# Testing if unsorted sets are disjoint in linear time. (homework problem)

Problem: Two sets A and B have n elements each. Assume that each element is an integer in the range [0, n^100]. These sets are not necessarily sorted. Show how to check whether these two sets are disjoint in O(n) time. Your algorithm should use O(n) space.

My original idea for this problem was to create a hash table of set A and search this hash table for each of the elements in B. However, I'm not aware of any way to create a hash table of a data set with this range that only takes O(n) space. Should I be considering a completely different approach?

UPDATE: I contacted the professor regarding this problem asking about implementing a hash table and his response was: Please note that hashing takes O(1) time for the operations only on an average. We need a worst case O(n) time algorithm for this problem.

So it seems the problem is looking for a different approach...

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Is it definitely [0,n^100], not [0,2^100]? Thing is, the number n^100 has 100 * log n digits. You can't even read n of them in O(n) time, let alone do anything with them. It may be that the question has got itself confused between what `n` means in this question, and what it usually means in complexity analysis (the size of the input in bits). –  Steve Jessop Nov 17 '10 at 18:59
I rechecked the assignment and the range is definitely [0,n^100]. I suppose the problem assumes that a number can be read independently of its magnitude/number of digits. –  ejf071189 Nov 17 '10 at 19:04
Hmm. If the question is assuming that, then perhaps it would allow you to store pointers to the numbers (O(1) space independently of its number of digits) and also compute hashcodes and compare values in O(1) time independently of the number of digits. Ridiculous assumption, but I think that otherwise the question is impossible. –  Steve Jessop Nov 17 '10 at 19:10
Depending on the representation of the number, an effective hashing scheme can use the length of the number, and a few MSBs, LSBs, etc., which would be O(1). –  Axn Nov 17 '10 at 20:06
@Steve, the standard assumpion is that you can perform operations on O(log n) bits in O(1) time. In this case, with the range [0, n^100], the constant hidden by big-O is roughly 100. Kind of weird, but it does fit with the standard assumption. –  jonderry Nov 17 '10 at 20:46

Input: Arrays A[m], B[n]

Output: True if they are disjoint, False otherwise

1. Brute Force: O(m*n) time, O(1) space

``````1. Search for each element of A into B
2. As soon as you get a match break and return false
3. If you reach till end, return true
``````

2. Sort both O(mlogm + nlogn + m + n)

``````1. Sort both arrays
2. Scan linearly
``````

3. Sort smaller O((m + n)logm)

``````1. Say, m < n, sort A
2. Binary search for each element of B into A
``````

4. Sort larger O((m + n)logn)

``````1. Say n > m, sort B
2. Binary search for each element of A into B
``````

5. Hashing O(m + n) time, O(m) or O(n) space

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Why not use a hash table? Aren't they O(n) to create(Assuming they are all unique), then O(n) to search, being O(2n) = O(n)?

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The concern is the space. Since the range ofpossible values is so large, wouldn't the hash table take larger space than O(n)? –  ejf071189 Nov 17 '10 at 18:55
A hash table uses a hash function to reduce the input domain to an appropriate size. –  Gareth Rees Nov 17 '10 at 19:10
I don't have much experience in implementing hash functions. I'm not sure if for the purpose of the problem it would be acceptable to just say that an appropriate hash function is used such that the size of the hash table is O(n), or if I would actually need to outline how the hash function works. –  ejf071189 Nov 17 '10 at 19:15
"Hash tables are constant time and linear space" is a very common assumption, even though it's not strictly true. –  Strilanc Nov 17 '10 at 19:54
@Strilanc: agree, especially since there are so many strategies to implement one. With a domain correctly defined though it should be possible to choose such an implementation I think. –  Matthieu M. Nov 19 '10 at 7:23

A hash set will work fine. It's extremely common to assume hash sets/tables are constant time per operation even though that's not strictly true.

Note that hash sets/tables absolutely only use space proportional to the elements inserted, not the potential total number of elements. You seem to have misunderstood that.

If "commonly assumed to be good enough" is unacceptable for some reason, you can use radix sort. It's linear in the total representation size of the input elements. (Caveat: that's slightly different from being linear in the number of elements.)

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So for implementing a radix sort, if the runtime is O(nk), is there a manipulation to the input that should be done first to lower the key lengths (k), otherwise the average key length could be as high as 100log(n) (base 10), so we'd have O(nlogn), or maybe I'm misunderstanding the description I'm reading on radix sort. –  ejf071189 Nov 17 '10 at 22:45
For instance, could the two methods be combined in such a way that the n elements are hashed into a table of size n with hash function such that the hash value has a set length regardless of the input value, then perform radix sort on the hash table based on the hash values? This seems roundabout, but as noted in the update to the original problem statement, searching the hash set is not applicable as it does not have "worst case" O(1) runtime. –  ejf071189 Nov 17 '10 at 22:50
@ejf071189: Hash values always have a set length, in general they are stored in the native word of the underlying platform, so you can assume 64 bits on most computers. The problem is about collisions, since you are reducing the space used for representation several integers might share the same hash: this is a degenerate case that should be assumed for worst-case analysis, unless you can prove it cannot happen (perfect hash). –  Matthieu M. Nov 19 '10 at 7:32