I am interested in algorithm in TSQL calculating Levenshtein distance.
I implemented the standard Levenshtein edit distance function in TSQL with several optimizations that improves the speed over the other versions I'm aware of. In cases where the two strings have characters in common at their start (shared prefix), characters in common at their end (shared suffix), and when the strings are large and a max edit distance is provided, the improvement in speed is significant. For example, when the inputs are two very similar 4000 character strings, and a max edit distance of 2 is specified, this is almost three orders of magnitude faster than the edit_distance_within
function in the accepted answer, returning the answer in 0.073 seconds (73 milliseconds) vs 55 seconds. It's also memory efficient, using space equal to the larger of the two input strings plus some constant space. It uses a single nvarchar "array" representing a column, and does all computations inplace in that, plus some helper int variables.
Optimizations:
 skips processing of shared prefix and/or suffix
 early return if larger string starts or ends with entire smaller string
 early return if difference in sizes guarantees max distance will be exceeded
 uses only a single array representing a column in the matrix (implemented as nvarchar)
 when a max distance is given, time complexity goes from (len1*len2) to (min(len1,len2)) i.e. linear
 when a max distance is given, early return as soon as max distance bound is known not to be achievable
Here is the code (updated 1/20/2014 to speed it up a bit more):
 =============================================
 Computes and returns the Levenshtein edit distance between two strings, i.e. the
 number of insertion, deletion, and sustitution edits required to transform one
 string to the other, or NULL if @max is exceeded. Comparisons use the case
 sensitivity configured in SQL Server (caseinsensitive by default).

