     dec i
     dec j
     aPathRev.add a[i]
     bPathRev.add b[j]
   elif costs[i][j] == 1 + costs[i-1][j]:
     dec i
     aPathRev.add a[i]
     bPathRev.add '-'
   elif costs[i][j] == 1 + costs[i][j-1]:
     dec j
     aPathRev.add '-'
     bPathRev.add b[j]
   else:
     quit "Internal error"

 result = (reversed(aPathRev).join(), reversed(bPathRev).join())

when isMainModule:

 var result = levenshteinAlign("place", "palace")
 echo result.a
 echo result.b
 echo ""

 result = levenshteinAlign("rosettacode","raisethysword")
 echo result.a
 echo result.b</lang>

Output:

p-lace
palace

r-oset-tacode
raisethysword

Perl

<lang perl>use strict; use warnings;

use List::Util qw(min);

sub levenshtein_distance_alignment {

   my @s = ('^', split //, shift);
   my @t = ('^', split //, shift);

   my @A;
   @{$A[$_][0]}{qw(d s t)} = ($_, join(, @s[1 .. $_]), ('~' x $_)) for 0 .. $#s;
   @{$A[0][$_]}{qw(d s t)} = ($_, ('-' x $_), join , @t[1 .. $_])  for 0 .. $#t;
   for my $i (1 .. $#s) {
       for my $j (1 .. $#t) {

if ($s[$i] ne $t[$j]) { $A[$i][$j]{d} = 1 + ( my $min = min $A[$i-1][$j]{d}, $A[$i][$j-1]{d}, $A[$i-1][$j-1]{d} ); @{$A[$i][$j]}{qw(s t)} = $A[$i-1][$j]{d} == $min ? ($A[$i-1][$j]{s}.$s[$i], $A[$i-1][$j]{t}.'-') : $A[$i][$j-1]{d} == $min ? ($A[$i][$j-1]{s}.'-', $A[$i][$j-1]{t}.$t[$j]) : ($A[$i-1][$j-1]{s}.$s[$i], $A[$i-1][$j-1]{t}.$t[$j]); }

           else {

@{$A[$i][$j]}{qw(d s t)} = ( $A[$i-1][$j-1]{d}, $A[$i-1][$j-1]{s}.$s[$i], $A[$i-1][$j-1]{t}.$t[$j] );

           }
       }
   }
   return @{$A[-1][-1]}{'s', 't'};

}

print join "\n", levenshtein_distance_alignment "rosettacode", "raisethysword";</lang>

Output:

ro-settac-o-de
raisethysword-

Phix

Translation of: Kotlin

plus the indicator from Go

<lang Phix>function LevenshteinAlignment(string a, b)

   integer la = length(a)+1,
           lb = length(b)+1
   sequence costs = repeat(repeat(0,lb),la)
   for j=1 to lb do
       costs[1][j] = j
   end for
   for i=2 to la do
       costs[i][1] = i
       for j=2 to lb do
           integer tmp1 = 1+min(costs[i-1][j], costs[i][j-1]),
                   tmp2 = costs[i-1][j-1] + (a[i-1]!=b[j-1])
           costs[i][j] = min(tmp1, tmp2)
       end for
   end for
   -- walk back through matrix to figure out the path
   string arev = "",
          brev = ""
   integer i = la, j = lb
   while i>1 and j>1 do
       integer tmp = costs[i-1][j-1] + (a[i-1]!=b[j-1])
       switch costs[i][j] do
           case tmp:                   i -= 1; arev &= a[i]
                                       j -= 1; brev &= b[j]
           case 1 + costs[i-1][j]:     i -= 1; arev &= a[i]
                                       brev &= '-'
           case 1 + costs[i][j-1]:     arev &= '-'
                                       j -= 1; brev &= b[j]
       end switch
   end while
   return {reverse(arev),reverse(brev)}

end function

procedure test(string a,b)

   {a,b} = LevenshteinAlignment(a,b)
   string c = sq_add(repeat(' ',length(a)),sq_mul(sq_ne(a,b),'|'-' '))
   printf(1,"%s\n%s\n%s\n\n",{a,b,c})

end procedure test("rosettacode", "raisethysword") test("place", "palace")</lang>

Output:

r-oset-tacode
raisethysword
 ||   |||| ||

p-lace
palace
 |

Python

<lang Python>from difflib import ndiff

def levenshtein(str1, str2):

   result = ""
   pos, removed = 0, 0
   for x in ndiff(str1, str2):
       if pos<len(str1) and str1[pos] == x[2]:
         pos += 1
         result += x[2]
         if x[0] == "-":
             removed += 1
         continue
       else:
         if removed > 0:
           removed -=1
         else:
           result += "-"
   print(result)

levenshtein("place","palace") levenshtein("rosettacode","raisethysword") </lang>

Output:

p-lace
ro-settac-o-de

Racket

Simple version (no aligment)

First we will analyze this solution that only computes the distance. See http://blog.racket-lang.org/2012/08/dynamic-programming-versus-memoization.html for a discussion of the code.

