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I need a way to compare multiple strings to a test string and return the string that closely resembles it:

TEST STRING: THE BROWN FOX JUMPED OVER THE RED COW

CHOICE A   : THE RED COW JUMPED OVER THE GREEN CHICKEN
CHOICE B   : THE RED COW JUMPED OVER THE RED COW
CHOICE C   : THE RED FOX JUMPED OVER THE BROWN COW

(If I did this correctly) The closest string to the "TEST STRING" should be "CHOICE C". What is the easiest way to do this?

I plan on implementing this into multiple languages including VB.net, Lua, and JavaScript. At this point, pseudo code is acceptable. If you can provide an example for a specific language, this is appreciated too!

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2  
Algorithms that typically do this type of stuff work on determining how many changes it takes to turn an examined string into the target string. Those types of algorithms don't work well at all in a situation like this. I think getting a computer to pull this off will be very tough. –  Matt Greer May 2 '11 at 16:28
2  
Levenshtein distance source code in many languages: Java, Ruby, Python, PHP, etc. en.wikibooks.org/wiki/Algorithm_Implementation/Strings/… –  joelparkerhenderson May 4 '12 at 1:26
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In general, what counts as "closest string" will depend on the similarity measure used, and the penalties used for introducing gaps in the alignment. For example, do you consider "cow" and "chicken" more similar than "cow" and "red" (because they are related concepts), or is it the other way around (because "chicken" has more letters than "cow")? But given a similarity measure and gap penalty, it can be shown that the Levenshtein algorithm below is guaranteed to find you the closest string. Same is true of Needleman-Wunsch and Smith-Waterman (further below). –  Sten L May 4 '12 at 9:56

8 Answers 8

up vote 629 down vote accepted
+100

I was presented with this problem about a year ago when it came to looking up user entered information about a oil rig in a database of miscellaneous information. The goal was to do some sort of fuzzy string search that could identify the database entry with the most common elements.

Part of the research involved implementing the Levenshtein distance algorithm, which determines how many changes must be made to a string or phrase to turn it into another string or phrase.

The implementation I came up with was relatively simple, and involved a weighted comparison of the length of the two phrases, the number of changes between each phrase, and whether each word could be found in the target entry.

The article is on a private site so I'll do my best to append the relevant contents here:


Fuzzy String Matching is the process of performing a human-like estimation of the similarity of two words or phrases. In many cases, it involves identifying words or phrases which are most similar to each other. This article describes an in-house solution to the fuzzy string matching problem and its usefulness in solving a variety of problems which can allow us to automate tasks which previously required tedious user involvement.

Introduction

The need to do fuzzy string matching originally came about while developing the Gulf of Mexico Validator tool. What existed was a database of known gulf of Mexico oil rigs and platforms, and people buying insurance would give us some badly typed out information about their assets and we had to match it to the database of known platforms. When there was very little information given, the best we could do is rely on an underwriter to "recognize" the one they were referring to and call up the proper information. This is where this automated solution comes in handy.

I spent a day researching methods of fuzzy string matching, and eventually stumbled upon the very useful Levenshtein distance algorithm on Wikipedia.

Implementation

After reading about the theory behind it, I implemented and found ways to optimize it. This is how my code looks like in VBA:

'Calculate the Levenshtein Distance between two strings (the number of insertions,
'deletions, and substitutions needed to transform the first string into the second)
Public Function LevenshteinDistance(ByRef S1 As String, ByVal S2 As String) As Long
    Dim L1 As Long, L2 As Long, D() As Long 'Length of input strings and distance matrix
    Dim i As Long, j As Long, cost As Long 'loop counters and cost of substitution for current letter
    Dim cI As Long, cD As Long, cS As Long 'cost of next Insertion, Deletion and Substitution
    L1 = Len(S1): L2 = Len(S2)
    ReDim D(0 To L1, 0 To L2)
    For i = 0 To L1: D(i, 0) = i: Next i
    For j = 0 To L2: D(0, j) = j: Next j