 Based on Sten Hjelmqvist's "Fast, memory efficient" algorithm, described
 at http://www.codeproject.com/Articles/13525/FastmemoryefficientLevenshteinalgorithm,
 with some additional optimizations.
 =============================================
CREATE FUNCTION [dbo].[Levenshtein](
@s nvarchar(4000)
, @t nvarchar(4000)
, @max int
)
RETURNS int
WITH SCHEMABINDING
AS
BEGIN
DECLARE @distance int = 0  return variable
, @v0 nvarchar(4000) running scratchpad for storing computed distances
, @start int = 1  index (1 based) of first nonmatching character between the two string
, @i int, @j int  loop counters: i for s string and j for t string
, @diag int  distance in cell diagonally above and left if we were using an m by n matrix
, @left int  distance in cell to the left if we were using an m by n matrix
, @sChar nchar  character at index i from s string
, @thisJ int  temporary storage of @j to allow SELECT combining
, @jOffset int  offset used to calculate starting value for j loop
, @jEnd int  ending value for j loop (stopping point for processing a column)
 get input string lengths including any trailing spaces (which SQL Server would otherwise ignore)
, @sLen int = datalength(@s) / datalength(left(left(@s, 1) + '.', 1))  length of smaller string
, @tLen int = datalength(@t) / datalength(left(left(@t, 1) + '.', 1))  length of larger string
, @lenDiff int  difference in length between the two strings
 if strings of different lengths, ensure shorter string is in s. This can result in a little
 faster speed by spending more time spinning just the inner loop during the main processing.
IF (@sLen > @tLen) BEGIN
SELECT @v0 = @s, @i = @sLen  temporarily use v0 for swap
SELECT @s = @t, @sLen = @tLen
SELECT @t = @v0, @tLen = @i
END
SELECT @max = ISNULL(@max, @tLen)
, @lenDiff = @tLen  @sLen
IF @lenDiff > @max RETURN NULL
 suffix common to both strings can be ignored
WHILE(@sLen > 0 AND SUBSTRING(@s, @sLen, 1) = SUBSTRING(@t, @tLen, 1))
SELECT @sLen = @sLen  1, @tLen = @tLen  1
IF (@sLen = 0) RETURN @tLen
 prefix common to both strings can be ignored
WHILE (@start < @sLen AND SUBSTRING(@s, @start, 1) = SUBSTRING(@t, @start, 1))
SELECT @start = @start + 1
IF (@start > 1) BEGIN
SELECT @sLen = @sLen  (@start  1)
, @tLen = @tLen  (@start  1)
 if all of shorter string matches prefix and/or suffix of longer string, then
 edit distance is just the delete of additional characters present in longer string
IF (@sLen <= 0) RETURN @tLen
SELECT @s = SUBSTRING(@s, @start, @sLen)
, @t = SUBSTRING(@t, @start, @tLen)
END
 initialize v0 array of distances
SELECT @v0 = '', @j = 1
WHILE (@j <= @tLen) BEGIN
SELECT @v0 = @v0 + NCHAR(CASE WHEN @j > @max THEN @max ELSE @j END)
SELECT @j = @j + 1
END
SELECT @jOffset = @max  @lenDiff
, @i = 1
WHILE (@i <= @sLen) BEGIN
SELECT @distance = @i
, @diag = @i  1
, @sChar = SUBSTRING(@s, @i, 1)
 no need to look beyond window of upper left diagonal (@i) + @max cells
 and the lower right diagonal (@i  @lenDiff)  @max cells
, @j = CASE WHEN @i <= @jOffset THEN 1 ELSE @i  @jOffset END
, @jEnd = CASE WHEN @i + @max >= @tLen THEN @tLen ELSE @i + @max END
WHILE (@j <= @jEnd) BEGIN
 at this point, @distance holds the previous value (the cell above if we were using an m by n matrix)
SELECT @left = UNICODE(SUBSTRING(@v0, @j, 1))
, @thisJ = @j
SELECT @distance =
CASE WHEN (@sChar = SUBSTRING(@t, @j, 1)) THEN @diag match, no change
ELSE 1 + CASE WHEN @diag < @left AND @diag < @distance THEN @diag substitution
WHEN @left < @distance THEN @left  insertion
ELSE @distance  deletion
END END
SELECT @v0 = STUFF(@v0, @thisJ, 1, NCHAR(@distance))
, @diag = @left
, @j = case when (@distance > @max) AND (@thisJ = @i + @lenDiff) then @jEnd + 2 else @thisJ + 1 end
END
SELECT @i = CASE WHEN @j > @jEnd + 1 THEN @sLen + 1 ELSE @i + 1 END
END
RETURN CASE WHEN @distance <= @max THEN @distance ELSE NULL END
END
As mentioned in the comments of this function, the case sensitivity of the character comparisons will follow the collation that's in effect. By default, SQL Server's collation is one that will result in case insensitive comparisons. One way to modify this function to always be case sensitive would be to add a specific collation to the two places where strings are compared. However, I have not thoroughly tested this, especially for side effects when the database is using a nondefault collation. These are how the two lines would be changed to force case sensitive comparisons:
 prefix common to both strings can be ignored
WHILE (@start < @sLen AND SUBSTRING(@s, @start, 1) = SUBSTRING(@t, @start, 1) COLLATE SQL_Latin1_General_Cp1_CS_AS)
and
SELECT @distance =
CASE WHEN (@sChar = SUBSTRING(@t, @j, 1) COLLATE SQL_Latin1_General_Cp1_CS_AS) THEN @diag match, no change

How can we use this to look up top 5 closest strings in a table? I mean let's say I have street names table with 10m rows. I enter search a street name but 1 character is incorrectly written. How can I look up top 5 closest matches with maximum performance? – MonsterMMORPG Feb 19 '17 at 1:06

Other than brute force (comparing all addresses), you can't. Levenshtein is not something that can easily take advantage of indexes. If you can narrow the candidates to a smaller subset via something that can be indexed, such as a zip code for address, or a phonetic code for names, for example, then straight Levenshtein like that in the answers here can feasibly be applied to the subset. To apply to an entire set that is large, you would need to go to something like Levenshtein Automata, but implementing that in SQL is way beyond the scope of the SO question being answered here. – hatchet  Reinstate Monica Feb 19 '17 at 1:30

