# How to calculate distance similarity measure of given 2 strings?

I need to calculate the similarity between 2 strings. So what exactly do I mean? Let me explain with an example:

• The real word: `hospital`
• Mistaken word: `haspita`

Now my aim is to determine how many characters I need to modify the mistaken word to obtain the real word. In this example, I need to modify 2 letters. So what would be the percent? I take the length of the real word always. So it becomes 2 / 8 = 25% so these 2 given string DSM is 75%.

How can I achieve this with performance being a key consideration?

• It won't get faster than looping through the strings characters and checking them one by one. There's no real optimization opportunity since every character needs to be checked in at least the shortest of the two strings. Feb 26, 2012 at 14:09
• Thanks Dervall. This is what comes to programmer mind at first but i saw many examples of optimization :D So better to ask and be sure with Experts answers. Feb 26, 2012 at 14:13
• @Dervall How does looping through the characters suffice? Even O(n^2) algorithms for this problem aren't trivial. Feb 26, 2012 at 14:14

I just addressed this exact same issue a few weeks ago. Since someone is asking now, I'll share the code. In my exhaustive tests my code is about 10x faster than the C# example on Wikipedia even when no maximum distance is supplied. When a maximum distance is supplied, this performance gain increases to 30x - 100x +. Note a couple key points for performance:

• If you need to compare the same words over and over, first convert the words to arrays of integers. The Damerau-Levenshtein algorithm includes many >, <, == comparisons, and `ints` compare much faster than `chars`.
• It includes a short-circuiting mechanism to quit if the distance exceeds a provided maximum
• Use a rotating set of three arrays rather than a massive matrix as in all the implementations I've see elsewhere
• Make sure your arrays slice accross the shorter word width.

Code (it works the exact same if you replace `int[]` with `String` in the parameter declarations:

``````/// <summary>
/// Computes the Damerau-Levenshtein Distance between two strings, represented as arrays of
/// integers, where each integer represents the code point of a character in the source string.
/// Includes an optional threshhold which can be used to indicate the maximum allowable distance.
/// </summary>
/// <param name="source">An array of the code points of the first string</param>
/// <param name="target">An array of the code points of the second string</param>
/// <param name="threshold">Maximum allowable distance</param>
/// <returns>Int.MaxValue if threshhold exceeded; otherwise the Damerau-Leveshteim distance between the strings</returns>
public static int DamerauLevenshteinDistance(int[] source, int[] target, int threshold) {

int length1 = source.Length;
int length2 = target.Length;

// Return trivial case - difference in string lengths exceeds threshhold
if (Math.Abs(length1 - length2) > threshold) { return int.MaxValue; }

// Ensure arrays [i] / length1 use shorter length
if (length1 > length2) {
Swap(ref target, ref source);
Swap(ref length1, ref length2);
}

int maxi = length1;
int maxj = length2;

int[] dCurrent = new int[maxi + 1];
int[] dMinus1 = new int[maxi + 1];
int[] dMinus2 = new int[maxi + 1];
int[] dSwap;

for (int i = 0; i <= maxi; i++) { dCurrent[i] = i; }

int jm1 = 0, im1 = 0, im2 = -1;

for (int j = 1; j <= maxj; j++) {

// Rotate
dSwap = dMinus2;
dMinus2 = dMinus1;
dMinus1 = dCurrent;
dCurrent = dSwap;

// Initialize
int minDistance = int.MaxValue;
dCurrent = j;
im1 = 0;
im2 = -1;

for (int i = 1; i <= maxi; i++) {

int cost = source[im1] == target[jm1] ? 0 : 1;

int del = dCurrent[im1] + 1;
int ins = dMinus1[i] + 1;
int sub = dMinus1[im1] + cost;

//Fastest execution for min value of 3 integers
int min = (del > ins) ? (ins > sub ? sub : ins) : (del > sub ? sub : del);

if (i > 1 && j > 1 && source[im2] == target[jm1] && source[im1] == target[j - 2])
min = Math.Min(min, dMinus2[im2] + cost);

dCurrent[i] = min;
if (min < minDistance) { minDistance = min; }
im1++;
im2++;
}
jm1++;
if (minDistance > threshold) { return int.MaxValue; }
}

int result = dCurrent[maxi];
return (result > threshold) ? int.MaxValue : result;
}
``````

