# How python-Levenshtein.ratio is computed

According to the `python-Levenshtein.ratio` source:

https://github.com/miohtama/python-Levenshtein/blob/master/Levenshtein.c#L722

it's computed as `(lensum - ldist) / lensum`. This works for

``````# pip install python-Levenshtein
import Levenshtein
Levenshtein.distance('ab', 'a') # returns 1
Levenshtein.ratio('ab', 'a')    # returns 0.666666
``````

However, it seems to break with

``````Levenshtein.distance('ab', 'ac')  # returns 1
Levenshtein.ratio('ab', 'ac')     # returns 0.5
``````

I feel I must be missing something very simple.. but why not `0.75`?

• I checked the library (at link you given) I am also confuse why he is using `sum`.Also `(1-1/3) = .666..` this correct according to code but also `(1-1/4) = 0.75` How its .5 ? not clear even in the documentation.... But The actual formula to calculate Levenshtein Distance is in my answer. – Grijesh Chauhan Jan 10 '13 at 17:13

Levenshtein distance for `'ab'` and `'ac'` as below:

so alignment is:

``````  a c
a b
``````

Alignment length = 2
number of mismatch = 1

`Levenshtein Distance` is `1` because only one substitutions is required to transfer `ac` into `ab` (or reverse)

Distance ratio = (Levenshtein Distance)/(Alignment length ) = 0.5

EDIT

you are writing

`(lensum - ldist) / lensum` = `(1 - ldist/lensum)` = 1 - 0.5 = 0.5.

But this is matching (not distance)
REFFRENCE, you may notice its written

`Matching %`

``````p = (1 - l/m) × 100
``````

Where `l` is the `levenshtein distance` and `m` is the `length of the longest of the two` words:

(notice: some author use longest of the two, I used alignment length)

``````(1 - 3/7) × 100 = 57.14...

(Word 1    Word 2    RATIO   Mis-Match   Match%
AB         AB         0       0        (1 - 0/2 )*100  = 100%
CD         AB         1       2        (1 - 2/2 )*100  = 0%
AB         AC        .5       1        (1 - 1/2 )*100  = 50%
``````

Why some authors divide by alignment length,other by max length of one of both?.., because Levenshtein don't consider gap. Distance = number of edits (insertion + deletion + replacement), While Needleman–Wunsch algorithm that is standard global alignment consider gap. This is (gap) difference between Needleman–Wunsch and Levenshtein, so much of paper use max distance between two sequences (BUT THIS IS MY OWN UNDERSTANDING, AND IAM NOT SURE 100%)

Here is IEEE TRANSACTIONS ON PAITERN ANALYSIS : Computation of Normalized Edit Distance and Applications In this paper Normalized Edit Distance as followed:

Given two strings X and Y over a finite alphabet, the normalized edit distance between X and Y, d( X , Y ) is defined as the minimum of W( P ) / L ( P )w, here P is an editing path between X and Y , W ( P ) is the sum of the weights of the elementary edit operations of P, and L(P) is the number of these operations (length of P).

• Thanks for the answer, it makes sense, but it doesn't address the aspect that really bothers me: that the two results (obtained with the same code) don't seem to be consistent with each other (i.e. they suggest two different ways of computing the ratio). How can this be? – cjauvin Jan 11 '13 at 14:38
• @cjauvin Did you read my comment to your question ...I have checked and I have the same impression that according to documentation it should be `.75` but two results in your example are contradicts. – Grijesh Chauhan Jan 11 '13 at 18:34
• Yes I've seen your comment, and that's why, although good and interesting, I cannot accept your answer as the solution, because what I'm really after is the reason for the contradiction in this particular piece of code. Maybe I should ask the PL maintainer. – cjauvin Jan 11 '13 at 19:19
• @cjauvin By the change I am working for you ..I meaning i am looking at that file(u liked)..If in case I find something I will answer you back...give me some time... – Grijesh Chauhan Jan 11 '13 at 19:31
• @cjauvin what is your email id? – Grijesh Chauhan Jan 11 '13 at 19:57

By looking more carefully at the C code, I found that this apparent contradiction is due to the fact that `ratio` treats the "replace" edit operation differently than the other operations (i.e. with a cost of 2), whereas `distance` treats them all the same with a cost of 1.

