## Calculating `String`

Similarity:

The common way of calculating the similarity between two strings in a 0%-100% fashion, as used in many libraries, is measuring how much (in %) you'd have to change the biggest string to turn it into the other:

```
public static double similarity(String s1, String s2) {
if (s1.length() < s2.length()) { // s1 should always be bigger
String swap = s1; s1 = s2; s2 = swap;
}
int bigLen = s1.length();
if (bigLen == 0) { return 1.0; /* both strings are zero length */ }
return (bigLen - computeEditDistance(s1, s2)) / (double) bigLen;
}
// full copy-paste working code is below
```

As you can see, the `similarity()`

method above uses a `computeEditDistance()`

method to calculate the **edit distance** step. There are several implementations to this step, each may suit a specific scenario better. The most common is the *Levenshtein distance algorithm* and we'll use it in our example below (for very large strings, other algorithms are likely to perform better).

### Calculating edit distance with *Levenshtein algorithm* in Java:

`LevenshteinDistance`

class is a **working example** of an implementation of the Levenshtein distance metric algorithm in Java (the `similarity`

method used above is included):

```
public class LevenshteinDistance {
public static double similarity(String s1, String s2) {
if (s1.length() < s2.length()) { // s1 should always be bigger
String swap = s1; s1 = s2; s2 = swap;
}
int bigLen = s1.length();
if (bigLen == 0) { return 1.0; /* both strings are zero length */ }
return (bigLen - computeEditDistance(s1, s2)) / (double) bigLen;
}
public static int computeEditDistance(String s1, String s2) {
s1 = s1.toLowerCase();
s2 = s2.toLowerCase();
int[] costs = new int[s2.length() + 1];
for (int i = 0; i <= s1.length(); i++) {
int lastValue = i;
for (int j = 0; j <= s2.length(); j++) {
if (i == 0)
costs[j] = j;
else {
if (j > 0) {
int newValue = costs[j - 1];
if (s1.charAt(i - 1) != s2.charAt(j - 1))
newValue = Math.min(Math.min(newValue, lastValue),
costs[j]) + 1;
costs[j - 1] = lastValue;
lastValue = newValue;
}
}
}
if (i > 0)
costs[s2.length()] = lastValue;
}
return costs[s2.length()];
}
public static void printDistance(String s1, String s2) {
System.out.println(s1 + "-->" + s2 + ": " +
computeEditDistance(s1, s2) + " ("+similarity(s1, s2)+")");
}
public static void main(String[] args) {
printDistance("", "");
printDistance("1234567890", "1");
printDistance("1234567890", "12");
printDistance("1234567890", "123");
printDistance("1234567890", "1234");
printDistance("1234567890", "12345");
printDistance("1234567890", "123456");
printDistance("1234567890", "1234567");
printDistance("1234567890", "12345678");
printDistance("1234567890", "123456789");
printDistance("1234567890", "1234567890");
printDistance("1234567890", "1234567980");
printDistance("47/2010", "472010");
printDistance("47/2010", "472011");
printDistance("47/2010", "AB.CDEF");
printDistance("47/2010", "4B.CDEFG");
printDistance("47/2010", "AB.CDEFG");
printDistance("The quick fox jumped", "The fox jumped");
printDistance("The quick fox jumped", "The fox");
printDistance("The quick fox jumped",
"The quick fox jumped off the balcany");
printDistance("kitten", "sitting");
printDistance("rosettacode", "raisethysword");
printDistance(new StringBuilder("rosettacode").reverse().toString(),
new StringBuilder("raisethysword").reverse().toString());
for (int i = 1; i < args.length; i += 2)
printDistance(args[i - 1], args[i]);
}
}
```

**Output:**

```
-->: 0 (1.0)
1234567890-->1: 9 (0.1)
1234567890-->12: 8 (0.2)
1234567890-->123: 7 (0.3)
1234567890-->1234: 6 (0.4)
1234567890-->12345: 5 (0.5)
1234567890-->123456: 4 (0.6)
1234567890-->1234567: 3 (0.7)
1234567890-->12345678: 2 (0.8)
1234567890-->123456789: 1 (0.9)
1234567890-->1234567890: 0 (1.0)
1234567890-->1234567980: 2 (0.8)
47/2010-->472010: 1 (0.8571428571428571)
47/2010-->472011: 2 (0.7142857142857143)
47/2010-->AB.CDEF: 7 (0.0)
47/2010-->4B.CDEFG: 7 (0.125)
47/2010-->AB.CDEFG: 8 (0.0)
The quick fox jumped-->The fox jumped: 6 (0.7)
The quick fox jumped-->The fox: 13 (0.35)
The quick fox jumped-->The quick fox jumped off the balcany: 16 (0.5555555555556)
kitten-->sitting: 3 (0.5714285714285714)
rosettacode-->raisethysword: 8 (0.38461538461538464)
edocattesor-->drowsyhtesiar: 8 (0.38461538461538464)
```

_{Levenshtein implementation source (along implementations in other languages): http://rosettacode.org/wiki/Levenshtein_distance#Java}