Where `Swap` is:

``````static void Swap<T>(ref T arg1,ref T arg2) {
T temp = arg1;
arg1 = arg2;
arg2 = temp;
}
``````
• I've compared a few implementation and yours seems to be from far the best performer, and results seems to be accurate. Thank you very much ! Dec 26, 2014 at 18:37
• I ported this to Java (here: gist.github.com/cordje/bd13c781337d8ffc30bf ) so that I could compare its performance with the various existing implementations. This is ~40% slower than the implementation at github.com/tdebatty/java-string-similarity/blob/master/src/main/… So, adding the initial threshold length check to that algorithm would be my choice. Jan 28, 2016 at 13:48
• Why do you think integers compare faster than chars? They are basically the same thing. When calculating the speed of your algorithm do you take into account the string -> int[] conversion? To Richard EB - in java a lot of memory allocations and operations are different so you can't conduct such comparisons. Jun 6, 2016 at 11:30
• Can confirm. Converting the string to `int[]` is a nightmare. i.imgur.com/mkW0aWw.png Dec 16, 2016 at 22:49
• If you are looking for a fast Levenshtein implementation, there is a nuget package called Fastenshtein that is very fast. Mar 19, 2018 at 9:42

What you are looking for is called edit distance or Levenshtein distance. The wikipedia article explains how it is calculated, and has a nice piece of pseudocode at the bottom to help you code this algorithm in C# very easily.

Here's an implementation from the first site linked below:

``````private static int  CalcLevenshteinDistance(string a, string b)
{
if (String.IsNullOrEmpty(a) && String.IsNullOrEmpty(b)) {
return 0;
}
if (String.IsNullOrEmpty(a)) {
return b.Length;
}
if (String.IsNullOrEmpty(b)) {
return a.Length;
}
int  lengthA   = a.Length;
int  lengthB   = b.Length;
var  distances = new int[lengthA + 1, lengthB + 1];
for (int i = 0;  i <= lengthA;  distances[i, 0] = i++);
for (int j = 0;  j <= lengthB;  distances[0, j] = j++);

for (int i = 1;  i <= lengthA;  i++)
for (int j = 1;  j <= lengthB;  j++)
{
int  cost = b[j - 1] == a[i - 1] ? 0 : 1;
distances[i, j] = Math.Min
(
Math.Min(distances[i - 1, j] + 1, distances[i, j - 1] + 1),
distances[i - 1, j - 1] + cost
);
}
return distances[lengthA, lengthB];
}
``````
• @MonsterMMORPG here is a rather straightforward implementation in C#. It uses `(M*N)` space, while a better implementation could use `2*MAX(M,N)` space. Feb 26, 2012 at 14:13
• Maybe you could adapt the algo at biorecipes.com/DynProgBasic/code.html Feb 26, 2012 at 14:14
• @dasblinkenlight thanks a lot for answer. Does it comes to your mind any better solution ? Or it would not worth to hassle for not important performance gain = Feb 26, 2012 at 14:21
• @MonsterMMORPG If your words are short (say 50 chars or less) I wouldn't bother. Feb 26, 2012 at 14:32
• @MonsterMMORPG here is an article that uses an `[m+1]` array. However, it starts to matter only when your string become reasonably long, say, a hundred characters or so. Feb 26, 2012 at 14:37

There is a big number of string similarity distance algorithms that can be used. Some listed here (but not exhaustively listed are):

A library that contains implementation to all of these is called SimMetrics which has both java and c# implementations.

• Thanks going to use Levenstein class at that file :) Feb 26, 2012 at 14:31
• Give Jaro winkler a go too. I've found that it gives great results. Feb 26, 2012 at 14:39

I have found that Levenshtein and Jaro Winkler are great for small differences betwen strings such as:

• Spelling mistakes; or
• ö instead of o in a persons name.

