How do I get the probability of a string being similar to another string in Python?

I want to get a decimal value like 0.9 (meaning 90%) etc. Preferably with standard Python and library.


similar("Apple","Appel") #would have a high prob.

similar("Apple","Mango") #would have a lower prob.
  • 13
    I don't think "probability" is quite the right term here. In any event, see stackoverflow.com/questions/682367/…
    – NPE
    Jun 30, 2013 at 7:37
  • 5
    The word you are looking for is ratio, not probability.
    – Inbar Rose
    Jun 30, 2013 at 8:21
  • 4
    Take a look at Hamming distance.
    – Diana
    Jun 30, 2013 at 8:47
  • 5
    The phrase is 'similarity metric', but there are multiple similarity metrics (Jaccard, Cosine, Hamming, Levenshein etc.) said so you need to specify which. Specifically you want a similarity metric between strings; @hbprotoss listed several.
    – smci
    Apr 26, 2018 at 0:56
  • I like the "bigrams" from stackoverflow.com/questions/653157/…
    – MarkHu
    Oct 9, 2020 at 18:59

16 Answers 16


There is a built in.

from difflib import SequenceMatcher

def similar(a, b):
    return SequenceMatcher(None, a, b).ratio()

Using it:

>>> similar("Apple","Appel")
>>> similar("Apple","Mango")
  • 76
    See this great answer comparing SequenceMatcher vs python-Levenshtein module. stackoverflow.com/questions/6690739/…
    – ssoler
    Feb 9, 2015 at 13:06
  • 2
    Interesting article and tool: chairnerd.seatgeek.com/…
    – DevLounge
    Jan 5, 2016 at 19:04
  • 11
    I would highly recommend checking out the whole difflib doc docs.python.org/2/library/difflib.html there is a get_close_matches built in, although i found sorted(... key=lambda x: difflib.SequenceMatcher(None, x, search).ratio(), ...) more reliable, with custom sorted(... .get_matching_blocks())[-1] > min_match checks Sep 15, 2016 at 19:51
  • 3
    @ThorSummoner brings attention to a very useful function (get_closest_matches). It's a convenience function that may be what you are looking for, AKA read the docs! In my particular application I was doing some basic error checking / reporting to the user providing bad input, and this answer allows me to report to them the potential matches and what the "similarity" was. If you don't need to display the similarity, though, definitely check out get_closest_matches
    – svenevs
    Sep 3, 2017 at 22:54
  • This worked perfectly. Simple and effective. Thankyou :) May 9, 2020 at 16:39

Solution #1: Python builtin

use SequenceMatcher from difflib

pros: built-in python library, no need extra package.
cons: too limited, there are so many other good algorithms for string similarity out there.

example :
>>> from difflib import SequenceMatcher
>>> s = SequenceMatcher(None, "abcd", "bcde")
>>> s.ratio()

Solution #2: jellyfish library

its a very good library with good coverage and few issues. it supports:

  • Levenshtein Distance
  • Damerau-Levenshtein Distance
  • Jaro Distance
  • Jaro-Winkler Distance
  • Match Rating Approach Comparison
  • Hamming Distance

pros: easy to use, gamut of supported algorithms, tested.
cons: not a built-in library.


>>> import jellyfish
>>> jellyfish.levenshtein_distance(u'jellyfish', u'smellyfish')
>>> jellyfish.jaro_distance(u'jellyfish', u'smellyfish')
>>> jellyfish.damerau_levenshtein_distance(u'jellyfish', u'jellyfihs')
  • Good answer, jellyfish is great. As of today, jellyfish uses a native library (with pure Python fallback). Jun 17, 2022 at 17:09
  • 1
    jaro_distance is now called jaro_similarity Feb 11 at 19:12

I think maybe you are looking for an algorithm describing the distance between strings. Here are some you may refer to:

  1. Hamming distance
  2. Levenshtein distance
  3. Damerau–Levenshtein distance
  4. Jaro–Winkler distance

TheFuzz is a package that implements Levenshtein distance in python, with some helper functions to help in certain situations where you may want two distinct strings to be considered identical. For example:

>>> fuzz.ratio("fuzzy wuzzy was a bear", "wuzzy fuzzy was a bear")
>>> fuzz.token_sort_ratio("fuzzy wuzzy was a bear", "wuzzy fuzzy was a bear")
  • 2
    updated link github.com/seatgeek/thefuzz Nov 19, 2021 at 10:37
  • Updated the link and package name, thanks.
    – BLT
    Nov 20, 2021 at 11:42
  • TheFuzz is incredible! It does vector distances using character embeddings that are incredibly powerful. It also has traditional string methods, but for doing things like cosine similarity between embedded records, it saves you a great deal of time :)
    – rjurney
    Aug 9, 2022 at 17:02