    For j = 1 To L2
        For i = 1 To L1
            cost = Abs(StrComp(Mid$(S1, i, 1), Mid$(S2, j, 1), vbTextCompare))
            cI = D(i - 1, j) + 1
            cD = D(i, j - 1) + 1
            cS = D(i - 1, j - 1) + cost
            If cI <= cD Then 'Insertion or Substitution
                If cI <= cS Then D(i, j) = cI Else D(i, j) = cS
            Else 'Deletion or Substitution
                If cD <= cS Then D(i, j) = cD Else D(i, j) = cS
            End If
        Next i
    Next j
    LevenshteinDistance = D(L1, L2)
End Function

Simple, speedy, and a very useful metric. Using this, I created two separate metrics for evaluating the similarity of two strings. One I call "valuePhrase" and one I call "valueWords". valuePhrase is just the Levenshtein distance between the two phrases, and valueWords splits the string into individual words, based on delimiters such as spaces, dashes, and anything else you'd like, and compares each word to each other word, summing up the shortest Levenshtein distance connecting any two words. Essentially, it measures whether the information in one 'phrase' is really contained in another, just as a word-wise permutation. I spent a few days as a side project coming up with the most efficient way possible of splitting a string based on delimiters.

valueWords, valuePhrase, and Split function:

Public Function valuePhrase#(ByRef S1$, ByRef S2$)
    valuePhrase = LevenshteinDistance(S1, S2)
End Function

Public Function valueWords#(ByRef S1$, ByRef S2$)
    Dim wordsS1$(), wordsS2$()
    wordsS1 = SplitMultiDelims(S1, " _-")
    wordsS2 = SplitMultiDelims(S2, " _-")
    Dim word1%, word2%, thisD#, wordbest#
    Dim wordsTotal#
    For word1 = LBound(wordsS1) To UBound(wordsS1)
        wordbest = Len(S2)
        For word2 = LBound(wordsS2) To UBound(wordsS2)
            thisD = LevenshteinDistance(wordsS1(word1), wordsS2(word2))
            If thisD < wordbest Then wordbest = thisD
            If thisD = 0 Then GoTo foundbest
        Next word2
foundbest:
        wordsTotal = wordsTotal + wordbest
    Next word1
    valueWords = wordsTotal
End Function

''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''
' SplitMultiDelims
' This function splits Text into an array of substrings, each substring
' delimited by any character in DelimChars. Only a single character
' may be a delimiter between two substrings, but DelimChars may
' contain any number of delimiter characters. It returns a single element
' array containing all of text if DelimChars is empty, or a 1 or greater
' element array if the Text is successfully split into substrings.
' If IgnoreConsecutiveDelimiters is true, empty array elements will not occur.
' If Limit greater than 0, the function will only split Text into 'Limit'
' array elements or less. The last element will contain the rest of Text.
''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''
Function SplitMultiDelims(ByRef Text As String, ByRef DelimChars As String, _
        Optional ByVal IgnoreConsecutiveDelimiters As Boolean = False, _
        Optional ByVal Limit As Long = -1) As String()
    Dim ElemStart As Long, N As Long, M As Long, Elements As Long
    Dim lDelims As Long, lText As Long
    Dim Arr() As String

    lText = Len(Text)
    lDelims = Len(DelimChars)
    If lDelims = 0 Or lText = 0 Or Limit = 1 Then
        ReDim Arr(0 To 0)
        Arr(0) = Text
        SplitMultiDelims = Arr
        Exit Function
    End If
    ReDim Arr(0 To IIf(Limit = -1, lText - 1, Limit))

    Elements = 0: ElemStart = 1
    For N = 1 To lText
        If InStr(DelimChars, Mid(Text, N, 1)) Then
            Arr(Elements) = Mid(Text, ElemStart, N - ElemStart)
            If IgnoreConsecutiveDelimiters Then
                If Len(Arr(Elements)) > 0 Then Elements = Elements + 1
            Else
                Elements = Elements + 1
            End If
            ElemStart = N + 1
            If Elements + 1 = Limit Then Exit For
        End If
    Next N
    'Get the last token terminated by the end of the string into the array
    If ElemStart <= lText Then Arr(Elements) = Mid(Text, ElemStart)
    'Since the end of string counts as the terminating delimiter, if the last character
    'was also a delimiter, we treat the two as consecutive, and so ignore the last elemnent
    If IgnoreConsecutiveDelimiters Then If Len(Arr(Elements)) = 0 Then Elements = Elements - 1

    ReDim Preserve Arr(0 To Elements) 'Chop off unused array elements
    SplitMultiDelims = Arr
End Function

Measures of Similarity

Using these two metrics, and a third which simply computes the distance between two strings, I have a series of variables which I can run an optimization algorithm to achieve the greatest number of matches. Fuzzy string matching is, itself, a fuzzy science, and so by creating linearly independent metrics for measuring string similarity, and having a known set of strings we wish to match to each other, we can find the parameters that, for our specific styles of strings, give the best fuzzy match results.