However when comparing something like article titles where significant chunks of the text would be the same but with "noise" around the edges, Smith-Waterman-Gotoh has been fantastic:

compare these 2 titles (that are the same but worded differently from different sources):

An endonuclease from Escherichia coli that introduces single polynucleotide chain scissions in ultraviolet-irradiated DNA

Endonuclease III: An Endonuclease from Escherichia coli That Introduces Single Polynucleotide Chain Scissions in Ultraviolet-Irradiated DNA

This site that provides algorithm comparison of the strings shows:

• Levenshtein: 81
• Smith-Waterman Gotoh 94
• Jaro Winkler 78

Jaro Winkler and Levenshtein are not as competent as Smith Waterman Gotoh in detecting the similarity. If we compare two titles that are not the same article, but have some matching text:

Fat metabolism in higher plants. The function of acyl thioesterases in the metabolism of acyl-coenzymes A and acyl-acyl carrier proteins

Fat metabolism in higher plants. The determination of acyl-acyl carrier protein and acyl coenzyme A in a complex lipid mixture

Jaro Winkler gives a false positive, but Smith Waterman Gotoh does not:

• Levenshtein: 54
• Smith-Waterman Gotoh 49
• Jaro Winkler 89

As Anastasiosyal pointed out, SimMetrics has the java code for these algorithms. I had success using the SmithWatermanGotoh java code from SimMetrics.

• Where can a c# or vb.net version of the Smith WaterMan source code be found Mar 26, 2018 at 22:54
• found it, here is the c# implementation jaligner.sourceforge.net/naligner Mar 28, 2018 at 21:17

Here is my implementation of Damerau Levenshtein Distance, which returns not only similarity coefficient, but also returns error locations in corrected word (this feature can be used in text editors). Also my implementation supports different weights of errors (substitution, deletion, insertion, transposition).

``````public static List<Mistake> OptimalStringAlignmentDistance(
string word, string correctedWord,
bool transposition = true,
int substitutionCost = 1,
int insertionCost = 1,
int deletionCost = 1,
int transpositionCost = 1)
{
int w_length = word.Length;
int cw_length = correctedWord.Length;
var d = new KeyValuePair<int, CharMistakeType>[w_length + 1, cw_length + 1];
var result = new List<Mistake>(Math.Max(w_length, cw_length));

if (w_length == 0)
{
for (int i = 0; i < cw_length; i++)
return result;
}

for (int i = 0; i <= w_length; i++)
d[i, 0] = new KeyValuePair<int, CharMistakeType>(i, CharMistakeType.None);

for (int j = 0; j <= cw_length; j++)
d[0, j] = new KeyValuePair<int, CharMistakeType>(j, CharMistakeType.None);

for (int i = 1; i <= w_length; i++)
{
for (int j = 1; j <= cw_length; j++)
{
bool equal = correctedWord[j - 1] == word[i - 1];
int delCost = d[i - 1, j].Key + deletionCost;
int insCost = d[i, j - 1].Key + insertionCost;
int subCost = d[i - 1, j - 1].Key;
if (!equal)
subCost += substitutionCost;
int transCost = int.MaxValue;
if (transposition && i > 1 && j > 1 && word[i - 1] == correctedWord[j - 2] && word[i - 2] == correctedWord[j - 1])
{
transCost = d[i - 2, j - 2].Key;
if (!equal)
transCost += transpositionCost;
}

int min = delCost;
CharMistakeType mistakeType = CharMistakeType.Deletion;
if (insCost < min)
{
min = insCost;
mistakeType = CharMistakeType.Insertion;
}
if (subCost < min)
{
min = subCost;
mistakeType = equal ? CharMistakeType.None : CharMistakeType.Substitution;
}
if (transCost < min)
{
min = transCost;
mistakeType = CharMistakeType.Transposition;
}

d[i, j] = new KeyValuePair<int, CharMistakeType>(min, mistakeType);
}
}

int w_ind = w_length;
int cw_ind = cw_length;
while (w_ind >= 0 && cw_ind >= 0)
{
switch (d[w_ind, cw_ind].Value)
{
case CharMistakeType.None:
w_ind--;
cw_ind--;
break;
case CharMistakeType.Substitution:
w_ind--;
cw_ind--;
break;
case CharMistakeType.Deletion:
w_ind--;
break;
case CharMistakeType.Insertion:
cw_ind--;
break;
case CharMistakeType.Transposition:
w_ind -= 2;
cw_ind -= 2;
break;
}
}
if (d[w_length, cw_length].Key > result.Count)
{
int delMistakesCount = d[w_length, cw_length].Key - result.Count;
for (int i = 0; i < delMistakesCount; i++)
}

result.Reverse();

return result;
}

public struct Mistake
{
public int Position;
public CharMistakeType Type;

public Mistake(int position, CharMistakeType type)
{
Position = position;
Type = type;
}

public override string ToString()
{
return Position + ", " + Type;
}
}

public enum CharMistakeType
{
None,
Substitution,
Insertion,
Deletion,
Transposition
}
``````

