# Edit distance recursive algorithm — Skiena

I'm reading The Algorithm Design Manual by Steven Skiena, and I'm on the dynamic programming chapter. He has some example code for edit distance and uses some functions which are explained neither in the book nor on the internet. So I'm wondering

a) how does this algorithm work?

b) what do the functions indel and match do?

``````#define MATCH     0       /* enumerated type symbol for match */
#define INSERT    1       /* enumerated type symbol for insert */
#define DELETE    2       /* enumerated type symbol for delete */

int string_compare(char *s, char *t, int i, int j)
{
int k;                  /* counter */
int opt[3];             /* cost of the three options */
int lowest_cost;        /* lowest cost */

if (i == 0) return(j * indel(' '));
if (j == 0) return(i * indel(' '));

opt[MATCH] = string_compare(s,t,i-1,j-1) + match(s[i],t[j]);
opt[INSERT] = string_compare(s,t,i,j-1) + indel(t[j]);
opt[DELETE] = string_compare(s,t,i-1,j) + indel(s[i]);

lowest_cost = opt[MATCH];
for (k=INSERT; k<=DELETE; k++)
if (opt[k] < lowest_cost) lowest_cost = opt[k];

return( lowest_cost );
}
``````
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They're explained in the book. Please read section 8.2.4 Varieties of Edit Distance

-

On page 287 in the book:

``````int match(char c, char d)
{
if (c == d) return(0);
else return(1);
}

int indel(char c)
{
return(1);
}
``````
-

Basically, it utilizes the dynamic programming method of solving problems where the solution to the problem is constructed to solutions to subproblems, to avoid recomputation, either bottom-up or top-down.

The recursive structure of the problem is as given here, where `i,j` are start (or end) indices in the two strings respectively.

Problem: Given two strings of size m, n and set of operations replace (R), insert (I) and delete (D) all at equal cost. Find minimum number of edits (operations) required to convert one string into another.

Identifying Recursive Methods:

What will be sub-problem in this case? Consider finding edit distance of part of the strings, say small prefix. Let us denote them as [1...i] and [1...j] for some 1< i < m and 1 < j < n. Clearly it is solving smaller instance of final problem, denote it as E(i, j). Our goal is finding E(m, n) and minimizing the cost.

In the prefix, we can right align the strings in three ways (i, -), (-, j) and (i, j). The hyphen symbol (-) representing no character. An example can make it more clear.

Given strings SUNDAY and SATURDAY. We want to convert SUNDAY into SATURDAY with minimum edits. Let us pick i = 2 and j = 4 i.e. prefix strings are SUN and SATU respectively (assume the strings indices start at 1). The right most characters can be aligned in three different ways.

Case 1: Align characters U and U. They are equal, no edit is required. We still left with the problem of i = 1 and j = 3, E(i-1, j-1).

Case 2: Align right character from first string and no character from second string. We need a deletion (D) here. We still left with problem of i = 1 and j = 4, E(i-1, j).

Case 3: Align right character from second string and no character from first string. We need an insertion (I) here. We still left with problem of i = 2 and j = 3, E(i, j-1).

Combining all the subproblems minimum cost of aligning prefix strings ending at i and j given by

E(i, j) = min( [E(i-1, j) + D], [E(i, j-1) + I], [E(i-1, j-1) + R if i,j characters are not same] )

We still not yet done. What will be base case(s)?

When both of the strings are of size 0, the cost is 0. When only one of the string is zero, we need edit operations as that of non-zero length string. Mathematically,

E(0, 0) = 0, E(i, 0) = i, E(0, j) = j

I recommend going through this lecture for a good explanation.

The function `match()` returns 1, if the two characters mismatch (so that one more move is added in the final answer) otherwise 0.

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the code implementing the above algorithm is :

``````int dpEdit(char *s1, char *s2 ,int len1,int len2)
{
if(len1==0)  /// Base Case
return len2;
else if(len2==0)
return len1;
else
{
int table[len1+1][len2+2];
for(int i=0;i<=len2;i++)
table[0][i]=i;
for(int i=0;i<=len1;i++)
table[i][0]=i;
for(int i=1;i<=len1;i++)
{
for(int j=1;j<=len2;j++)
{