<lang racket>#lang racket

(define (memoize f)

 (local ([define table (make-hash)])
   (lambda args
     (dict-ref! table args (λ () (apply f args))))))

(define levenshtein

 (memoize
  (lambda (s t)
    (cond
      [(and (empty? s) (empty? t)) 0]
      [(empty? s) (length t)]
      [(empty? t) (length s)]
      [else
       (if (equal? (first s) (first t))
           (levenshtein (rest s) (rest t))
           (min (add1 (levenshtein (rest s) t))
                (add1 (levenshtein s (rest t)))
                (add1 (levenshtein (rest s) (rest t)))))]))))</lang>

Demonstration: <lang racket>(levenshtein (string->list "rosettacode")

            (string->list "raisethysword"))</lang>

Output:

Complete version

Now we extend the code from http://blog.racket-lang.org/2012/08/dynamic-programming-versus-memoization.html to show also the alignment. The code is very similar, but it stores the partial results (number of edits and alignment of each substring) in a lev structure. <lang Racket>#lang racket

(struct lev (n s t))

(define (lev-add old n sx tx)

 (lev (+ n (lev-n old))
      (cons sx (lev-s old))
      (cons tx (lev-t old))))

(define (list-repeat n v)

 (build-list n (lambda (_) v)))

(define (memoize f)

 (local ([define table (make-hash)])
   (lambda args
     (dict-ref! table args (λ () (apply f args))))))

(define levenshtein/list

 (memoize
  (lambda (s t)
    (cond
      [(and (empty? s) (empty? t)) 
       (lev 0 '() '())]
      [(empty? s) 
       (lev (length t) (list-repeat (length t) #\-) t)]
      [(empty? t) 
       (lev (length s) s (list-repeat (length s) #\-))]
      [else
       (if (equal? (first s) (first t))
           (lev-add (levenshtein/list (rest s) (rest t))
                    0 (first s) (first t))
           (argmin lev-n (list (lev-add (levenshtein/list (rest s) t)
                                        1 (first s) #\-)
                               (lev-add (levenshtein/list s (rest t))
                                        1 #\- (first t))
                               (lev-add (levenshtein/list (rest s) (rest t))
                                        1 (first s) (first t)))))]))))

(define (levenshtein s t)

 (let ([result (levenshtein/list (string->list s) 
                                 (string->list t))])
   (values (lev-n result)
           (list->string (lev-s result)) 
           (list->string (lev-t result)))))</lang>

Demonstration: <lang racket>(let-values ([(dist exp-s exp-t)

             (levenshtein "rosettacode" "raisethysword")])
 (printf "levenshtein: ~a edits\n" dist)
 (displayln exp-s)
 (displayln exp-t))</lang>

Output:

levenshtein: 8 edits
r-oset-taco-de
raisethysword-

Raku

(formerly Perl 6)

Translation of: Perl

<lang perl6>sub align ( Str $σ, Str $t ) {

   my @s = flat *, $σ.comb;
   my @t = flat *, $t.comb;
    
   my @A;
   @A[$_][ 0]<d s t> = $_, @s[1..$_].join, '-' x $_ for ^@s;
   @A[ 0][$_]<d s t> = $_, '-' x $_, @t[1..$_].join for ^@t;
    
   for 1 ..^ @s X 1..^ @t -> (\i, \j) {

if @s[i] ne @t[j] { @A[i][j]<d> = 1 + my $min = min @A[i-1][j]<d>, @A[i][j-1]<d>, @A[i-1][j-1]<d>; @A[i][j] = @A[i-1][j]<d> == $min ?? (@A[i-1][j] Z~ @s[i], '-') !! @A[i][j-1]<d> == $min ?? (@A[i][j-1] ~~Z~ '-', @t[j]) !! (@A[i-1][j-1] ~~Z~ @s[i], @t[j]); } else { @A[i][j]<d s t> = @A[i-1][j-1]<d s t> Z~ , @s[i], @t[j]; }~~~~

~~} return @A[*-1][*-1];~~
}
.say for align 'rosettacode', 'raisethysword';</lang>

