# Calculating the similarity of two lists

I have two lists:

eg. a = [1,8,3,9,4,9,3,8,1,2,3] and b = [1,8,1,3,9,4,9,3,8,1,2,3]

Both contain ints. There is no meaning behind the ints (eg. 1 is not 'closer' to 3 than it is to 8).

I'm trying to devise an algorithm to calculate the similarity between two ORDERED lists. Ordered is keyword right here (so I can't just take the set of both lists and calculate their set_difference percentage). Sometimes numbers do repeat (for example 3, 8, and 9 above, and I cannot ignore the repeats).

In the example above, the function I would call would tell me that a and b are ~90% similar for example. How can I do that? Edit distance was something which came to mind. I know how to use it with strings but I'm not sure how to use it with a list of ints. Thanks!

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Considering a string to simply be a list of characters, there would seem to be a pretty simple mapping between calculating edit distance on strings and calculating edit distance on lists of integers. – Chowlett Jul 15 '11 at 15:49
maybe you are looking for the hamming distance? – Pat B Jul 15 '11 at 16:03
@Pat B: Hamming distance requires the sequences to be of the same length, and it can't deal with deletions/insertions. Take a look at the OP's example (`a` and `b`). – NPE Jul 15 '11 at 16:06
@aix: good point. You could zip down the two lists with izip_longest to solve that problem I guess. – Pat B Jul 15 '11 at 16:28

You can use the difflib module

ratio()
Return a measure of the sequences’ similarity as a float in the range [0, 1].

Which gives :

`````` >>> s1=[1,8,3,9,4,9,3,8,1,2,3]
>>> s2=[1,8,1,3,9,4,9,3,8,1,2,3]
>>> sm=difflib.SequenceMatcher(None,s1,s2)
>>> sm.ratio()
0.9565217391304348
``````
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only problem here would be those spaces also end up counting in the percent difference – aerain Jul 15 '11 at 16:49
More reason why you don't want to use this approach: this punishes double-digit integers more than single digit ones and can sometimes confuse single and double (or more) digit numbers. – aerain Jul 15 '11 at 16:56
in fact no (about the spaces) because the SequenceMatcher is smart enough to detect spaces as junk. – kraymer Jul 15 '11 at 16:58
@aerain after checking the doc, SequenceMatcher accept sequences of any type, so I edited the answer to process int lists – kraymer Jul 15 '11 at 17:13
thanks! Ignore my previous comments in this thread now. I actually like this approach the best! – aerain Jul 15 '11 at 17:51

It sounds like edit (or Levenshtein) distance is precisely the right tool for the job.

Here is one Python implementation that can be used on lists of integers: http://hetland.org/coding/python/levenshtein.py

Using that code, `levenshtein([1,8,3,9,4,9,3,8,1,2,3], [1,8,1,3,9,4,9,3,8,1,2,3])` returns `1`, which is the edit distance.

Given the edit distance and the lengths of the two arrays, computing a "percentage similarity" metric should be pretty trivial.

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Yup works great. Thanks! What would you divide the edit distance by to get the percent? Not sure which one of the lists to use – aerain Jul 15 '11 at 17:17
actually I'd recommend the difflib module approach. I didn't know it could be used to compare sequence similarity. – aerain Jul 15 '11 at 17:52

Just use the same algorithm for calculating edit distance on strings if the values don't have any particular meaning.

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One way to tackle this is to utilize histogram. As an example (demonstration with numpy):

``````In []: a= array([1,8,3,9,4,9,3,8,1,2,3])
In []: b= array([1,8,1,3,9,4,9,3,8,1,2,3])

In []: a_c, _= histogram(a, arange(9)+ 1)
In []: a_c
Out[]: array([2, 1, 3, 1, 0, 0, 0, 4])

In []: b_c, _= histogram(b, arange(9)+ 1)
In []: b_c
Out[]: array([3, 1, 3, 1, 0, 0, 0, 4])

In []: (a_c- b_c).sum()
Out[]: -1
``````

There exist now plethora of ways to harness `a_c` and `b_c`.

Where the (seemingly) simplest similarity measure is:

``````In []: 1- abs(-1/ 9.)
Out[]: 0.8888888888888888
``````

Followed by:

``````In []: norm(a_c)/ norm(b_c)
Out[]: 0.92796072713833688
``````

and:

``````In []: a_n= (a_c/ norm(a_c))[:, None]
In []: 1- norm(b_c- dot(dot(a_n, a_n.T), b_c))/ norm(b_c)
Out[]: 0.84445724579043624
``````

Thus, you need to be much more specific to find out most suitable similarity measure suitable for your purposes.

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Unless im missing the point.

``````from __future__ import division

def similar(x,y):
si = 0
for a,b in zip(x, y):
if a == b:
si += 1
return (si/len(x)) * 100

if __name__ in '__main__':
a = [1,8,3,9,4,9,3,8,1,2,3]
b = [1,8,1,3,9,4,9,3,8,1,2,3]
result = similar(a,b)
if result is not None:
print "%s%s Similar!" % (result,'%')
``````
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I think the main issue is that it can't deal with deletions/insertions (it considers the two sequences in this OP's example as 18% similar whereas he is expecting ~90%). – NPE Jul 15 '11 at 16:15
@aix is right here – aerain Jul 15 '11 at 16:48

I've implemented something for a similar task a long time ago. Now, I have only a blog entry for that. It was simple: you had to compute the pdf of both sequences then it would find the common area covered by the graphical representation of pdf.

Sorry for the broken images on link, the external server that I've used back then is dead now.

Right now, for your problem the code translates to

``````def overlap(pdf1, pdf2):
s = 0
for k in pdf1:
if pdf2.has_key(k):
s += min(pdf1[k], pdf2[k])
return s

def pdf(l):
d = {}
s = 0.0
for i in l:
s += i
if d.has_key(i):
d[i] += 1
else:
d[i] = 1
for k in d:
d[k] /= s
return d

def solve():
a = [1, 8, 3, 9, 4, 9, 3, 8, 1, 2, 3]
b = [1, 8, 1, 3, 9, 4, 9, 3, 8, 1, 2, 3]
pdf_a = pdf(a)
pdf_b = pdf(b)
print pdf_a
print pdf_b
print overlap(pdf_a, pdf_b)
print overlap(pdf_b, pdf_a)

if __name__ == '__main__':
solve()
``````

Unfortunately, it gives an unexpected answer, only `0.212292609351`

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