Initially, the goal of the metric was to have a low search value for for an exact match, and increasing search values for increasingly permuted measures. In an impractical case, this was fairly easy to define using a set of well defined permutations, and engineering the final formula such that they had increasing search values results as desired.

Fuzzy String Matching Permutations

Fuzzy String Matching Value Phrase

Fuzzy String Matching Value Words

As you can see, the last two metrics, which are fuzzy string matching metrics, already have a natural tendency to give low scores to strings that are meant to match (down the diagonal). This is very good.

Application To allow the optimization of fuzzy matching, I weight each metric. As such, every application of fuzzy string match can weight the parameters differently. The formula that defines the final score is a simply combination of the metrics and their weights:

value = Min(phraseWeight*phraseValue, wordsWeight*wordsValue)*minWeight + 
        Max(phraseWeight*phraseValue, wordsWeight*wordsValue)*maxWeight + lengthWeight*lengthValue

Using an optimization algorithm (neural network is best here because it is a discrete, multi-dimentional problem), the goal is now to maximize the number of matches. I created a function that detects the number of correct matches of each set to each other, as can be seen in this final screenshot. A column or row gets a point if the lowest score is assigned the the string that was meant to be matched, and partial points are given if there is a tie for the lowest score, and the correct match is among the tied matched strings. I then optimized it. You can see that a green cell is the column that best matches the current row, and a blue square around the cell is the row that best matches the current column. The score in the bottom corner is roughly the number of successful matches and this is what we tell our optimization problem to maximize.

Fuzzy String Matching Optimized Metric

The algorithm was a wonderful success, and the solution parameters say a lot about this type of problem. You'll notice the optimized score was 44, and the best possible score is 48. The 5 columns at the end are decoys, and do not have any match at all to the row values. The more decoys there are, the harder it will naturally be to find the best match.

In this particular matching case, the length of the strings are irrelevant, because we are expecting abbreviations that represent longer words, so the optimal weight for length is -0.3, which means we do not penalize strings which vary in length. We reduce the score in anticipation of these abbreviations, giving more room for partial word matches to supersede non-word matches that simply require less substitutions because the string is shorter.

The word weight is 1.0 while the phrase weight is only 0.5, which means that we penalize whole words missing from one string and value more the entire phrase being intact. This is useful because a lot of these strings have one word in common (the peril) where what really matters is whether or not the combination (region and peril) are maintained.

Finally, the min weight is optimized at 10 and the max weight at 1. What this means is that if the best of the two scores (value phrase and value words) isn't very good, the match is greatly penalized, but we don't greatly penalize the worst of the two scores. Essentially, this puts emphasis on requiring [i]either[/i] the valueWord or valuePhrase to have a good score, but not both. A sort of "take what we can get" mentality.

It's really fascinating what the optimized value of these 5 weights say about the sort of fuzzy string matching taking place. For completely different practical cases of fuzzy string matching, these parameters are very different. I've used it for 3 separate applications so far.

While unused in the final optimization, a benchmarking sheet was established which matches columns to themselves for all perfect results down the diagonal, and lets the user change parameters to control the rate at which scores diverge from 0, and note innate similarities between search phrases (which could in theory be used to offset false positives in the results)

Fuzzy String Matching Benchmark

Further Applications

This solution has potential to be used anywhere where the user wishes to have a computer system identify a string in a set of strings where there is no perfect match. (Like an approximate match vlookup for strings). If anyone finding this article is seeking similar functionality, feel free to contact the author to discuss methods of catering the solution to your particular application.


So what you should take from this, is that you probably want to use a combination of high level heuristics (finding words from one phrase in the other phrase, length of both phrases, etc) along with the implementation of the Levenshtein distance algorithm. Because deciding which is the "best" match is a heuristic (fuzzy) determination - you'll have to come up with a set of weights for any metrics you come up with to determine similarity.

