I'm trying to understand the Wagner–Fischer algorithm for finding distance between to strings. I'm looking through a pseudocode of it in the following link: http://en.wikipedia.org/wiki/Wagner%E2%80%93Fischer_algorithm

int EditDistance(char s[1..m], char t[1..n])
   // For all i and j, d[i,j] will hold the Levenshtein distance between
   // the first i characters of s and the first j characters of t.
   // Note that d has (m+1)  x(n+1) values.
   let d be a 2-d array of int with dimensions [0..m, 0..n]

   for i in [0..m]
     d[i, 0] ← i // the distance of any first string to an empty second string
   for j in [0..n]
     d[0, j] ← j // the distance of any second string to an empty first string

   for j in [1..n]
     for i in [1..m]
       if s[i] = t[j] then  
         d[i, j] ← d[i-1, j-1]       // no operation required
         d[i, j] ← minimum of
                      d[i-1, j] + 1,  // a deletion
                      d[i, j-1] + 1,  // an insertion
                      d[i-1, j-1] + 1 // a substitution

   return d[m,n]

Actually I get the algorithm's point and understand it intuitively, by it's not obvious for me why are d[i-1, j] + 1, d[i, j-1] + 1 and d[i-1, j-1] + 1 considered as a deletion, insertion and substitution. It'd be great if someone explained the implementation nuances in a more detailed way.


I have created a gist which prints out the sequence of operations as well as the goal which each step is trying to solve, which should complement my explanation of the Fischer-Wagner algorithm.

To be able to understand the Fischer-Wagner algorithm you have to keep in mind that it is belongs to the family of dynamic programming algorithms. This means that it will compute partial solutions to a bigger problem, store the partial solution and use the result of the partial computation for the next computation.

So what does this mean for the Fisher-Wagner algorithm? In this context this means that each element of the distance matrix d contains the best possible trace of operations to get you from your current string A to another string B. This explanation is still a little bit abstract, so let me explain what I mean by that by walking you through an example.

Lets assume you want to calculate the Levensthein distance of the two strings "ABV" and "FV" using the Fischer-Wagner algorithm. Then your distance matrix will look like this:

|     |j->| 0 | 1 | 2 |
|   i |   | # | F | V |
|   0 | # |   |   |   |
|   1 | A |   |   |   |
|   2 | B |   |   |   |
|   3 | C |   |   |   |

The first row/column of this table name the indices of the distance matrix, the second name the characters of the strings. '#' is the empty string (i.e. a string with zero length).

Each element of this distance matrix marks a subproblems that you want to solve. For example, the entry [i=0, j=2] contains the shortest distance from arriving from an empty string "" to "FV" the entry [i=2, j=1] contains the shortest distance for the problem "AB" => "F".

Let's fast forward the algorithm to the subproblem [i=2, j=2], i.e. how to get from "AB" to "FV". In this case, the distance matrix looks like this.

|     |j->| 0 | 1 | 2 |
|   i |   | # | F | V |
|   0 | # | 0 | 1 | 2 |
|   1 | A | 1 | 1 | 2 |
|   2 | B | 2 | 2 |   |
|   3 | C | 3 | 3 |   |

"B" and "V" are not equal, which means we need to perform one of the following three operations to make them equal:

  1. delete "B". We take the cost of the cell above d[i=1, j=2], because we know that this cell is the cheapest sequence of operations that gets us from "A" => "FV". However, our problem is getting from "AB" => "FV", not from "A" => "FV. We do know that we can replace "A" by "FV" by applying the operations of cell d[i=1, j=2] (we solved this subproblem earlier), which leaves us with a string "FVB" for the cost of 2. We then deleted the "B" ("FVB" => "FV") and we are done. The cost of this operation is 2+1.
  2. insert "V". Similar as delete "B", only we take the value to the left d[i=2, j=1] because we know it is the cheapest sequence of operations to get from "AB"=>"F". Since our problem is to get from "AB"=>"FV", we only need to add the cost of inserting "V" and we are done.
  3. substitute "B" with "V". Similar to the previous cases. We know that d[i=1, j=1] contains the cheapest sequence of operations to change "A"=>"F". Applying this operation changes our problem changes to "FB"=>"FV", which can be solve by substituting "B" with "F".

After considering these 3 options, we pick the cheapest one, which is substituting "B" by "F" (1+1).

After solving all subproblems in that fashion, the output will produce the final result, which is the minimal edit distance from "ABC => "FV".

  • Very good answer! I wonder is the asterisk marks in we can replace "A*"* by "FV" by just typos? They are quite confusing. Sep 28 '18 at 9:43
  • @BjörnLindqvist it was indeed a typo and I corrected it, thanks for pointing it out.
    – Stefan
    Oct 1 '18 at 7:52

Note the string which is imagined to be kept at columns is constant and we need to find the edit distance of the string kept at rows . See this for example enter image description here

Here we are trying to compute Edit distance of AVERY ! So now, the substructure DP[i][j]=DP[i-1][j-1] (if G[j]==A[i])

NOTE: G stands for GARVEY and A for AVERY

because If we can solve Edit Distance of G[j-1] and A[i-1] in k operations we can solve G[j] and A[i] operations ( No operation needed for last character)

Other wise

DP[i][j]= minimum of following

DP[i-1][j]+1 (See we can only delete from the Row String (whose EDIT distance is to be calculated !) DP[i-1][j] represents the string G[1...j] and A[1...i-1]! See the character A[i] deleted??)

DP[i][j-1]+1 (See this is not a deletion!! What we do is add a character at i+1 th posiition ! And hence it is equal to G[j] (We can add any character))

DP[i-1][j-1]+1 (I guess this is easy now the i th and j th character weren't same so what we did was change the A[i] th character into G[j]th)

Feel free to ask doubts :)

  • Hey I guess I got the first point (deletion) A[1...i-1] claims that A[i] has been deleted. But the insertion and substitution remain non intuitive. Say "What we do is add a character at i+1 th posiition" is not obvious.
    – mdavid
    Jun 12 '15 at 10:05
  • Let the string be A[1...i] where A[i] does not equal to B[j] (Here A is the string whose Edit Distance is to be calculated !) As A[i]!= B[j] what we do is insert a character just after i th position which is equal to B[j], So, the edit distance will be 1 plus Edit distance of A[1....i] & B[1...j-1] (j-1 because we have fixed it by adding another character) Substitution is as simple as that A[1....i] and B[1....j] , here A[i]!= B[j] what we can do is we can substitute A[i] such that it is equal to B[j]... and then our edit distance will be 1+edit distance of A[1....i-1] & B[1...j-1] Jun 12 '15 at 10:10
  • But if A[i]!= B[j] why we insert a character just after i th position which is equal to B[j]
    – mdavid
    Jun 12 '15 at 10:56
  • We are looking at the edit distance of A[1...i] and B[1...j] . Now inserting some other letter will cause nothing good ! Why? Just because we will have to delete it or add another letter which is not optimal for minimum edit dostance... Now dynamic programming is a careful brute force so we try all the possibilities deletion, insertion and replacement. Thats why we try each deletion,insertion and replacement! Jun 12 '15 at 12:53

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.