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I know there are similar answer to this on stack, as well as online, but I feel I'm missing something. Given the code below, we need to reconstruct the sequence of events that led to the resulting minimum edit distance. For the code below, we need to write a function that outputs:

Equal, L, L
Delete, E
Equal, A, A
Substitute, D, S
Insert, T

EDIT: CODE IS UPDATED WITH MY (PARTIALLY CORRECT) SOLUTION

Here is the code, with my partial solution. It works for example I was given ("lead" -> "last"), but doesn't work for the example below ("hint" -> "isnt"). I suspect this is because the first character is equal, which is throwing off my code. Any tips or pointers in the right direction would be great!

def printMatrix(M):
        for row in M:
                print row
        print

def med(s, t):  
        k = len(s) + 1
        l = len(t) + 1

        M = [[0 for i in range(k)] for j in range(l)]
        MTrace = [["" for i in range(k)] for j in range(l)]

        M[0][0] = 0


        for i in xrange(0, k):
                M[i][0] = i
                MTrace[i][0] = s[i-1]

        for j in xrange(0, l):
                M[0][j] = j
                MTrace[0][j] = t[j-1]

        MTrace[0][0] = "DONE"

        for i in xrange(1, k):
                for j in xrange(1, l):

                        sub = 1
                        sub_op = "sub"
                        if s[i-1] == t[j-1]:
                                # equality
                                sub = 0
                                sub_op = "eq"


                        # deletion
                        min_value = M[i-1][j] + 1
                        op = "del"
                        if min_value > M[i][j-1] + 1:
                                # insertion
                                min_value = M[i][j-1] + 1
                                op = "ins"
                        if min_value > M[i-1][j-1] + sub:
                                # substitution
                                min_value = M[i-1][j-1] + sub
                                op = sub_op


                        M[i][j] = min_value
                        MTrace[i][j] = op                        

        print "final Matrix"
        printMatrix(M)
        printMatrix(MTrace)

############ MY PARTIAL SOLUTION

        def array_append(array,x,y):
            ops_string = MTrace[x][y]
            if ops_string == 'ins':
                array.append(("Insert",MTrace[0][y]))
            elif ops_string == 'sub':
                array.append(("Substitute",MTrace[x][0],MTrace[0][y]))
            elif ops_string == 'eq':
                array.append(("Equal",MTrace[x][0],MTrace[0][y]))
            elif ops_string == 'del':
                array.append(("Delete",MTrace[x][0]))


        i = len(s)
        j = len(t)

        ops_array = []
        base = M[i][j]
        array_append(ops_array,i,j)


        while MTrace[i][j] != "DONE":
            base = M[i][j]
            local_min = min(M[i][j-1],M[i-1][j],M[i-1][j-1])
            if base == local_min:
                i = i - 1
                j = j - 1
                array_append(ops_array,i,j)
            elif M[i][j-1] < M[i-1][j]:
                j = j -1
                array_append(ops_array,i,j)
            elif M[i-1][j] < M[i][j-1]:
                i = i - 1
                array_append(ops_array,i,j)
            else:
                i = i - 1
                j = j - 1
                array_append(ops_array,i,j)

        print ops_array
#########

        return M[k-1][l-1]      

print med('lead', 'last')
share|improve this question

3 Answers 3

up vote 12 down vote accepted

It's my opinion that understanding the algorithm more deeply is important in this case. Rather than giving you some pseudocode, I'll walk you through the essential steps of the algorithm, and show you how the data you want is "encoded" in the final matrix that results. Of course, if you don't need to roll your own algorithm, then you should obviously just use someone else's, as MattH suggests!

This looks to me like an implementation of the Wagner-Fischer algorithm. The basic idea is to calculate the distances between "nearby" prefixes, take the minimum, and then calculate the distance for the current pair of strings from that. So for example, say you have two strings 'h' and 'i' (with an underscore denoting the empty string):

  _ h
_ 0 1
i 1 1

The distance from the empty string to any string of length L is L. That covers the values in the first row and column, which simply increment. From there, you can calculate the value of any location by taking the minimum from among the upper, left, and upper-left values, and adding one, or, if the letter is the same at that point in the string, taking the upper-left value unchanged. For the value at (1, 1) in the table above, the minimum is 0 at (0, 0), so the value at (1, 1) is 1, and that's the minimum edit distance from 'i' to 'h'. So in general, the minimum edit distance is always in the lower right corner of the matrix. Now let's do another.

