Checking fuzzy/approximate substring existing in a longer string, in Python?

Using algorithms like leveinstein ( leveinstein or difflib) , it is easy to find approximate matches.eg.

``````>>> import difflib
>>> difflib.SequenceMatcher(None,"amazing","amaging").ratio()
0.8571428571428571
``````

The fuzzy matches can be detected by deciding a threshold as needed.

Current requirement : To find fuzzy substring based on a threshold in a bigger string.

eg.

``````large_string = "thelargemanhatanproject is a great project in themanhattincity"
query_string = "manhattan"
#result = "manhatan","manhattin" and their indexes in large_string
``````

One brute force solution is to generate all substrings of length N-1 to N+1 ( or other matching length),where N is length of query_string, and use levenstein on them one by one and see the threshold.

Is there better solution available in python , preferably an included module in python 2.7 , or an externally available module .

---------------------UPDATE AND SOLUTION ----------------

Python regex module works pretty well, though it is little bit slower than inbuilt `re` module for fuzzy substring cases, which is an obvious outcome due to extra operations. The desired output is good and the control over magnitude of fuzziness can be easily defined.

``````>>> import regex
>>> input = "Monalisa was painted by Leonrdo da Vinchi"
>>> regex.search(r'\b(leonardo){e<3}\s+(da)\s+(vinci){e<2}\b',input,flags=regex.IGNORECASE)
<regex.Match object; span=(23, 41), match=' Leonrdo da Vinchi', fuzzy_counts=(0, 2, 1)>
``````
• The `regex` solution does work for the given example. What problem are you having with it? Commented May 31, 2015 at 11:22
• I would name the variable as `txt` or something else, instead of `input` which is a python keyword :).
– arun
Commented Dec 7, 2023 at 1:30

The new regex library that's soon supposed to replace re includes fuzzy matching.

https://pypi.python.org/pypi/regex/

The fuzzy matching syntax looks fairly expressive, but this would give you a match with one or fewer insertions/additions/deletions.

``````import regex
regex.match('(amazing){e<=1}', 'amaging')
``````
• FWIW, the fuzzy matching sadly might be removed for the version intended to be added to the standard library... if it ever actually gets in, that is. Commented May 31, 2015 at 11:26
• I couldn't get this to work with the OP's "manhattan" example -- can you show the code to make that work? Commented Jun 1, 2015 at 17:25
• It's a shame that `regex.match('(test){e<=1}', '123 test')` doesn't match anything Commented Nov 25, 2017 at 17:44
• @AwaisHussain - did you try `regex.search('(test){e<=1}', '123 test')`? I wouldn't expect that match call to return a hit. Commented Sep 18, 2018 at 19:14
• @EthanFurman did you try this? `for m in regex.findall('(manhattan){e<2}', "thelargemanhatanproject is a great project in themanhattincity"): print(m)`. This gives `manhatan` and `manhattin`.
– arun
Commented Dec 7, 2023 at 1:36

The approaches above are good, but I needed to find a small needle in lots of hay, and ended up approaching it like this:

``````from difflib import SequenceMatcher as SM
from nltk.util import ngrams
import codecs

needle = "this is the string we want to find"
hay    = "text text lots of text and more and more this string is the one we wanted to find and here is some more and even more still"

needle_length  = len(needle.split())
max_sim_val    = 0
max_sim_string = u""

for ngram in ngrams(hay.split(), needle_length + int(.2*needle_length)):
hay_ngram = u" ".join(ngram)
similarity = SM(None, hay_ngram, needle).ratio()
if similarity > max_sim_val:
max_sim_val = similarity
max_sim_string = hay_ngram

print max_sim_val, max_sim_string
``````

Yields:

``````0.72972972973 this string is the one we wanted to find
``````
• How do we get the starting index of the substring? Commented Mar 24, 2022 at 17:02
• Not bulletproof, but you could simply use the `find` string method `index = hay.find(max_sim_string)` Commented Oct 6, 2023 at 19:46
• I tested with `needle = "this is the string we want to find"` and `hay = "text text lots of text and this is the string we want to find more"`. Should give a score of 1 since it's a perfect match, but gives a score of 0.944 instead. Commented May 9 at 14:47
• @FranckDernoncourt can you figure out why? Check the needle length vs your ngram length :) Commented May 9 at 23:01

I use fuzzywuzzy to fuzzy match based on threshold and fuzzysearch to fuzzy extract words from the match.