This code is a part of my project: Yandex-Linguistics.NET.

I wrote some tests and it's seems to me that method is working.

But comments and remarks are welcome.

Here is an alternative approach:

A typical method for finding similarity is Levenshtein distance, and there is no doubt a library with code available.

Unfortunately, this requires comparing to every string. You might be able to write a specialized version of the code to short-circuit the calculation if the distance is greater than some threshold, you would still have to do all the comparisons.

Another idea is to use some variant of trigrams or n-grams. These are sequences of n characters (or n words or n genomic sequences or n whatever). Keep a mapping of trigrams to strings and choose the ones that have the biggest overlap. A typical choice of n is "3", hence the name.

For instance, English would have these trigrams:

• Eng
• ngl
• gli
• lis
• ish

And England would have:

• Eng
• ngl
• gla
• lan
• and

Well, 2 out of 7 (or 4 out of 10) match. If this works for you, and you can index the trigram/string table and get a faster search.

You can also combine this with Levenshtein to reduce the set of comparison to those that have some minimum number of n-grams in common.

Here's a VB.net implementation:

``````Public Shared Function LevenshteinDistance(ByVal v1 As String, ByVal v2 As String) As Integer
Dim cost(v1.Length, v2.Length) As Integer
If v1.Length = 0 Then
Return v2.Length                'if string 1 is empty, the number of edits will be the insertion of all characters in string 2
ElseIf v2.Length = 0 Then
Return v1.Length                'if string 2 is empty, the number of edits will be the insertion of all characters in string 1
Else
'setup the base costs for inserting the correct characters
For v1Count As Integer = 0 To v1.Length
cost(v1Count, 0) = v1Count
Next v1Count
For v2Count As Integer = 0 To v2.Length
cost(0, v2Count) = v2Count
Next v2Count
'now work out the cheapest route to having the correct characters
For v1Count As Integer = 1 To v1.Length
For v2Count As Integer = 1 To v2.Length
'the first min term is the cost of editing the character in place (which will be the cost-to-date or the cost-to-date + 1 (depending on whether a change is required)
'the second min term is the cost of inserting the correct character into string 1 (cost-to-date + 1),
'the third min term is the cost of inserting the correct character into string 2 (cost-to-date + 1) and
cost(v1Count, v2Count) = Math.Min(
cost(v1Count - 1, v2Count - 1) + If(v1.Chars(v1Count - 1) = v2.Chars(v2Count - 1), 0, 1),
Math.Min(
cost(v1Count - 1, v2Count) + 1,
cost(v1Count, v2Count - 1) + 1
)
)
Next v2Count
Next v1Count

'the final result is the cheapest cost to get the two strings to match, which is the bottom right cell in the matrix
'in the event of strings being equal, this will be the result of zipping diagonally down the matrix (which will be square as the strings are the same length)
Return cost(v1.Length, v2.Length)
End If
End Function
``````