  _ h i
_ 0 1 2
i 1 1 1
s 2 2 2

Now things go a little differently. At (1, 2) (in (row, column) i.e. row-major notation), we find that the corresponding letter in both strings is the same -- i. So we don't have to add anything; we just take the value in the upper-left cell (0, 1) -- which is 1 -- unaltered. The intuition here is that we don't have to do anything, because the letter being added to both strings is the same; the lengths of both strings increase by one, so we move diagonally. Continuing...

  _ h i n t
_ 0 1 2 3 4
i 1 1 1 2 3
s 2 2 2 2 3
n 3 3 3 2 3
t 4 4 4 3 2

Now we have a slightly more complex matrix. The final minimum edit distance here is 2, because the last two letters of these two strings are the same. Convenient!

But how do we extract the types of edits from this table? The key is to realize that movement on the table corresponds to particular types of edits. So for example, a rightward movement from (0, 0) to (0, 1) takes us from _ -> _, requiring no edits, to _ -> h, requiring one edit, an insertion. Likewise, a downward movement from (0, 0) to (1, 0) takes us from _ -> _, requiring no edits, to i -> _, requiring one edit, a deletion. And finally, a diagonal movement from (0, 0) to (1, 1) takes us from _ -> _, requiring no edits, to h -> i, requiring one edit, a substitution.

So now all we have to do is reverse our steps, tracing local minima from among the upper, left, and upper-left cells back to the origin, (0, 0), keeping in mind that if the current value is the same as the minimum, then we must go to the upper-left cell, since that's the only kind of movement that doesn't increment the edit distance.

There are two possible paths in this case:

(4, 4) -> (3, 3) -> (2, 2) -> (1, 2) -> (0, 1) -> (0, 0)

and

(4, 4) -> (3, 3) -> (2, 2) -> (1, 1) -> (0, 0)

Reversing them, we get

(0, 0) -> (0, 1) -> (1, 2) -> (2, 2) -> (3, 3) -> (4, 4)

and

(0, 0) -> (1, 1) -> (2, 2) -> (3, 3) -> (4, 4)

So for the first version, our first operation is a movement to the right, i.e. an insertion. The letter inserted is h, since we're moving from isnt to hint. (This corresponds to Insert, h in your verbose output.) Our next operation is a diagonal movement, i.e. either a substitution, or a no-op. In this case, it's a no-op because the edit distance is the same at both locations (i.e. the letter is the same). So Equal, i, i. Then a downward movement, corresponding to a deletion. The letter deleted is s, since again, we're moving from isnt to hint. (In general, the letter to insert comes from the output string, while the letter to delete comes from the input string.) So that's Delete, s. Then two diagonal movements with no change in value: Equal, n, n and Equal, t, t.

The result:

Insert, h
Equal, i, i
Delete, s
Equal, n, n
Equal, t, t

Performing these instructions on isnt:

isnt
hisnt
hisnt
hint
hint
hint

For a total edit distance of 2.

I'll leave the second minimum path as an exercise.

Once you grok all this, it shouldn't be hard to code at all. The key, in cases like this, is to deeply understand the algorithm first. Once you've done that, coding it up is a cinch.

As a final note, you might chose to accumulate the edits as you populate the matrix. In that case, each cell in your matrix could be a tuple: (2, ('ins', 'eq', 'del', 'eq', 'eq')). So here you would increment the length, and append the operation corresponding to a movement from the minimal previous state. That does away with the backtracking, and so decreases the complexity of the code; but it takes up extra memory. If you do this, the final edit sequence will appear along with the final edit distance in the lower right corner of the matrix.

share|improve this answer
1  
1UP - Nice write up –  MattH May 17 '12 at 18:30
    
Thank you so much for the verbose explanation. This is exactly what I was looking for. –  Adam_G May 18 '12 at 4:01
    
@senderle, again, thank you! This is extremely helpful. For the 2nd path, I got: sub, i, h sub, s, i eq, n, n eq, n, n Since this also had an edit distance of 2, how do I decide which one to use? (Sorry, it looks like none of my line-breaks are working) –  Adam_G May 18 '12 at 15:23
    
In my original code, I end up with a matrix like this: [0, 1, 2, 3, 4] [1, 0, 1, 2, 3] [2, 1, 1, 2, 3] [3, 2, 1, 2, 3] [4, 3, 2, 2, 3] I noted the example my professor supplied in my original comment: Equal, L, L Delete, E Equal, A, A Substitute, D, S Insert, T But couldn't I also just go diagonally down the middle, with: Equal, L, L Sub, E, A Sub, A, S Sub, D, T Is either answer "more correct" than the other? –  Adam_G May 18 '12 at 15:25
    