`process.extractBests` takes a query, list of words and a cutoff score and returns a list of tuples of match and score above the cutoff score.

`find_near_matches` takes the result of `process.extractBests` and returns the start and end indices of words. I use the indices to build the words and use the built word to find the index in the large string. `max_l_dist` of `find_near_matches` is 'Levenshtein distance' which has to be adjusted to suit the needs.

``````from fuzzysearch import find_near_matches
from fuzzywuzzy import process

large_string = "thelargemanhatanproject is a great project in themanhattincity"
query_string = "manhattan"

def fuzzy_extract(qs, ls, threshold):
'''fuzzy matches 'qs' in 'ls' and returns list of
tuples of (word,index)
'''
for word, _ in process.extractBests(qs, (ls,), score_cutoff=threshold):
print('word {}'.format(word))
for match in find_near_matches(qs, word, max_l_dist=1):
match = word[match.start:match.end]
print('match {}'.format(match))
index = ls.find(match)
yield (match, index)
``````

To test:

``````query_string = "manhattan"
print('query: {}\nstring: {}'.format(query_string, large_string))
for match,index in fuzzy_extract(query_string, large_string, 70):
print('match: {}\nindex: {}'.format(match, index))

query_string = "citi"
print('query: {}\nstring: {}'.format(query_string, large_string))
for match,index in fuzzy_extract(query_string, large_string, 30):
print('match: {}\nindex: {}'.format(match, index))

query_string = "greet"
print('query: {}\nstring: {}'.format(query_string, large_string))
for match,index in fuzzy_extract(query_string, large_string, 30):
print('match: {}\nindex: {}'.format(match, index))
``````

Output:

``````query: manhattan
string: thelargemanhatanproject is a great project in themanhattincity
match: manhatan
index: 8
match: manhattin
index: 49

query: citi
string: thelargemanhatanproject is a great project in themanhattincity
match: city
index: 58

query: greet
string: thelargemanhatanproject is a great project in themanhattincity
match: great
index: 29
``````
• index = ls.find(match) will only return the first occurrence. Commented May 26, 2020 at 14:32
• Excellent, but currently falls foul of github.com/taleinat/fuzzysearch/issues/13 - so you need to add: `if len(ls) < len(qs): return; yield` (following stackoverflow.com/a/6266586/1021819). Commented Jun 25, 2020 at 13:01
• Note: only works when trying to match one word with another word. Doesn't work for multi-word matches. Commented May 9 at 14:41
• Note: only works when trying to match one word with another word. Doesn't work for multi-word matches. E.g. fail to see the close match with `large_string = "thelargema nhatanproject is " ` and `query_string = "thelarge manhatanproject"`. Commented May 9 at 17:22

How about using `difflib.SequenceMatcher.get_matching_blocks`?

``````>>> import difflib
>>> large_string = "thelargemanhatanproject"
>>> query_string = "manhattan"
>>> s = difflib.SequenceMatcher(None, large_string, query_string)
>>> sum(n for i,j,n in s.get_matching_blocks()) / float(len(query_string))
0.8888888888888888

>>> query_string = "banana"
>>> s = difflib.SequenceMatcher(None, large_string, query_string)
>>> sum(n for i,j,n in s.get_matching_blocks()) / float(len(query_string))
0.6666666666666666
``````

UPDATE

``````import difflib

def matches(large_string, query_string, threshold):
words = large_string.split()
for word in words:
s = difflib.SequenceMatcher(None, word, query_string)
match = ''.join(word[i:i+n] for i, j, n in s.get_matching_blocks() if n)
if len(match) / float(len(query_string)) >= threshold:
yield match

large_string = "thelargemanhatanproject is a great project in themanhattincity"
query_string = "manhattan"
print list(matches(large_string, query_string, 0.8))
``````