With the appropriate set of heuristics and weights, you'll have your comparison program quickly making the decisions that you would have made.

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7  
Bonus: If anyone wants to include additional metrics into their weighted heuristic, (since I only provided 3 which weren't all that linearly independent) - here is a whole list on wikipedia: en.wikipedia.org/wiki/String_metric –  Alain Apr 9 '12 at 20:22
    
Awesome! You may be able to speed this up quite a bit by replacing the 2D-matrix-based code in LevenshteinDistance() with something like the 1D approach as used in Chas Emerick’s Java implementation. –  JanX2 May 4 '12 at 18:46
    
If S2 has a lot of words (and creating many small objects is not prohibitively slow in your language of choice) a trie can speed things up. Fast and Easy Levenshtein distance using a Trie is a great article about tries. –  JanX2 May 4 '12 at 19:20
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You win the internet for this answer. Game over. –  Scott Beeson Apr 17 '13 at 19:12

This problem turns up all the time in bioinformatics. The accepted answer above (which was great by the way) is known in bioinformatics as the Needleman-Wunsch (compare two strings) and Smith-Waterman (find an approximate substring in a longer string) algorithms. They work great and have been workhorses for decades.

But what if you have a million strings to compare? That's a trillion pairwise comparisons, each of which is O(n*m)! Modern DNA sequencers easily generate a billion short DNA sequences, each about 200 DNA "letters" long. Typically, we want to find, for each such string, the best match against the human genome (3 billion letters). Clearly, the Needleman-Wunsch algorithm and its relatives will not do.

This so-called "alignment problem" is a field of active research. The most popular algorithms are currently able to find inexact matches between 1 billion short strings and the human genome in a matter of hours on reasonable hardware (say, eight cores and 32 GB RAM).

Most of these algorithms work by quickly finding short exact matches (seeds) and then extending these to the full string using a slower algorithm (for example, the Smith-Waterman). The reason this works is that we are really only interested in a few close matches, so it pays off to get rid of the 99.9...% of pairs that have nothing in common.

How does finding exact matches help finding inexact matches? Well, say we allow only a single difference between the query and the target. It is easy to see that this difference must occur in either the right or left half of the query, and so the other half must match exactly. This idea can be extended to multiple mismatches and is the basis for the ELAND algorithm commonly used with Illumina DNA sequencers.

There are many very good algorithms for doing exact string matching. Given a query string of length 200, and a target string of length 3 billion (the human genome), we want to find any place in the target where there is a substring of length k that matches a substring of the query exactly. A simple approach is to begin by indexing the target: take all k-long substrings, put them in an array and sort them. Then take each k-long substring of the query and search the sorted index. Sort and search can be done in O(log n) time.

But storage can be a problem. An index of the 3 billion letter target would need to hold 3 billion pointers and 3 billion k-long words. It would seem hard to fit this in less than several tens of gigabytes of RAM. But amazingly we can greatly compress the index, using the Burrows-Wheeler transform, and it will still be efficiently queryable. An index of the human genome can fit in less than 4 GB RAM. This idea is the basis of popular sequence aligners such as Bowtie and BWA.

Alternatively, we can use a suffix array, which stores only the pointers, yet represents a simultaneous index of all suffixes in the target string (essentially, a simultaneous index for all possible values of k; the same is true of the Burrows-Wheeler transform). A suffix array index of the human genome will take 12 GB of RAM if we use 32-bit pointers.

The links above contain a wealth of information and links to primary research papers. The ELAND link goes to a PDF with useful figures illustrating the concepts involved, and shows how to deal with insertions and deletions.

Finally, while these algorithms have basically solved the problem of (re)sequencing single human genomes (a billion short strings), DNA sequencing technology improves even faster than Moore's law, and we are fast approaching trillion-letter datasets. For example, there are currently projects underway to sequence the genomes of 10,000 vertebrate species, each a billion letters long or so. Naturally, we will want to do pairwise inexact string matching on the data...