I don't think so. As I should have mentioned, the path your code will take depends on things like what order you pass your arguments to min. But the edit distance is the same, and the input and output strings are the same, so I don't see how your professor can fault you for getting a different result. Indeed, this example has (by my count, which could be mistaken) no fewer than five different correct edit sequences. However, perhaps your professor wants to see you go through all of this, and figure out how to code it so that the result is exactly like the example he gave you. –  senderle May 18 '12 at 15:58

I suggest you have a look at the python-Levenshtein module. Will probably get you a long way there:

>>> import Levenshtein
>>> Levenshtein.editops('LEAD','LAST')
[('replace', 1, 1), ('replace', 2, 2), ('replace', 3, 3)]

You can process the output from edit ops to create your verbose instructions.

share|improve this answer

I don't know python, but the following C# code works if that's any help.

public class EditDistanceCalculator
{
    public double SubstitutionCost { get; private set; }
    public double DeletionCost { get; private set; }
    public double InsertionCost { get; private set; }

    public EditDistanceCalculator() : this(1,1, 1)
    {
    }

    public EditDistanceCalculator(double substitutionCost, double insertionCost, double deletionCost)
    {
        InsertionCost = insertionCost;
        DeletionCost = deletionCost;
        SubstitutionCost = substitutionCost;
    }

    public Move[] CalcEditDistance(string s, string t)
    {
        if (s == null) throw new ArgumentNullException("s");
        if (t == null) throw new ArgumentNullException("t");

        var distances = new Cell[s.Length + 1, t.Length + 1];
        for (int i = 0; i <= s.Length; i++)
            distances[i, 0] = new Cell(i, Move.Delete);
        for (int j = 0; j <= t.Length; j++)
            distances[0, j] = new Cell(j, Move.Insert);

        for (int i = 1; i <= s.Length; i++)
            for (int j = 1; j <= t.Length; j++)
                distances[i, j] = CalcEditDistance(distances, s, t, i, j);

        return GetEdit(distances, s.Length, t.Length);
    }

    private Cell CalcEditDistance(Cell[,] distances, string s, string t, int i, int j)
    {
        var cell = s[i - 1] == t[j - 1]
                            ? new Cell(distances[i - 1, j - 1].Cost, Move.Match)
                            : new Cell(SubstitutionCost + distances[i - 1, j - 1].Cost, Move.Substitute);
        double deletionCost = DeletionCost + distances[i - 1, j].Cost;
        if (deletionCost < cell.Cost)
            cell = new Cell(deletionCost, Move.Delete);

        double insertionCost = InsertionCost + distances[i, j - 1].Cost;
        if (insertionCost < cell.Cost)
            cell = new Cell(insertionCost, Move.Insert);

        return cell;
    }

    private static Move[] GetEdit(Cell[,] distances, int i, int j)
    {
        var moves = new Stack<Move>();
        while (i > 0 && j > 0)
        {
            var move = distances[i, j].Move;
            moves.Push(move);
            switch (move)
            {
                case Move.Match:
                case Move.Substitute:
                    i--;
                    j--;
                    break;
                case Move.Insert:
                    j--;
                    break;
                case Move.Delete:
                    i--;
                    break;
                default:
                    throw new ArgumentOutOfRangeException();
            }
        }
        for (int k = 0; k < i; k++)
            moves.Push(Move.Delete);
        for (int k = 0; k < j; k++)
            moves.Push(Move.Insert);

        return moves.ToArray();
    }

    class Cell
    {
        public double Cost { get; private set; }
        public Move Move { get; private set; }

        public Cell(double cost, Move move)
        {
            Cost = cost;
            Move = move;
        }
    }
}

public enum Move
{
    Match,
    Substitute,
    Insert,
    Delete
}

Some tests:

    [TestMethod]
    public void TestEditDistance()
    {
        var expected = new[]
            {
                Move.Delete, 
                Move.Substitute, 
                Move.Match, 
                Move.Match, 
                Move.Match, 
                Move.Match, 
                Move.Match, 
                Move.Insert,
                Move.Substitute, 
                Move.Match, 
                Move.Substitute, 
                Move.Match, 
                Move.Match, 
                Move.Match, 
                Move.Match
            };
        Assert.IsTrue(expected.SequenceEqual(new EditDistanceCalculator().CalcEditDistance("thou-shalt-not", "you-should-not")));

        var calc = new EditDistanceCalculator(3, 1, 1);
        var edit = calc.CalcEditDistance("democrat", "republican");
        Console.WriteLine(string.Join(",", edit));
        Assert.AreEqual(3, edit.Count(m => m == Move.Match)); //eca
    }
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