# Get position of subsequence using Levenshtein-Distance

I have a huge number of records containing sequences ('ATCGTGTGCATCAGTTTCGA...'), up to 500 characters. I also have a list of smaller sequences, usually 10-20 characters. I would like to use the Levenshtein distance in order to find these smaller sequences inside the records allowing for small changes or indels (L_distance <=2).

The problem is that I also want to get the start position of such smaller sequences, and apparently it only compares sequences of the same length.

``````>>> import Levenshtein
>>> s1 = raw_input('first word: ')
first word: ATCGTAATACGATCGTACGACATCGCGGCCCTAGC
>>> s2 = raw_input('second word: ')
first word: TACGAT
>>> Levenshtein.distance(s1,s2)
29
``````

In this example I would like to obtain the position (7) and the distance (0 in this case).

Is there an easy way to solve this problem, or do I have to break the larger sequences into smaller ones and then run the Levenshtein distance for all of them? That might take too much time.

Thanks.

UPDATE #Naive implementation generating all substrings after looking for an exact match.

``````def find_tag(pattern,text,errors):
m = len(pattern)
i=0
min_distance=errors+1
while i<=len(text)-m:
distance = Levenshtein.distance(text[i:i+m],pattern)
print text[i:i+m],distance #to see all matches.
if distance<=errors:
if distance<min_distance:
match=[i,distance]
min_distance=distance
i+=1
return match

#Real example. In this case just looking for one pattern, but we have about 50.
import re, Levenshtein

text = 'GACTAGCACTGTAGGGATAACAATTTCACACAGGTGGACAATTACATTGAAAATCACAGATTGGTCACACACACATTGGACATACATAGAAACACACACACATACATTAGATACGAACATAGAAACACACATTAGACGCGTACATAGACACAAACACATTGACAGGCAGTTCAGATGATGACGCCCGACTGATACTCGCGTAGTCGTGGGAGGCAAGGCACACAGGGGATAGG' #Example of a record
pattern = 'TGCACTGTAGGGATAACAAT' #distance 1
errors = 2 #max errors allowed

match = re.search(pattern,text)

if match:
print [match.start(),0] #First we look for exact match
else:
find_tag(pattern,text,errors)
``````
-
I already read that one and it's not fully answered there. How do you get the position? The're just creating substrings as I pointed out in the original question. –  biojl Nov 1 '13 at 11:14
get_matching_blocks docs say: Return list of triples describing matching subsequences. Each triple is of the form (i, j, n), and means that a[i:i+n] == b[j:j+n]. The triples are monotonically increasing in i and j. Won't that give you the position? –  flup Nov 1 '13 at 11:22
Do you need this to be efficient? Would just iterating over sub-strings of each sequence and calculating the L-distance be too slow? –  taleinat Nov 1 '13 at 11:30
I still don't see how can I extract the position from that one-liner. Yes I need an efficient code since I have millions of records and the possible substrings to look for are about 50-60. –  biojl Nov 1 '13 at 11:33

Assuming the maximum Levenshtein distance allowed is small, this can be done in a single-pass while keeping a list of candidates for fuzzy matches.

Here is an example implementation I just worked up. It's not thoroughly tested, documented or optimized. But at least it works for simple examples (see below). I've tried to avoid having it return several matches due to skipping characters at the edges of the sub-sequence, but as I've said, I haven't thoroughly tested this.

If you're interested I'll be happy to clean this up, write some tests, do basic optimization and make this available as an open-source library.

``````from collections import namedtuple

Candidate = namedtuple('Candidate', ['start', 'subseq_index', 'dist'])
Match = namedtuple('Match', ['start', 'end', 'dist'])

def find_near_matches(subsequence, sequence, max_l_dist=0):
prev_char = None
candidates = []
for index, char in enumerate(sequence):
for skip in range(min(max_l_dist+1, len(subsequence))):
candidates.append(Candidate(index, skip, skip))
if subsequence[skip] == prev_char:
break
new_candidates = []
for cand in candidates:
if char == subsequence[cand.subseq_index]:
if cand.subseq_index + 1 == len(subsequence):
yield Match(cand.start, index + 1, cand.dist)
else:
new_candidates.append(cand._replace(
subseq_index=cand.subseq_index + 1,
))
else:
if cand.dist == max_l_dist or cand.subseq_index == 0:
continue
# add a candidate skipping a sequence char
new_candidates.append(cand._replace(dist=cand.dist + 1))
# try skipping subsequence chars
for n_skipped in range(1, max_l_dist - cand.dist + 1):
if cand.subseq_index + n_skipped == len(subsequence):
yield Match(cand.start, index + 1, cand.dist + n_skipped)
break
elif subsequence[cand.subseq_index + n_skipped] == char:
# add a candidate skipping n_skipped subsequence chars
new_candidates.append(cand._replace(
dist=cand.dist + n_skipped,
subseq_index=cand.subseq_index + n_skipped,
))
break
candidates = new_candidates
prev_char = char
``````

Now:

``````>>> list(find_near_matches('bde', 'abcdefg', 0))
[]
>>> list(find_near_matches('bde', 'abcdefg', 1))
[Match(start=1, end=5, dist=1), Match(start=3, end=5, dist=1)]
>>> list(find_near_matches('cde', 'abcdefg', 0))
[Match(start=2, end=5, dist=0)]
>>> list(find_near_matches('cde', 'abcdefg', 1))
[Match(start=2, end=5, dist=0)]
>>> match = _[0]
>>> 'abcdefg'[match.start:match.end]
'cde'
``````

EDIT:

Following this question, I'm writing a Python library for searching for nearly matching sub-sequences: `fuzzysearch`. It it still very much a work-in-progress.

For now, try the `find_near_matches_with_ngrams()` function! It should perform particularly well in your use-case.

-
Hi @taleinat, this is great! Usually we expect to find the small sequences in the records without any modifications (distance = 0) or very few (1 or 2). I'm updating the question with the naive code I generated. I would like know how much faster is your solution. And it will be great to have a library, there's more people interested in this algorithm. –  biojl Nov 1 '13 at 14:15
>>> list(find_near_matches(pattern,text,1)) [Match(start=3, end=24, dist=1), Match(start=5, end=24, dist=1)] In this case the real one is the first one, as you expect to find the whole pattern, not a piece. –  biojl Nov 4 '13 at 9:38
Well, that's an example of issues with the edge of the subsequence. What if the entire subsequence is there except the first letter? The second match is just as valid as the first if your only criterion is Levenshtein distance. In any case, I'm still working on this, and will add filtering out of such duplicate matches, returning only the "best" one. –  taleinat Nov 5 '13 at 13:40
You're right. I've noticed that my solution (and yours) fail to localize cases when a insertion/deletion is longer than 1 character. I'm putting the -- where the indel should be. i.e. `ATCTATCGTTTACGG ATCTAT--TTTACGGCCGTAGCTAGCTGACTGATCGTA` –  biojl Nov 5 '13 at 14:30
As mentioned in my edit of the answer, I've published a Python module called `fuzzysearch` with relevant functionality. –  taleinat Mar 12 '14 at 11:13