~~Output:~~
~~ro-settac-o-de raisethysword-~~
~~Ruby~~
Translation of: Tcl
uses "lcs" from here <lang ruby>require 'lcs'
def levenshtein_align(a, b)
apos, bpos = LCS.new(a, b).backtrack2 c = "" d = "" x0 = y0 = -1 dx = dy = 0 apos.zip(bpos) do |x,y| diff = x + dx - y - dy if diff < 0 dx -= diff c += "-" * (-diff) elsif diff > 0 dy += diff d += "-" * diff end c += a[x0+1..x] x0 = x d += b[y0+1..y] y0 = y end c += a[x0+1..-1] d += b[y0+1..-1] diff = a.length + y0 - b.length - x0 if diff < 0 c += "-" * (-diff) elsif diff > 0 d += "-" * diff end [c, d]
end
puts levenshtein_align("rosettacode", "raisethysword")</lang>

~~Output:~~
~~r-oset-taco-de raisethysword-~~
~~Rust~~
~~Cargo.toml~~
~~[dependencies] edit-distance = "^1.0.0"~~
src/main.rs <lang Rust>extern crate edit_distance;
edit_distance("rosettacode", "raisethysword");</lang>
~~Scala~~

~~Output:~~

~~Best seen running in your browser either by ScalaFiddle (ES aka JavaScript, non JVM) or [1].~~

<lang Scala>import scala.collection.mutable import scala.collection.parallel.ParSeq
object LevenshteinAlignment extends App {
~~val vlad = new Levenshtein("rosettacode", "raisethysword") val alignment = vlad.revLevenstein()~~
~~class Levenshtein(s1: String, s2: String) { val memoizedCosts = mutable.Map[(Int, Int), Int]()~~
def revLevenstein(): (String, String) = { def revLev: (Int, Int, String, String) => (String, String) = { case (_, 0, revS1, revS2) => (revS1, revS2) case (0, _, revS1, revS2) => (revS1, revS2) case (i, j, revS1, revS2) => if (memoizedCosts(i, j) == (memoizedCosts(i - 1, j - 1) + (if (s1(i - 1) != s2(j - 1)) 1 else 0))) revLev(i - 1, j - 1, s1(i - 1) + revS1, s2(j - 1) + revS2) else if (memoizedCosts(i, j) == 1 + memoizedCosts(i - 1, j)) revLev(i - 1, j, s1(i - 1) + revS1, "-" + revS2) else revLev(i, j - 1, "-" + revS1, s2(j - 1) + revS2) }
~~revLev(s1.length, s2.length, "", "") }~~
private def levenshtein: Int = { def lev: ((Int, Int)) => Int = { case (k1, k2) => memoizedCosts.getOrElseUpdate((k1, k2), (k1, k2) match { case (i, 0) => i case (0, j) => j case (i, j) => ParSeq(1 + lev((i - 1, j)), 1 + lev((i, j - 1)), lev((i - 1, j - 1)) + (if (s1(i - 1) != s2(j - 1)) 1 else 0)).min }) }
~~lev((s1.length, s2.length)) }~~
~~levenshtein }~~
~~println(alignment._1) println(alignment._2)~~
~~}</lang>~~
~~Sidef~~
Translation of: Perl
~~<lang ruby>func align(s, t) {~~
~~s.chars!.prepend!('^') t.chars!.prepend!('^')~~
~~var A = []~~

for i (1 .. s.end) { for j (1 .. t.end) { if (s[i] != t[j]) { A[i][j]{:d} = 1+( var min = Math.min(A[i-1][j]{:d}, A[i][j-1]{:d}, A[i-1][j-1]{:d}) ) A[i][j]{@|

} = (A[i-1][j]{:d} == min ? [A[i-1][j]{:s}+s[i], A[i-1][j]{:t}+'-'] : (A[i][j-1]{:d} == min ? [A[i][j-1]{:s}+'-', A[i][j-1]{:t}+t[j]] : [A[i-1][j-1]{:s}+s[i], A[i-1][j-1]{:t}+t[j]]))... } else { A[i][j]{@|<d s t>} = ( A[i-1][j-1]{:d}, A[i-1][j-1]{:s}+s[i], A[i-1][j-1]{:t}+t[j], ) } } } return [A[-1][-1]{@|~~}] } align("rosettacode", "raisethysword").each { .say }</lang>~~