This can be seen in the calls to the internal `levenshtein_common` function made within `ratio_py` function:

``````static PyObject*
ratio_py(PyObject *self, PyObject *args)
{
size_t lensum;
long int ldist;

if ((ldist = levenshtein_common(args, "ratio", 1, &lensum)) < 0) //Call
return NULL;

if (lensum == 0)
return PyFloat_FromDouble(1.0);

return PyFloat_FromDouble((double)(lensum - ldist)/(lensum));
}
``````

and by `distance_py` function:

``````static PyObject*
distance_py(PyObject *self, PyObject *args)
{
size_t lensum;
long int ldist;

if ((ldist = levenshtein_common(args, "distance", 0, &lensum)) < 0)
return NULL;

return PyInt_FromLong((long)ldist);
}
``````

which ultimately results in different cost arguments being sent to another internal function, `lev_edit_distance`, which has the following doc snippet:

``````@xcost: If nonzero, the replace operation has weight 2, otherwise all
edit operations have equal weights of 1.
``````

Code of lev_edit_distance():

``````/**
* lev_edit_distance:
* @len1: The length of @string1.
* @string1: A sequence of bytes of length @len1, may contain NUL characters.
* @len2: The length of @string2.
* @string2: A sequence of bytes of length @len2, may contain NUL characters.
* @xcost: If nonzero, the replace operation has weight 2, otherwise all
*         edit operations have equal weights of 1.
*
* Computes Levenshtein edit distance of two strings.
*
* Returns: The edit distance.
**/
_LEV_STATIC_PY size_t
lev_edit_distance(size_t len1, const lev_byte *string1,
size_t len2, const lev_byte *string2,
int xcost)
{
size_t i;
``````

So in my example,

`ratio('ab', 'ac')` implies a replacement operation (cost of 2), over the total length of the strings (4), hence `2/4 = 0.5`.

That explains the "how", I guess the only remaining aspect would be the "why", but for the moment I'm satisfied with this understanding.

• The why: a guess, but since the sum of lengths is used in calculation of the ratio: r = (1- d/L)*100 , with d= lev.distance and L=sum of lengths, you need replacement to be 2 to get a ratio of 0 with a complete replacement. e.g. "abcd" -> "dcba" has a ratio of 0 ( = (1-8/8)*100 ) – dstibbe May 28 '19 at 6:17
• Correction: "abcd" -> "xyzw" will result in a ratio of 0, "abcd" -> "dcba" will result in 25, because the distance is 6, not 8. – dstibbe May 28 '19 at 6:42

`(lensum - ldist) / lensum`

ldist is not the distance, is the sum of costs

Each number of the array that is not match comes from above, from left or diagonal

If the number comes from the left he is an Insertion, it comes from above it is a deletion, it comes from the diagonal it is a replacement

The insert and delete have cost 1, and the substitution has cost 2. The replacement cost is 2 because it is a delete and insert

ab ac cost is 2 because it is a replacement

``````>>> import Levenshtein as lev
>>> lev.distance("ab","ac")
1
>>> lev.ratio("ab","ac")
0.5
>>> (4.0-1.0)/4.0    #Erro, the distance is 1 but the cost is 2 to be a replacement
0.75
>>> lev.ratio("ab","a")
0.6666666666666666
>>> lev.distance("ab","a")
1
>>> (3.0-1.0)/3.0    #Coincidence, the distance equal to the cost of insertion that is 1
0.6666666666666666
>>> x="ab"
>>> y="ac"
>>> lev.editops(x,y)
[('replace', 1, 1)]
>>> ldist = sum([2 for item in lev.editops(x,y) if item[0] == 'replace'])+ sum([1 for item in lev.editops(x,y) if item[0] != 'replace'])
>>> ldist
2
>>> ln=len(x)+len(y)
>>> ln
4
>>> (4.0-2.0)/4.0
0.5
``````

Another example:

The cost is 9 (4 replace => 4*2=8 and 1 delete 1*1=1, 8+1=9)

``````str1=len("google") #6
str2=len("look-at") #7
str1 + str2 #13
``````

distance = 5 (According the vector (7, 6) = 5 of matrix)

ratio is (13-9)/13 = 0.3076923076923077

``````>>> c="look-at"
Although there's no absolute standard, normalized Levensthein distance is most commonly defined `ldist / max(len(a), len(b))`. That would yield .5 for both examples.
The `max` makes sense since it is the lowest upper bound on Levenshtein distance: to obtain `a` from `b` where `len(a) > len(b)`, you can always substitute the first `len(b)` elements of `b` with the corresponding ones from `a`, then insert the missing part `a[len(b):]`, for a total of `len(a)` edit operations.
This argument extends in the obvious way to the case where `len(a) <= len(b)`. To turn normalized distance into a similarity measure, subtract it from one: `1 - ldist / max(len(a), len(b))`.