I'm designing an algorithm to do the following: Given array A[1... n]
, for every i < j
, find all inversion pairs such that A[i] > A[j]
. I'm using merge sort and copying array A to array B and then comparing the two arrays, but I'm having a difficult time seeing how I can use this to find the number of inversions. Any hints or help would be greatly appreciated.



The only advice I could give to this (which looks suspiciously like a homework question ;) ) is to first do it manually with a small set of numbers (e.g. 5), and then write down the steps you took to solve the problem. This should allow you to figure out a generic solution you can use to write the code. 


So here is O(n log n) solution in java.
This is almost normal merge sort, the whole magic is hidden in merge function. Note that while sorting algorithm remove inversions. While merging algorithm counts number of removed inversions (sorted out one might say). The only moment when inversions are removed is when algorithm takes element from the right side of an array and merge it to the main array. The number of inversions removed by this operation is the number of elements left from the the left array to be merged. :) Hope it's explanatory enough. 


I've found it in O(n * log n) time by the following method.
Here’s an example run of this algorithm. Original array A = (6, 9, 1, 14, 8, 12, 3, 2) 1: Merge sort and copy to array B B = (1, 2, 3, 6, 8, 9, 12, 14) 2: Take A[1] and binary search to find it in array B A[1] = 6 B = (1, 2, 3, 6, 8, 9, 12, 14) 6 is in the 4th position of array B, thus there are 3 inversions. We know this because 6 was in the first position in array A, thus any lower value element that subsequently appears in array A would have an index of j > i (since i in this case is 1). 2.b: Remove A[1] from array A and also from its corresponding position in array B (bold elements are removed). A = (6, 9, 1, 14, 8, 12, 3, 2) = (9, 1, 14, 8, 12, 3, 2) B = (1, 2, 3, 6, 8, 9, 12, 14) = (1, 2, 3, 8, 9, 12, 14) 3: Rerun from step 2 on the new A and B arrays. A[1] = 9 B = (1, 2, 3, 8, 9, 12, 14) 9 is now in the 5th position of array B, thus there are 4 inversions. We know this because 9 was in the first position in array A, thus any lower value element that subsequently appears would have an index of j > i (since i in this case is again 1). Remove A[1] from array A and also from its corresponding position in array B (bold elements are removed) A = (9, 1, 14, 8, 12, 3, 2) = (1, 14, 8, 12, 3, 2) B = (1, 2, 3, 8, 9, 12, 14) = (1, 2, 3, 8, 12, 14) Continuing in this vein will give us the total number of inversions for array A once the loop is complete. Step 1 (merge sort) would take O(n * log n) to execute. Step 2 would execute n times and at each execution would perform a binary search that takes O(log n) to run for a total of O(n * log n). Total running time would thus be O(n * log n) + O(n * log n) = O(n * log n). Thanks for your help. Writing out the sample arrays on a piece of paper really helped to visualize the problem. 


In Python



I had a question similar to this for homework actually. I was restricted that it must have O(nlogn) efficiency. I used the idea you proposed of using Mergesort, since it is already of the correct efficiency. I just inserted some code into the merging function that was basically: Whenever a number from the array on the right is being added to the output array, I add to the total number of inversions, the amount of numbers remaining in the left array. This makes a lot of sense to me now that I've thought about it enough. Your counting how many times there is a greater number coming before any numbers. hth. 


Note that the answer by Geoffrey Irving is wrong.
Take the sequence { 3, 2, 1 } as an example. There are three inversions: (3, 2), (3, 1), (2, 1), so the inversion number is 3. However, according to the quoted method the answer would have been 2. 


Check this out: http://www.cs.jhu.edu/~xfliu/600.363_F03/hw_solution/solution1.pdf I hope that it will give you the right answer.



Here is one possible solution with variation of binary tree. It adds a field called rightSubTreeSize to each tree node. Keep on inserting number into binary tree in the order they appear in the array. If number goes lhs of node the inversion count for that element would be (1 + rightSubTreeSize). Since all those elements are greater than current element and they would have appeared earlier in the array. If element goes to rhs of a node, just increase its rightSubTreeSize. Following is the code.






I wonder why nobody mentioned binaryindexed trees yet. You can use one to maintain prefix sums on the values of your permutation elements. Then you can just proceed from right to left and count for every element the number of elements smaller than it to the right:
The complexity is O(n log n), and the constant factor is very low. 


Here is a C code for count inversions
An explanation was given in detail here: http://www.geeksforgeeks.org/countinginversions/ 


Here is c++ solution



Here is O(n*log(n)) perl implementation:



The number of inversions can be found by analyzing the merge process in merge sort : When copying a element from the second array to the merge array (the 9 in this exemple), it keeps its place relatively to other elements. When copying a element from the first array to the merge array (the 5 here) it is inverted with all the elements staying in the second array (2 inversions with the 3 and the 4). So a little modification of merge sort can solve the problem in O(n ln n).



The easy O(n^2) answer is to use nested forloops and increment a counter for every inversion
Now I suppose you want a more efficient solution, I'll think about it. 


I recently had to do this in R:



Java implementation:



Here is my take using Scala:



I think el diablo's answer can be optimized to remove step 2b in which we delete already processed elements. Instead we can define # of inversion for x = position of x in sorted array  position of x in orig array 


Another Python solution, short one. Makes use of builtin bisect module, which provides functions to insert element into its place in sorted array and to find index of element in sorted array. The idea is to store elements left of nth in such array, which would allow us to easily find the number of them greater than nth. Complexity is O(n * log n)



C code easy to understand:



O(n log n) time, O(n) space solution in java. A mergesort, with a tweak to preserve the number of inversions performed during the merge step. (for a well explained mergesort take a look at http://www.vogella.com/tutorials/JavaAlgorithmsMergesort/article.html ) Since mergesort can be made in place, the space complexity may be improved to O(1). When using this sort, the inversions happen only in the merge step and only when we have to put an element of the second part before elements from the first half, e.g.
merged with
we have 3 + 2 + 0 = 5 inversions:
After we have made the 5 inversions, our new merged list is 0, 1, 5, 6, 10, 15, 22 There is a demo task on Codility called ArrayInversionCount, where you can test your solution.



Here's my O(n log n) solution in Ruby:
And some test cases:



Use mergesort, in merge step incremeant counter if the number copied to output is from right array. 


Since this is an old question, I'll provide my answer in C.



In Java Brute force algorithm works faster than piggy backed merge sort algorithm this is because of run time optimization done by Java Dynamic compiler. For Brute force loop rolling optimization will result in much better results. 


One possible solution in C++ satisfying the O(N*log(N)) time complexity requirement would be as follows.
It differs from a regular merge sort only by the counter. 


The number of inversions in an array is half the total distance elements must be moved in order to sort the array. Therefore, it can be computed by sorting the array, maintaining the resulting permutation p[i], and then computing the sum of abs(p[i]i)/2. This takes O(n log n) time, which is optimal. An alternative method is given at http://mathworld.wolfram.com/PermutationInversion.html. This method is equivalent to the sum of max(0, p[i]i), which is equal to the sum of abs(p[i]i])/2 since the total distance elements move left is equal to the total distance elements move to the right. EDIT: This method is wrong (see comments), and there is unfortunately no way to fix it while preserving the character of the method. 


protected by Community♦ May 12 '14 at 12:10
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