You can create a function like:

def similar(w1, w2):
    w1 = w1 + ' ' * (len(w2) - len(w1))
    w2 = w2 + ' ' * (len(w1) - len(w2))
    return sum(1 if i == j else 0 for i, j in zip(w1, w2)) / float(len(w1))
  • but similar('appel','apple') is higher than similar('appel','ape')
    – tenstar
    Jun 30, 2013 at 7:46
  • 1
    Your function will compare a given string against other stings. I want a way to return the string with the highest similarity ratio Feb 22, 2017 at 22:55
  • 1
    @SaulloCastro, if self.similar(search_string, item.text()) > 0.80: works for now. Thanks, Feb 22, 2017 at 23:12

Note, difflib.SequenceMatcher only finds the longest contiguous matching subsequence, this is often not what is desired, for example:

>>> a1 = "Apple"
>>> a2 = "Appel"
>>> a1 *= 50
>>> a2 *= 50
>>> SequenceMatcher(None, a1, a2).ratio()
0.012  # very low
>>> SequenceMatcher(None, a1, a2).get_matching_blocks()
[Match(a=0, b=0, size=3), Match(a=250, b=250, size=0)]  # only the first block is recorded

Finding the similarity between two strings is closely related to the concept of pairwise sequence alignment in bioinformatics. There are many dedicated libraries for this including biopython. This example implements the Needleman Wunsch algorithm:

>>> from Bio.Align import PairwiseAligner
>>> aligner = PairwiseAligner()
>>> aligner.score(a1, a2)
>>> aligner.algorithm

Using biopython or another bioinformatics package is more flexible than any part of the python standard library since many different scoring schemes and algorithms are available. Also, you can actually get the matching sequences to visualise what is happening:

>>> alignment = next(aligner.align(a1, a2))
>>> alignment.score
>>> print(alignment)

Package distance includes Levenshtein distance:

import distance
distance.levenshtein("lenvestein", "levenshtein")
# 3

You can find most of the text similarity methods and how they are calculated under this link: https://github.com/luozhouyang/python-string-similarity#python-string-similarity Here some examples;

  • Normalized, metric, similarity and distance

  • (Normalized) similarity and distance

  • Metric distances

  • Shingles (n-gram) based similarity and distance
  • Levenshtein
  • Normalized Levenshtein
  • Weighted Levenshtein
  • Damerau-Levenshtein
  • Optimal String Alignment
  • Jaro-Winkler
  • Longest Common Subsequence
  • Metric Longest Common Subsequence
  • N-Gram
  • Shingle(n-gram) based algorithms
  • Q-Gram
  • Cosine similarity
  • Jaccard index
  • Sorensen-Dice coefficient
  • Overlap coefficient (i.e.,Szymkiewicz-Simpson)


BLEU, or the Bilingual Evaluation Understudy, is a score for comparing a candidate translation of text to one or more reference translations.

A perfect match results in a score of 1.0, whereas a perfect mismatch results in a score of 0.0.

Although developed for translation, it can be used to evaluate text generated for a suite of natural language processing tasks.


import nltk
from nltk.translate import bleu
from nltk.translate.bleu_score import SmoothingFunction
smoothie = SmoothingFunction().method4


print('BLEUscore:',bleu([C1], C2, smoothing_function=smoothie))

Examples: By updating C1 and C2.

C1='Test' C2='Test'

BLEUscore: 1.0

C1='Test' C2='Best'

BLEUscore: 0.2326589746035907

C1='Test' C2='Text'

BLEUscore: 0.2866227639866161

You can also compare sentence similarity:

C1='It is tough.' C2='It is rough.'

BLEUscore: 0.7348889200874658

C1='It is tough.' C2='It is tough.'

BLEUscore: 1.0

The builtin SequenceMatcher is very slow on large input, here's how it can be done with diff-match-patch:

from diff_match_patch import diff_match_patch

def compute_similarity_and_diff(text1, text2):
    dmp = diff_match_patch()
    dmp.Diff_Timeout = 0.0
    diff = dmp.diff_main(text1, text2, False)

    # similarity
    common_text = sum([len(txt) for op, txt in diff if op == 0])
    text_length = max(len(text1), len(text2))
    sim = common_text / text_length

    return sim, diff


TextDistance – python library for comparing distance between two or more sequences by many algorithms. It has Textdistance

  • 30+ algorithms
  • Pure python implementation
  • Simple usage
  • More than two sequences comparing
  • Some algorithms have more than one implementation in one class.
  • Optional numpy usage for maximum speed.


import textdistance
textdistance.hamming('test', 'text')




import textdistance

textdistance.hamming.normalized_similarity('test', 'text')



Thanks and Cheers!!!


There are many metrics to define similarity and distance between strings as mentioned above. I will give my 5 cents by showing an example of Jaccard similarity with Q-Grams and an example with edit distance.

