## 1) Few words about Levenshtein distance algorithm improvement

**Recursive implementation of Levenshteins distance has exponential complexity**.

I'd suggest you to use **memoization technique** and implement Levenshtein distance without recursion, and reduce complexity to `O(N^2)`

(needs `O(N^2)`

memory)

```
public static int levenshteinDistance( String s1, String s2 ) {
return dist( s1.toCharArray(), s2.toCharArray() );
}
public static int dist( char[] s1, char[] s2 ) {
// distance matrix - to memoize distances between substrings
// needed to avoid recursion
int[][] d = new int[ s1.length + 1 ][ s2.length + 1 ];
// d[i][j] - would contain distance between such substrings:
// s1.subString(0, i) and s2.subString(0, j)
for( int i = 0; i < s1.length + 1; i++ ) {
d[ i ][ 0 ] = i;
}
for(int j = 0; j < s2.length + 1; j++) {
d[ 0 ][ j ] = j;
}
for( int i = 1; i < s1.length + 1; i++ ) {
for( int j = 1; j < s2.length + 1; j++ ) {
int d1 = d[ i - 1 ][ j ] + 1;
int d2 = d[ i ][ j - 1 ] + 1;
int d3 = d[ i - 1 ][ j - 1 ];
if ( s1[ i - 1 ] != s2[ j - 1 ] ) {
d3 += 1;
}
d[ i ][ j ] = Math.min( Math.min( d1, d2 ), d3 );
}
}
return d[ s1.length ][ s2.length ];
}
```

Or, even better - you may notice, that for each cell in distance matrix - you're need only information about previous line, so **you can reduce memory needs to **`O(N)`

:

```
public static int dist( char[] s1, char[] s2 ) {
// memoize only previous line of distance matrix
int[] prev = new int[ s2.length + 1 ];
for( int j = 0; j < s2.length + 1; j++ ) {
prev[ j ] = j;
}
for( int i = 1; i < s1.length + 1; i++ ) {
// calculate current line of distance matrix
int[] curr = new int[ s2.length + 1 ];
curr[0] = i;
for( int j = 1; j < s2.length + 1; j++ ) {
int d1 = prev[ j ] + 1;
int d2 = curr[ j - 1 ] + 1;
int d3 = prev[ j - 1 ];
if ( s1[ i - 1 ] != s2[ j - 1 ] ) {
d3 += 1;
}
curr[ j ] = Math.min( Math.min( d1, d2 ), d3 );
}
// define current line of distance matrix as previous
prev = curr;
}
return prev[ s2.length ];
}
```

## 2) Few words about autocomplete

Levenshtein's distance is perferred only if you need to find exact matches.

But what if your keyword would be `apple`

and user typed `green apples`

? Levenshteins distance between query and keyword would be large (**7 points**). And Levensteins distance between `apple`

and `bcdfghk`

(dumb string) would be **7 points** too!

I'd suggest you to use **full-text search engine** (e.g. Lucene). The trick is - that you have to use **n-gram** model to represent each keyword.

In few words:

**1)** you have to represent each keyword as document, which contains n-grams: `apple -> [ap, pp, pl, le]`

.

**2)** after transforming each keyword to set of n-grams - you have to **index each keyword-document** by n-gram in your search engine. You'll have to create index like this:

```
...
ap -> apple, map, happy ...
pp -> apple ...
pl -> apple, place ...
...
```

**3)** So you have n-gram index. **When you're get query - you have to split it into n-grams**. Aftre this - you'll have set of users query n-grams. And all you need - is to match most similar documents from your search engine. In draft approach it would be enough.

**4)** For better suggest - you may rank results of search-engine by Levenshtein distance.

**P.S.** I'd suggest you to look through the book **"Introduction to information retrieval"**.