# Comparison Algorithm

I have 2 arrays (`A` and `B`) that contain similar data with some differences. I would like to return an array of objects that are only in `A` and another array of objects that are only in `B`. So far I have been thinking:

1. Brute force with some optimizations (this is trivial)
2. Sort the arrays and use a binary search.

What are my other options? Any languages/solutions are fair game.

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You could sort both arrays then do a linear scan through both arrays at the same time. This would be an O(nlogn) algorithm for the sort and O(n) for the scan / building of the new arrays.

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I'd stuff array A's elements into a hash table, then iterate over array B doing lookups in the hash table to efficiently determine which elements in B are also in A. Then do the same with B's elements in a hash table while iterating over array A. That would be O(N) throughout.

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Hash tables tend to generate faster algorithms, but ones that usually occupies most memory. Good answer, by the way –  Samuel Carrijo Aug 11 '09 at 3:24

A lot of this is going to depend on what type of data you have. You mention sorting, so I take it the elements are comparable. With sets of size `m` and `n`, this will take `O(m lg m + n lg n)` to sort, and that will dominate. (Asymptotically, it won't matter if you do binary search or walk both lists. Walking both lists should be `O( m + n)`.) Of course, if you are using data with a better sort algorithm available, such as integers with radix-sort, you should be able to get down to `O( m + n)`.

Using sets (as others are suggesting) implicitly suggests using hashing, which will definitely make your problem easier. If you hash all the elements in A ( `O(m)` ) and store all the hashes in a hash set in memory, then hash B ( `O(n)` ) and detect where collisions may occur in the hash set. This becomes a matter for optimization: you have to evaluate a classic speed-memory trade-off. The larger your hash set, the quicker the collision-checks will be. This will run in `O( m + n )`.

It's worth noting that you can prove that any algorithm that does what you ask will run in at least `m + n` time, since all the inputs need to be looked at.

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@David: in comparing sorting versus hash table approaches you also need to consider 1) cost of hash function computation vs cost of comparison (optimized for the not-equals case) and 2) whether the hash function gives a good spread. –  Stephen C Aug 11 '09 at 3:40
@Stephen absolutely! I didn't want to get into those considerations because they tend to require assumptions about the inputs which we don't have. –  David Berger Aug 13 '09 at 0:43

I don't have an implementation or algorithm beyond what's already been said but I thought I would leave this solution in c#/linq for anyone who might find this question and wants to do this:

``````    var a = new int[] { 1, 2, 3, 6, 7, 8, 9, 10 };
var b = new int[] { 1, 2, 3, 4, 5, 6, 7 };

int[] missingFromA = b.Except(a);

{
Console.Write("{0} ", i);
}
Console.WriteLine();
foreach (var i in missingFromA)
{
Console.Write("{0} ", i);
}
``````

This prints:

``````8 9 10
4 5
``````
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Try using Sets. They usually have a difference() method (or something like this) that returns exactly what u want. Simple as that. Once it's language-agnostic, how you create sets or transform the difference into an array is done using general methods.

``````Set A = createSetA();
Set B = createSetB();

Array onlyAElements = transformToArray(A.difference(B));
Array onlyBElements = transformToArray(B.difference(A));
``````

Alternatively, you could sort both arrays, and get both difference arrays at the same time. Something like

``````int aIndex = 0;
int bIndex = 0;

Array aOnly = new Array();
Array bOnly = new Array();

while (aIndex != a.length || bIndex != b.length)
{
if (A[aIndex] == B[bIndex]
{
aIndex++;
bIndex++;
}
else if (A[aIndex] > B[bIndex])
{
aIndex++;
}
else
{