Above code print: `['manhatan', 'manhattn']`

• How to retrieve the fuzzily matched substring from the blocks ? eg "manhatan" Commented Jul 19, 2013 at 9:27
• @DhruvPathak, `a = "thelargemanhatanproject"; b = "manhattan"; s = difflib.SequenceMatcher(None, a, b); ''.join(a[i:i+n] for i, j, n in s.get_matching_blocks() if n)` Commented Jul 19, 2013 at 9:36
• it does not extract "manhatan" from the large_string, it results in the query_string "manhattan" (double t) Commented Jul 19, 2013 at 13:45
• @DhruvPathak, ?? The code in my comment yield `'manhatan'`. (single t) Commented Jul 19, 2013 at 13:50
• Can your code be extended to give multiple substrings too, as shown in the example edit in my quetsion ? Commented Jul 19, 2013 at 18:26

Recently I've written an alignment library for Python: https://github.com/eseraygun/python-alignment

Using it, you can perform both global and local alignments with arbitrary scoring strategies on any pair of sequences. Actually, in your case, you need semi-local alignments as you don't care for the substrings of `query_string`. I've simulated semi-local algorithm using local alignment and some heuristics in the following code but it is easy to extend the library for a proper implementation.

Here is the example code in the README file modified for your case.

``````from alignment.sequence import Sequence, GAP_ELEMENT
from alignment.vocabulary import Vocabulary
from alignment.sequencealigner import SimpleScoring, LocalSequenceAligner

large_string = "thelargemanhatanproject is a great project in themanhattincity"
query_string = "manhattan"

# Create sequences to be aligned.
a = Sequence(large_string)
b = Sequence(query_string)

# Create a vocabulary and encode the sequences.
v = Vocabulary()
aEncoded = v.encodeSequence(a)
bEncoded = v.encodeSequence(b)

# Create a scoring and align the sequences using local aligner.
scoring = SimpleScoring(1, -1)
aligner = LocalSequenceAligner(scoring, -1, minScore=5)
score, encodeds = aligner.align(aEncoded, bEncoded, backtrace=True)

# Iterate over optimal alignments and print them.
for encoded in encodeds:
alignment = v.decodeSequenceAlignment(encoded)

# Simulate a semi-local alignment.
if len(filter(lambda e: e != GAP_ELEMENT, alignment.second)) != len(b):
continue
if alignment.first[0] == GAP_ELEMENT or alignment.first[-1] == GAP_ELEMENT:
continue
if alignment.second[0] == GAP_ELEMENT or alignment.second[-1] == GAP_ELEMENT:
continue

print alignment
print 'Alignment score:', alignment.score
print 'Percent identity:', alignment.percentIdentity()
print
``````

The output for `minScore=5` is as follows.

``````m a n h a - t a n
m a n h a t t a n
Alignment score: 7
Percent identity: 88.8888888889

m a n h a t t - i
m a n h a t t a n
Alignment score: 5
Percent identity: 77.7777777778

m a n h a t t i n
m a n h a t t a n
Alignment score: 7
Percent identity: 88.8888888889
``````

If you remove the `minScore` argument, you will get only the best scoring matches.

``````m a n h a - t a n
m a n h a t t a n
Alignment score: 7
Percent identity: 88.8888888889

m a n h a t t i n
m a n h a t t a n
Alignment score: 7
Percent identity: 88.8888888889
``````

Note that all algorithms in the library have `O(n * m)` time complexity, `n` and `m` being the lengths of the sequences.

I ran into this problem, and I found that neither of the top two answers worked. Instead, I used the following algorithm to detect the minimally wrong fuzzy match:

``````def fuzzy_substring_search(cls, major: str, minor: str, errs: int = 4) -> Optional[regex.Match]:
"""Find the closest matching fuzzy substring.

Args:
major: the string to search in
minor: the string to search with
errs: the total number of errors

Returns:
Optional[regex.Match] object
"""
errs_ = 0
s = regex.search(f"({minor}){{e<={errs_}}}", major)
while s is None and errs_ <= errs:
errs_ += 1
s = regex.search(f"({minor}){{e<={errs_}}}", major)
return s
``````

This has the benefit of returning exact matches if they exist, and escalating fuzziness as needed.

• Please do see the update in my question, I could find a module that worked well Commented Aug 30, 2022 at 10:48
• @DhruvPathak I see your solution, and I don't doubt it works for your use case. Commented Sep 2, 2022 at 12:53