The libraries

from nltk.metrics.distance import jaccard_distance
from nltk.util import ngrams
from nltk.metrics.distance  import edit_distance

Jaccard Similarity

1-jaccard_distance(set(ngrams('Apple', 2)), set(ngrams('Appel', 2)))

and we get:


And for the Apple and Mango

1-jaccard_distance(set(ngrams('Apple', 2)), set(ngrams('Mango', 2)))

and we get:


Edit Distance

edit_distance('Apple', 'Appel')

and we get:


And finally,

edit_distance('Apple', 'Mango')

and we get:


Cosine Similarity on Q-Grams (q=2)

Another solution is to work with the textdistance library. I will provide an example of Cosine Similarity

import textdistance
1-textdistance.Cosine(qval=2).distance('Apple', 'Appel')

and we get:


Adding the Spacy NLP library also to the mix;

def main():
    str1= "Mar 31 09:08:41  The world is beautiful"
    str2= "Mar 31 19:08:42  Beautiful is the world"
    print("NLP Similarity=",nlp(str1).similarity(nlp(str2)))
    print("Diff lib similarity",SequenceMatcher(None, str1, str2).ratio()) 
    print("Jellyfish lib similarity",jellyfish.jaro_distance(str1, str2))

if __name__ == '__main__':

    #python3 -m spacy download en_core_web_sm
    #nlp = spacy.load("en_core_web_sm")
    nlp = spacy.load("en_core_web_md")

Run with Robert Kern's line_profiler

kernprof -l -v ./python/loganalysis/testspacy.py

NLP Similarity= 0.9999999821467294
Diff lib similarity 0.5897435897435898
Jellyfish lib similarity 0.8561253561253562

However the time's are revealing

Function: main at line 32

Line #      Hits         Time  Per Hit   % Time  Line Contents
    32                                           @profile
    33                                           def main():
    34         1          1.0      1.0      0.0      str1= "Mar 31 09:08:41  The world is beautiful"
    35         1          0.0      0.0      0.0      str2= "Mar 31 19:08:42  Beautiful is the world"
    36         1      43248.0  43248.0     99.1      print("NLP Similarity=",nlp(str1).similarity(nlp(str2)))
    37         1        375.0    375.0      0.9      print("Diff lib similarity",SequenceMatcher(None, str1, str2).ratio()) 
    38         1         30.0     30.0      0.1      print("Jellyfish lib similarity",jellyfish.jaro_distance(str1, str2))

Here's what i thought of:

import string

def match(a,b):
    a,b = a.lower(), b.lower()
    error = 0
    for i in string.ascii_lowercase:
            error += abs(a.count(i) - b.count(i))
    total = len(a) + len(b)
    return (total-error)/total

if __name__ == "__main__":
    print(match("pple inc", "Apple Inc."))
  • Python3.6+=

  • No Libuary Imported

  • Works Well in most scenarios

In stack overflow, when you tries to add a tag or post a question, it bring up all relevant stuff. This is so convenient and is exactly the algorithm that I am looking for. Therefore, I coded a query set similarity filter.

def compare(qs, ip):
    al = 2
    v = 0
    for ii, letter in enumerate(ip):
        if letter == qs[ii]:
            v += al
            ac = 0
            for jj in range(al):
                if ii - jj < 0 or ii + jj > len(qs) - 1: 
                elif letter == qs[ii - jj] or letter == qs[ii + jj]:
                    ac += jj
            v += ac
    return v

def getSimilarQuerySet(queryset, inp, length):
    return [k for tt, (k, v) in enumerate(reversed(sorted({it: compare(it, inp) for it in queryset}.items(), key=lambda item: item[1])))][:length]

if __name__ == "__main__":
    print(compare('apple', 'mongo'))
    # 0
    print(compare('apple', 'apple'))
    # 10
    print(compare('apple', 'appel'))
    # 7
    print(compare('dude', 'ud'))
    # 1
    print(compare('dude', 'du'))
    # 4
    print(compare('dude', 'dud'))
    # 6

    print(compare('apple', 'mongo'))
    # 2
    print(compare('apple', 'appel'))
    # 8

    # ['javascript', 'java']


  • compare takes two string and returns a positive integer.
  • you can edit the al allowed variable in compare, it indicates how large the range we need to search through. It works like this: two strings are iterated, if same character is find at same index, then accumulator will be added to a largest value. Then, we search in the index range of allowed, if matched, add to the accumulator based on how far the letter is. (the further, the smaller)
  • length indicate how many items you want as result, that is most similar to input string.

I have my own for my purposes, which is 2x faster than difflib SequenceMatcher's quick_ratio(), while providing similar results. a and b are strings:

    score = 0
    for letters in enumerate(a):
        score = score + b.count(letters[1])

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.