~~Output:~~
~~ro-settac-o-de raisethysword-~~
~~Tcl~~
Library: Tcllib (Package: struct::list)
~~<lang tcl>package require struct::list proc levenshtein/align {a b} {~~
~~lassign [struct::list longestCommonSubsequence [split $a ""] [split $b ""]]\~~
~~apos bpos~~
~~set c "" set d "" set x0 [set y0 -1] set dx [set dy 0] foreach x $apos y $bpos {~~
if {$x+$dx < $y+$dy} { set n [expr {($y+$dy)-($x+$dx)}] incr dx $n append c [string repeat "-" $n] } elseif {$x+$dx > $y+$dy} { set n [expr {($x+$dx)-($y+$dy)}] incr dy $n append d [string repeat "-" $n] } append c [string range $a $x0+1 $x] set x0 $x append d [string range $b $y0+1 $y] set y0 $y
~~} append c [string range $a $x0+1 end] append d [string range $b $y0+1 end] set al [string length $a] set bl [string length $b] if {$al+$y0 < $bl+$x0} {~~
~~append c [string repeat "-" [expr {$bl+$x0-$y0-$al}]]~~
~~} elseif {$bl+$x0 < $al+$y0} {~~
~~append d [string repeat "-" [expr {$al+$y0-$x0-$bl}]]~~
~~} return $c\n$d~~
}
puts [levenshtein/align "rosettacode" "raisethysword"]</lang>

~~Output:~~
~~r-oset-taco-de raisethysword-~~
~~Wren~~
Translation of: Kotlin
Library: Wren-str
Library: Wren-math
<lang ecmascript>import "/str" for Str import "/math" for Math
var levenshteinAlign = Fn.new { |a, b|
a = Str.lower(a) b = Str.lower(b) var costs = List.filled(a.count+1, null) for (i in 0..a.count) costs[i] = List.filled(b.count+1, 0) for (j in 0..b.count) costs[0][j] = j for (i in 1..a.count) { costs[i][0] = i for (j in 1..b.count) { var temp = costs[i - 1][j - 1] + ((a[i - 1] == b[j - 1]) ? 0 : 1) costs[i][j] = Math.min(1 + Math.min(costs[i - 1][j], costs[i][j - 1]), temp) } } // walk back through matrix to figure out path var aPathRev = "" var bPathRev = "" var i = a.count var j = b.count while (i != 0 && j != 0) { var temp = costs[i - 1][j - 1] + ((a[i - 1] == b[j - 1]) ? 0 : 1) var cij = costs[i][j] if (cij == temp) { i = i - 1 aPathRev = aPathRev + a[i] j = j - 1 bPathRev = bPathRev + b[j] } else if (cij == 1 + costs[i-1][j]) { i = i - 1 aPathRev = aPathRev + a[i] bPathRev = bPathRev + "-" } else if (cij == 1 + costs[i][j-1]) { aPathRev = aPathRev + "-" j = j - 1 bPathRev = bPathRev+ b[j] } } return [aPathRev[-1..0], bPathRev[-1..0]]
}
var result = levenshteinAlign.call("place", "palace") System.print(result[0]) System.print(result[1]) System.print() result = levenshteinAlign.call("rosettacode","raisethysword") System.print(result[0]) System.print(result[1])</lang>

~~Output:~~
~~p-lace palace r-oset-tacode raisethysword~~
~~zkl~~
Translation of: Java
~~<lang zkl>fcn alignment(a,b){~~
a,b = a.toLower(), b.toLower(); costs := (a.len()+1).pump(List(),'wrap(a){ [1..b.len()].pump(List(a)) }); foreach i,j in (a.len()+1, [1..b.len()]){ costs[i][j] = ( 1 + costs[i-1][j].min(costs[i][j-1]) ) .min(if(a[i-1] == b[j-1]) costs[i-1][j-1] else costs[i-1][j-1] + 1); } // walk back through matrix to figure out path aPathRev,bPathRev := Data(),Data(); // byte buckets i,j := a.len(), b.len(); while(i!=0 and j!= 0){ if (costs[i][j] == ( if(a[i-1]==b[j-1]) costs[i-1][j-1] else costs[i-1][j-1]+1 )){ aPathRev.append(a[i-=1]);
~~bPathRev.append(b[j-=1]);~~
~~} else if(costs[i][j] == 1+costs[i-1][j]){~~
~~aPathRev.append(a[i-=1]); bPathRev.append("-");~~
~~} else if (costs[i][j] == 1+costs[i][j-1]){~~
~~aPathRev.append("-"); bPathRev.append(b[j-=1]);~~
~~} } return(aPathRev.text.reverse(), bPathRev.text.reverse())~~
~~}</lang> <lang zkl>result := alignment("rosettacode", "raisethysword"); println(result[0]); println(result[1]);</lang>~~

~~Output:~~
~~r-oset-tacode raisethysword~~