@MonsterMMORPG in theory you could do the reverse and calculate all possible permutations for a given Levenshteindistance. Or you could try and see if the words in your addresses make up a list short enough to be useful (probably ignoring words which only rarely appear). – TheConstructor Jul 28 '17 at 7:59

@MonsterMMORPG  this is late, but I thought I'd add a better answer. If you know the minimum number of edits you will allow, you can use the Symmetric Delete method like has been done in the symspell project on github. You can store a small subset of permutations of just deletes, and then search for any in the small set of delete permutations of the search string. On the returned set (which would be small if you only allow 1 or 2 max edit distance), you then do the full levenshtein calc. But that should be much, much less than doing it on all strings. – hatchet  Reinstate Monica Dec 20 '17 at 20:33

1@DaveCousineau  As mentioned in the function comments, string comparisons use the case sensitivity for the SQL Server collation in effect. By default, this typically means case insensitive. See the edit to my post I just added. The Fribble implementation in another answer behaves similarly regarding collation. – hatchet  Reinstate Monica Jan 31 at 21:40
Arnold Fribble had two proposals on sqlteam.com/forums
This is the younger one from 2006:
SET QUOTED_IDENTIFIER ON
GO
SET ANSI_NULLS ON
GO
CREATE FUNCTION edit_distance_within(@s nvarchar(4000), @t nvarchar(4000), @d int)
RETURNS int
AS
BEGIN
DECLARE @sl int, @tl int, @i int, @j int, @sc nchar, @c int, @c1 int,
@cv0 nvarchar(4000), @cv1 nvarchar(4000), @cmin int
SELECT @sl = LEN(@s), @tl = LEN(@t), @cv1 = '', @j = 1, @i = 1, @c = 0
WHILE @j <= @tl
SELECT @cv1 = @cv1 + NCHAR(@j), @j = @j + 1
WHILE @i <= @sl
BEGIN
SELECT @sc = SUBSTRING(@s, @i, 1), @c1 = @i, @c = @i, @cv0 = '', @j = 1, @cmin = 4000
WHILE @j <= @tl
BEGIN
SET @c = @c + 1
SET @c1 = @c1  CASE WHEN @sc = SUBSTRING(@t, @j, 1) THEN 1 ELSE 0 END
IF @c > @c1 SET @c = @c1
SET @c1 = UNICODE(SUBSTRING(@cv1, @j, 1)) + 1
IF @c > @c1 SET @c = @c1
IF @c < @cmin SET @cmin = @c
SELECT @cv0 = @cv0 + NCHAR(@c), @j = @j + 1
END
IF @cmin > @d BREAK
SELECT @cv1 = @cv0, @i = @i + 1
END
RETURN CASE WHEN @cmin <= @d AND @c <= @d THEN @c ELSE 1 END
END
GO

1@Alexander, it seems to work but I would change your variable names to something more meaningfull. Also, I'd get rid of @d, you know the length of the two strings in your input. – Lieven Keersmaekers Feb 18 '09 at 12:01

2@Lieven: It isn't my implementation, the author is Arnold Fribble. @d parameter is a maximal allowed difference between strings after reaching which they are considered too diverse and function returns 1. It's added because the algorithm in TSQL works too slowly. – Alexander Prokofyev Feb 18 '09 at 12:26

