# Is there a way to measure how sorted a list is?

Is there is a way to measure how sorted a list is?

I mean, it's not about knowing if a list is sorted or not (boolean), but something like a ratio of "sortness", something like the coefficient of correlation in statistics.

For example,

• If the items of a list are in ascending order, then its rate would be 1.0

• If list is sorted descending, its rate would be -1.0

• If list is almost sorted ascending, its rate would be 0.9 or some value close to 1.

• If the list is not sorted at all (random), its rate would be close to 0

I'm writting a small library in Scala for practice. I think a sorting rate would be useful, but I don't find any information about something like that. Maybe I don't know adequate terms for the concept.

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@TimMedora: Edit distance? That doesn't give -1 for reverse sort, though. –  duskwuff Jun 8 '13 at 0:15
Would this be used to determine the ideal algorithm to sort the list? E.g. for values close to 0, QuickSort would be ideal, but values on either end of the scale (nearly sorted or nearly reverse sorted), MergeSort would be much faster, since QC devolves to O(N^2) in those cases. –  Darrel Hoffman Jun 8 '13 at 14:04
+1 for "ratio of sortess" –  0x499602D2 Jun 8 '13 at 14:17
@Fuhrmanator The stochastic version of the algorithm does not have to perform a sort to arrive at a probabilistic estimate of the sortedness. It's only if you want to get an exact measure that you need to perform a sort. –  Timothy Shields Jun 11 '13 at 20:19
Sarcastic but funny first instinct: You could insertion sort the list and see how long it takes, and then compare that to how long it takes to sort (the now sorted) list and the reverse of it. –  kqr Jun 12 '13 at 0:45

You can simply count the number of inversions in the list.

# Inversion

An inversion in a sequence of elements of type T is a pair of sequence elements that appear out of order according to some ordering < on the set of T's.

From Wikipedia:

Formally, let A(1), A(2), ..., A(n) be a sequence of n numbers.
If i < j and A(i) > A(j), then the pair (i,j) is called an inversion of A.

The inversion number of a sequence is one common measure of its sortedness.
Formally, the inversion number is defined to be the number of inversions, that is,

To make these definitions clearer, consider the example sequence 9, 5, 7, 6. This sequence has the inversions (0,1), (0,2), (0,3), (2,3) and the inversion number 4.

If you want a value between 0 and 1, you can divide the inversion number by N choose 2.

To actually create an algorithm to compute this score for how sorted a list is, you have two approaches:

# Approach 1 (Deterministic)

Modify your favorite sorting algorithm to keep track of how many inversions it is correcting as it runs. Though this is nontrivial and has varying implementations depending on the sorting algorithm you choose, you will end up with an algorithm that is no more expensive (in terms of complexity) than the sorting algorithm you started with.

If you take this route, be aware that it's not as simple as counting "swaps." Mergesort, for example, is worst case O(N log N), yet if it is run on a list sorted in descending order, it will correct all N choose 2 inversions. That's O(N^2) inversions corrected in O(N log N) operations. So some operations must inevitably be correcting more than one inversion at a time. You have to be careful with your implementation. Note: you can do this with O(N log N) complexity, it's just tricky.

# Approach 2 (Stochastic)

• Randomly sample pairs (i,j), where i != j
• For each pair, determine whether list[min(i,j)] < list[max(i,j)] (0 or 1)
• Compute the average of these comparisons and then normalize by N choose 2

I would personally go with the stochastic approach unless you have a requirement of exactness - if only because it's so easy to implement.

If what you really want is a value (z') between -1 (sorted descending) to 1 (sorted ascending), you can simply map the value above (z), which is between 0 (sorted ascending) and 1 (sorted descending), to this range using this formula:

z' = -2 * z + 1

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It's kind of fascinating to me that sorting a list is (typically) O(n*logn), and the naive/obvious method of computing inversions is O(n^2). I wonder if there are better algorithms out there for computing the number of inversions? –  Mark Bessey Jun 8 '13 at 1:48
There are a couple of interesting approaches in this SO question: stackoverflow.com/questions/6523712/… Basically, they amount to sorting the array in order to figure out how many inversions there are. –  Mark Bessey Jun 8 '13 at 1:54
@MarkBessey Thanks for the link! I've incorporated it in the answer. –  Timothy Shields Jun 8 '13 at 1:57
I naively thought you could just count adjacent pairs that are out of order. But that will severely undercount: 1 2 3 1 2 3 only has one adjacent inversion, but it's 50% inverted by the more correct measure. –  Barmar Jun 11 '13 at 19:44
@Barmar I think that list 1 2 3 1 2 3 would qualify as sorta sorted ;-) –  scunliffe Jun 12 '13 at 1:30

The traditional measure of how sorted a list (or other sequential structure) is, is the number of inversions.

The number of inversions is the number of pairs (a,b) st index of a < b AND b << a. For these purposes << represents whatever ordering relation you choose for your particular sort.

A fully sorted list has no inversions, and a completely reversed list has the maximum number of inversions.