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3  
Really good run-down. A couple of corrections: Sorting the infixes takes O(n) at least, not O(log n). And since O(log n) search is actually too slow in practice, you’d normally build an additional table to get O(1) lookup (q-gram index). Furthermore, I’m not sure why you treat this differently from the suffix array – it’s just an optimisation of the latter, no (sorting fixed-length infixes instead of suffixes since we don’t actually need more than a fixed length). –  Konrad Rudolph May 4 '12 at 8:52
1  
Furthermore, these algorithms are still impractical for de novo sequencing. They’ve solved the sequencing of human genomes only insofar as we have a reference sequence that can be used to map against. But for de novo assembly other algorithms are needed (well, there are some aligners which are based on mapping but stitching the contigs together is a whole ’nother problem). Finally, shameless plug: my bachelor thesis contains a detailed description of the ELAND algorithm. –  Konrad Rudolph May 4 '12 at 8:55
    
Thanks. I edited out the error. The reason I started by describing the fixed-length array was because it's easy to understand. Suffix arrays and BWT are a bit harder to grasp, but actually we do sometimes want to use an index with different values of k. For example, STAR uses suffix arrays to efficiently find spliced alignments. This is of course useful for aligning RNA to the genome. –  Sten L May 4 '12 at 9:16

I contest that choice B is closer to the test string, as it's only 4 characters(and 2 deletes) from being the original string. Whereas you see C as closer because it includes both brown and red. It would, however, have a greater edit distance.

There is an algorithm called Levenshtein Distance which measures the edit distance between two inputs.

Here is a tool for that algorithm.

  1. Rates choice A as a distance of 15.
  2. Rates choice B as a distance of 6.
  3. Rates choice C as a distance of 9.

EDIT: Sorry, I keep mixing strings in the levenshtein tool. Updated to correct answers.

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Ok, I guess that is true. I'll take a look at this. I personally don't care how close it is to the target as long as it is pretty dang close. No need for perfection ;) Points for you until I can verify the results of your answer :) –  Xander May 2 '11 at 16:31

Lua implementation, for posterity:

function levenshtein_distance(str1, str2)
    local len1, len2 = #str1, #str2
    local char1, char2, distance = {}, {}, {}
    str1:gsub('.', function (c) table.insert(char1, c) end)
    str2:gsub('.', function (c) table.insert(char2, c) end)
    for i = 0, len1 do distance[i] = {} end
    for i = 0, len1 do distance[i][0] = i end
    for i = 0, len2 do distance[0][i] = i end
    for i = 1, len1 do
        for j = 1, len2 do
            distance[i][j] = math.min(
                distance[i-1][j  ] + 1,
                distance[i  ][j-1] + 1,
                distance[i-1][j-1] + (char1[i] == char2[j] and 0 or 1)
                )
        end
    end
    return distance[len1][len2]
end
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You might be interested in this blog post.

http://seatgeek.com/blog/dev/fuzzywuzzy-fuzzy-string-matching-in-python

Fuzzywuzzy is a Python library that provides easy distance measures such as Levenshtein distance for string matching. It is built on top of difflib in the standard library and will make use of the C implementation Python-levenshtein if available.

http://pypi.python.org/pypi/python-Levenshtein/

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You might find this library helpful! http://code.google.com/p/google-diff-match-patch/

It is currently available in Java, JavaScript, Dart, C++, C#, Objective C, Lua and Python

It works pretty well too. I use it in a couple of my Lua projects.

And I don't think it would be too difficult to port it to other languages!

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If you're doing this in the context of a search engine or frontend against a database, you might consider using a tool like Apache Solr, with the ComplexPhraseQueryParser plugin. This combination allows you to search against an index of strings with the results sorted by relevance, as determined by Levenshtein distance.

We've been using it against a large collection of artists and song titles when the incoming query may have one or more typos, and it's worked pretty well (and remarkably fast considering the collections are in the millions of strings).

Additionally, with Solr, you can search against the index on demand via JSON, so you won't have to reinvent the solution between the different languages you're looking at.

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A very, very good resource for these kinds of algorithms is Simmetrics: http://sourceforge.net/projects/simmetrics/

Unfortunately the awesome website containing a lot of the documentation is gone :( In case it comes back up again, its previous address was this: http://www.dcs.shef.ac.uk/~sam/simmetrics.html

Voila (courtesy of "Wayback Machine"): http://web.archive.org/web/20081230184321/http://www.dcs.shef.ac.uk/~sam/simmetrics.html

You can study the code source, there are dozens of algorithms for these kinds of comparisons, each with a different trade-off. The implementations are in Java.

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