First of all, write a function called `AreRowsEqual()`

, which compares two rows. So, now, the problem has been restated as `Find similar elements in 3 arrays`

.

Secondly, try to think of a solution that would be the closest to something you already know based on prior knowledge: to find equal elements in two arrays, you need a double nested for loop. So, to find equal elements in three arrays, you would need a triple nested loop, right?

Okay, now, cross this out as a bad, bad, bad solution, because its time complexity is **O(n^3)**. We should be able to do better.

Consider this: in order for an element to be similar in all 3 arrays, first it has to be similar among the first two; then, it has to be similar among the next two. The complexity of such an algorithm will be something akin to **O(x*n)**, where x is the number of arrays. Much better, right? (I cannot figure out precisely what the O() will be, help anyone?) **EDIT:** it turns out it is O((n^2)*(x-1)), which is a lot better than O(n^3) when n > x **--END EDIT** This, incidentally, allows you to forget about the requirement for strictly `3`

arrays and just consider a number of `x`

arrays.

I wrote an approach which received one upvote and then I realized that it was not going to work and I deleted it. This is another try, which I believe will work:

Create a two dimensional array of integers. We will call this 'the matrix'. This matrix will have `x`

columns, and the number of rows will be the number of rows of your first array. (Yes, this will work even if your arrays have differing lengths.) The numbers in the cells of this matrix will be matching row indexes. So, for example, after the algorithm I am describing finishes, a row of `{ 1, 3, 2 }`

in the matrix will tell us that row 1 of the first array matches row 3 of the second array and row 2 of the third array. We will use `-1`

to indicate 'no match'.

So, the first column of the matrix needs to be initialized with the indexes of all rows of your first array, that is, with the numbers `0, 1, 2, ... n`

where `n`

is the number of elements in the first array.

For each additional array, fill its column in the matrix as follows: loop through each row of the current column in the matrix, and compute the cell as follows: if the corresponding cell of the previous column was `-1`

, carry the `-1`

over into this cell. Otherwise, look for a row in the current array which matches the corresponding row of the previous array, and if found, store its index into this cell. Otherwise, store -1 in this cell.

Repeat for all of your arrays, that is, for all the columns in the matrix. In the end, your matching rows are those that do not have a `-1`

in the last column of the matrix.

If you *really* care about efficiency, you can do as John B suggested, and write an immutable class called `Row`

which encapsulates (contains a reference to) a row and implements `hashCode()`

and `equals()`

. `equals()`

here can be implemented using `Arrays.deepEquals()`

. There may also be some goodie in `Arrays`

called `deepHashCode()`

, or else you will need to roll your own.