You should check out the algorithm psuedo code over at: en.wikipedia.org/wiki/Levenshtein_distance it isn't a whole lot improved. – Norman H Jan 29 '15 at 22:05
IIRC, with SQL Server 2005 and later you can write stored procedures in any .NET language: Using CLR Integration in SQL Server 2005. With that it shouldn't be hard to write a procedure for calculating Levenstein distance.
A simple Hello, World! extracted from the help:
using System;
using System.Data;
using Microsoft.SqlServer.Server;
using System.Data.SqlTypes;
public class HelloWorldProc
{
[Microsoft.SqlServer.Server.SqlProcedure]
public static void HelloWorld(out string text)
{
SqlContext.Pipe.Send("Hello world!" + Environment.NewLine);
text = "Hello world!";
}
}
Then in your SQL Server run the following:
CREATE ASSEMBLY helloworld from 'c:\helloworld.dll' WITH PERMISSION_SET = SAFE
CREATE PROCEDURE hello
@i nchar(25) OUTPUT
AS
EXTERNAL NAME helloworld.HelloWorldProc.HelloWorld
And now you can test run it:
DECLARE @J nchar(25)
EXEC hello @J out
PRINT @J
Hope this helps.
You can use Levenshtein Distance Algorithm for comparing strings
Here you can find a TSQL example at http://www.kodyaz.com/articles/fuzzystringmatchingusinglevenshteindistancesqlserver.aspx
CREATE FUNCTION edit_distance(@s1 nvarchar(3999), @s2 nvarchar(3999))
RETURNS int
AS
BEGIN
DECLARE @s1_len int, @s2_len int
DECLARE @i int, @j int, @s1_char nchar, @c int, @c_temp int
DECLARE @cv0 varbinary(8000), @cv1 varbinary(8000)
SELECT
@s1_len = LEN(@s1),
@s2_len = LEN(@s2),
@cv1 = 0x0000,
@j = 1, @i = 1, @c = 0
WHILE @j <= @s2_len
SELECT @cv1 = @cv1 + CAST(@j AS binary(2)), @j = @j + 1
WHILE @i <= @s1_len
BEGIN
SELECT
@s1_char = SUBSTRING(@s1, @i, 1),
@c = @i,
@cv0 = CAST(@i AS binary(2)),
@j = 1
WHILE @j <= @s2_len
BEGIN
SET @c = @c + 1
SET @c_temp = CAST(SUBSTRING(@cv1, @j+@j1, 2) AS int) +
CASE WHEN @s1_char = SUBSTRING(@s2, @j, 1) THEN 0 ELSE 1 END
IF @c > @c_temp SET @c = @c_temp
SET @c_temp = CAST(SUBSTRING(@cv1, @j+@j+1, 2) AS int)+1
IF @c > @c_temp SET @c = @c_temp
SELECT @cv0 = @cv0 + CAST(@c AS binary(2)), @j = @j + 1
END
SELECT @cv1 = @cv0, @i = @i + 1
END
RETURN @c
END
(Function developped by Joseph Gama)
Usage :
select
dbo.edit_distance('Fuzzy String Match','fuzzy string match'),
dbo.edit_distance('fuzzy','fuzy'),
dbo.edit_distance('Fuzzy String Match','fuzy string match'),
dbo.edit_distance('levenshtein distance sql','levenshtein sql server'),
dbo.edit_distance('distance','server')
The algorithm simply returns the stpe count to change one string into other by replacing a different character at one step
I was looking for a code example for the Levenshtein algorithm, too, and was happy to find it here. Of course I wanted to understand how the algorithm is working and I was playing around a little bit with one of the above examples I was playing around a little bit that was posted by Veve. In order to get a better understanding of the code I created an EXCEL with the Matrix.
distance for FUZZY compared with FUZY
Images say more than 1000 words.
With this EXCEL I found that there was potential for additional performance optimization. All values in the upper right red area do not need to be calculated. The value of each red cell results in the value of the left cell plus 1. This is because, the second string will be always longer in that area than the first one, what increases the distance by the value of 1 for each character.
You can reflect that by using the statement IF @j <= @i and increasing the value of @i Prior to this statement.
CREATE FUNCTION [dbo].[f_LevenshteinDistance](@s1 nvarchar(3999), @s2 nvarchar(3999))
RETURNS int
AS
BEGIN
DECLARE @s1_len int;
DECLARE @s2_len int;
DECLARE @i int;
DECLARE @j int;
DECLARE @s1_char nchar;
DECLARE @c int;
DECLARE @c_temp int;
DECLARE @cv0 varbinary(8000);
DECLARE @cv1 varbinary(8000);
SELECT
@s1_len = LEN(@s1),
@s2_len = LEN(@s2),
@cv1 = 0x0000 ,
@j = 1 ,
@i = 1 ,
@c = 0
WHILE @j <= @s2_len
SELECT @cv1 = @cv1 + CAST(@j AS binary(2)), @j = @j + 1;
WHILE @i <= @s1_len
BEGIN
SELECT
@s1_char = SUBSTRING(@s1, @i, 1),
@c = @i ,
@cv0 = CAST(@i AS binary(2)),
@j = 1;
SET @i = @i + 1;
WHILE @j <= @s2_len
BEGIN
SET @c = @c + 1;
IF @j <= @i
BEGIN
SET @c_temp = CAST(SUBSTRING(@cv1, @j + @j  1, 2) AS int) + CASE WHEN @s1_char = SUBSTRING(@s2, @j, 1) THEN 0 ELSE 1 END;
IF @c > @c_temp SET @c = @c_temp
SET @c_temp = CAST(SUBSTRING(@cv1, @j + @j + 1, 2) AS int) + 1;
IF @c > @c_temp SET @c = @c_temp;
END;
SELECT @cv0 = @cv0 + CAST(@c AS binary(2)), @j = @j + 1;
END;
SET @cv1 = @cv0;
END;
RETURN @c;
END;

