## Algorithm

The function `ff()`

below uses recursion (i.e. backtracking) to solve your problem. The basic idea is that at the start of any call to `f()`

, we are trying to match a suffix `t`

of the original "needle" string to a suffix `s`

of the "haystack" string, while allowing only a certain number of each type of edit operation.

```
// ss is the start of the haystack, used only for reporting the match endpoints.
void f(char* ss, char* s, char* t, int mm, int ins, int del) {
while (*s && *s == *t) ++s, ++t; // OK to always match longest segment
if (!*t) printf("%d\n", s - ss); // Matched; print endpoint of match
if (mm && *s && *t) f(ss, s + 1, t + 1, mm - 1, ins, del);
if (ins && *s) f(ss, s + 1, t, mm, ins - 1, del);
if (del && *t) f(ss, s, t + 1, mm, ins, del - 1);
}
// Find all occurrences of t starting at any position in s, with at most
// mm mismatches, ins insertions and del deletions.
void ff(char* s, char* t, int mm, int ins, int del) {
for (char* ss = s; *s; ++s) {
// printf("Starting from offset %d...\n", s - ss);
f(ss, s, t, mm, ins, del);
}
}
```

Example call:

```
ff("xxabcydef", "abcdefg", 1, 1, 1);
```

This outputs:

```
9
9
```

because there are two ways to find "abcdefg" in "xxabcydef" with at most 1 of each kind of change, and both of these ways end at position 9:

```
Haystack: xxabcydef-
Needle: abc-defg
```

which has 1 insertion (of `y`

) and 1 deletion (of `g`

), and

```
Haystack: xxabcyde-f
Needle: abc-defg
```

which has 1 insertion (of `y`

), 1 deletion (of `f`

), and 1 substitution of `g`

to `f`

.

## Dominance Relation

It may not be obvious why it's actually safe to use the `while`

loop on line 3 to greedily match as many characters as possible at the start of the two strings. In fact this may reduce the number of *times* that a particular end position will be reported as a match, but it will never cause an end position to be forgotten completely -- and since we're usually interested in just whether or not there is a match ending at a given position of the haystack, and without this `while`

loop the algorithm would *always* take time exponential in the needle size, this seems a win-win.

It is guaranteed to work because of a *dominance relation*. To see this, suppose the opposite -- that it is in fact unsafe (i.e. misses some matches). Then there would be some match in which an initial segment of equal characters from both strings are not aligned to each other, for example:

```
Haystack: abbbbc
Needle: a-b-bc
```

However, any such match can be transformed into another match having the same number of operations of each type, and ending at the same position, by shunting the leftmost character following a gap to the left of the gap:

```
Haystack: abbbbc
Needle: ab--bc
```

If you do this repeatedly until it's no longer possible to shunt characters without requiring a substitution, you will get a match in which the largest initial segment of equal characters from both strings are aligned to each other:

```
Haystack: abbbbc
Needle: abb--c
```

My algorithm will find all such matches, so it follows that no match position will be overlooked by it.

## Exponential Time

Like any backtracking program, this function will exhibit exponential slowdowns on certain inputs. Of course, it may be that on the inputs you happen to use, this doesn't occur, and it works out faster than particular implementations of DP algorithms.