# Efficient Way to Find Pair Orderings?

Let's say I have three arrays `a`, `b`, and `c` of equal length `N`. The elements of each of these arrays come from a totally ordered set, but are not sorted. I also have two index variables, `i` and `j`. For all `i != j`, I want to count the number of index pairs such that `a[i] < a[j]`, `b[i] > b[j]` and `c[i] < c[j]`. Is there any way this can be done in less than O(N ^ 2) time complexity, for example by creative use of sorting algorithms?

Notes: The inspiration for this question is that, if you only have two arrays, `a` and `b`, you can find the number of index pairs such that `a[i] < a[j]` and `b[i] > b[j]` in O(N log N) with a merge sort. I'm basically looking for a generalization to three arrays.

For simplicity, you may assume that no two elements of any array are equal (no ties).

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Are you wanting a single array when this algorithm finishes? E.g. an array which stores all elements from `a`, `b` and `c` in a sorted order? – Davidann Jan 19 '11 at 18:31
Could you give an example of what a "well-defined total ordering" is? – Davidann Jan 19 '11 at 18:33
A total ordering on a set holds antisymmetry, transitivity, and totality; see the Wiki article for more info. en.wikipedia.org/wiki/Total_order – Tim Jan 19 '11 at 18:42
@David: the elements in the arrays are members of a totally ordered set, i.e. they can be sorted, but are not. – Fred Foo Jan 19 '11 at 19:31
@David, sorry, I should have said "for each array, the elements are members of some totally ordered set". However, @dsimcha's wording is the more usual way of expressing this. – Fred Foo Jan 19 '11 at 19:45