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Technically, 5 4 3 2 1 is fully sorted since order isn't specified, but I'm being pedantic :-) –  paxdiablo Jun 8 '13 at 0:38
@paxdiablo That depends on the definition of <. –  Marcin Jun 8 '13 at 0:43
@paxdiablo, well one could measure sortedness by the distance from the number of inversions to the closest of 0 or n choose 2. –  dbaupp Jun 8 '13 at 1:51

I would count comparisons and divide it to the total number of comparisons. Here is a simple Python example.

my_list = [1,4,5,6,9,-1,5,3,55,11,12,13,14]

right_comparison_count = 0

for i in range(len(my_list)-1):
if my_list[i] < my_list[i+1]: # Assume you want to it ascending order
right_comparison_count += 1

if right_comparison_count == 0:
result = -1
else:
result = float(right_comparison_count) / float((len(my_list) - 1))

print result

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There has been great answers, and I would like to add a mathematical aspect for completeness:

• You can measure how sorted a list is by measuring how much it is correlated to a sorted list. To do that, you may use the rank correlation (the most known being Spearman's), which is exactly the same as the usual correlation, but it uses the rank of elements in a list instead of the analog values of its items.

• Many extensions exist, like a correlation coefficient (+1 for exact sort, -1 for exact inversion)

• This allows you to have statistical properties for this measure, like the permutational central limit theorem, which allows you to know the distribution of this measure for random lists.

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I am not sure of the "best" method, but a simple one would be to compare every element with the one after it, incrementing a counter if element2 > element 1 (or whatever you want to test) and then divide by the total number of elements. It should give you a percentage.

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If you take your list, calculate the ranks of the values in that list and call the list of ranks Y and another list, X that contains the integers from 1 to length(Y), you can obtain exactly the measure of sortedness that you are looking for by calculating the correlation coefficient, r, between the two lists.

r = \frac{\sum ^n _{i=1}(X_i - \bar{X})(Y_i - \bar{Y})}{\sqrt{\sum ^n _{i=1}(X_i - \bar{X})^2} \sqrt{\sum ^n _{i=1}(Y_i - \bar{Y})^2}}


For a fully-sorted list, r = 1.0, for a reverse-sorted list, r=-1.0, and the r varies between these limits for varying degrees of sortedness.

A possible problem with this approach, depending on the application, is that calculating the rank of each item in the list is equivalent to sorting it, so it is an O(n log n) operation.

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But that won't ignore the curve shape. If his array is sorted, but, say, contains values increasing exponentially, the correlation will be small where he wants it to be 1.0. –  Lee Daniel Crocker Jun 8 '13 at 0:28
@LeeDanielCrocker: Yes, that's a good point. I've amended my answer to address this by taking ranks of the values. –  Simon Jun 8 '13 at 0:30

#!/usr/bin/python3

def sign(x, y):
if x < y:
return 1
elif x > y:
return -1
else:
return 0

def mean(list_):
return float(sum(list_)) / float(len(list_))

def main():
list_ = [ 1, 2, 3, 4, 6, 5, 7, 8 ]
signs = []
# this zip is pairing up element 0, 1, then 1, 2, then 2, 3, etc...
for elem1, elem2 in zip(list_[:-1], list_[1:]):
signs.append(sign(elem1, elem2))

# This should print 1 for a sorted list, -1 for a list that is in reverse order
# and 0 for a run of the same numbers, like all 4's
print(mean(signs))

main()

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This only counts adjacent inversions. If you look at the other answers you’ll see that this is insufficient. –  Konrad Rudolph Jun 8 '13 at 11:56
@KonradRudolph: I think this answer satisfies the question as asked. The fact that other answers are more comprehensive doesn't mean that this one is insufficient; it depends on the OP's requirements. –  LarsH Jun 8 '13 at 14:52

Apart from inversion count, for numeric lists, mean square distance from the sorted state is imaginable:

#! ruby
d = -> a { a.zip( a.sort ).map { |u, v| ( u - v ) ** 2 }.reduce( :+ ) ** 0.5 }

a = 8, 7, 3, 4, 10, 9, 6, 2, 5, 1
d.( a ) #=> 15.556
d.( a.sort ) #=> 0.0
d.( a.sort.reverse ) # => 18.166 is the worrst case

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I think that's the square of the standard correlation function, see en.wikipedia.org/wiki/Correlation_ratio . And applies equally to non-numeric lists; the two values which are compared are the object's position in the two lists. –  Peter Webb Jun 8 '13 at 9:44
I am a simpleton. I don't even know what correlation ratio is. When I read that Wikipedia article, right at the top, I'm asked to learn what "statistical dispersion" is, then "standard deviation", then "variation", then "interclass correlation coefficient". I learnt all of that, several times, and several times, I forgot it again. In this pragmatic answer of mine, I simply measure the distance between the two vectors with Pythagoras theorem, that I remember from the elementary school, that's all. –  Boris Stitnicky Jun 8 '13 at 23:14

You can use actual correlation.

Suppose that to each item in the sorted list, you assign an integer rank starting from zero. Note that a graph of the elements position index versus rank will look like dots in a straight line (correlation of 1.0 between the position and rank).

You can compute a correlation on this data. For a reverse sort you will get -1 and so on.

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I'm sorry, but this leaves too much unexplained, like how you assign the integers. –  Marcin Jun 8 '13 at 0:56
You need the sorted list to assign the integers; then it is just an enumeration of the items. –  Kaz Jun 8 '13 at 1:08
Exactly what I was going to suggest. Determine the correlation between the position of the object in the original list and its position in the sorted list. The bad news is that correlation routines probably run in O(n^2); the good news is they are probably off-the-shelf for your environment. –  Peter Webb Jun 8 '13 at 9:41
Yeah, just Spearman's rho en.wikipedia.org/wiki/… –  Lucas Jun 8 '13 at 14:52
@PeterWebb Calculating the correlation can be done in O(n). –  Owen Jun 14 '13 at 4:01