As written, this will not always give the correct results. For example, the inputs
('jane', 'jeanne')
will return a distance of 3, when the distance should be 2. To correct this additional code should be added that swaps@s1
and@s2
if@s1
has a shorter length than@s2
. – hatchet  Reinstate Monica Jun 5 '17 at 23:44
In TSQL the best and fastest way to compare two items are SELECT statements that join tables on indexed columns. Therefore this is how I suggest to implement the editing distance if you want to benefit from the advantages of a RDBMS engine. TSQL Loops will work too, but Levenstein distance calculations will be faster in other languages than in TSQL for large volume comparisons.
I have implemented the editing distance in several systems using series of Joins against temporary tables designed for that purpose only. It requires some heavy preprocessing steps  the preparation of the temporary tables  but it works very well with large number of comparisons.
In a few words: the preprocessing consists of creating, populating and indexing temp tables. The first one contains reference ids, a oneletter column and a charindex column. This table is populated by running a series of insert queries that split every word into letters (using SELECT SUBSTRING) to create as many rows as word in the source list have letters (I know, that's a lot of rows but SQL server can handle billions of rows). Then make a second table with a 2letter column, another table with a 3letter column, etc. The end results is a series of tables which contain reference ids and substrings of each the words, as well a the reference of their position in the word.
Once this is done, the whole game is about duplicating these tables and joining them against their duplicate in a GROUP BY select query which counts the number of matches. This creates a series of measures for every possible pair of words, which are then reaggregated into a single Levenstein distance per pair of words.
Technically this is very different than most other implementations of the Levenstein distance (or its variants) so you need to deeply understand how the Levenstein distance works and why it was designed as it is. Investigate the alternatives as well because with that method you end up with a series of underlying metrics which can help calculate many variants of the editing distance at the same time, providing you with interesting machine learning potential improvements.
Another point already mentioned by previous answers in this page: try to pre process as much as possible to eliminate the pairs that do not require distance measurement. For example a pair of two words that have not a single letter in common should be excluded, because the editing distance can be obtained from the length of the strings. Or do not measure the distance between two copies of the same word, since it is 0 by nature. Or remove duplicates before doing the measurement, if your list of words comes from a long text it is likely that the same words will appear more than once, so measuring the distance only once will save processing time, etc.