# Determining if a sequence T is a sorting of a sequence S in O(n) time

I know that one can easily determine if a sequence is sorted in O(n) time. However, how can we insure that some sequence T is indeed the sorting of elements from sequence S in O(n) time?

That is, someone might have an algorithm that outputs some sequence T that is indeed in sorted order, but may not contain any elements from sequence S, so how can we check that T is indeed a sorted sequence of S in O(n) time?

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If you really mean O() analysis, which is asymptotic in N, there is no O(n) solution to your question. –  Heath Hunnicutt Apr 1 '12 at 21:30

1. Get the length L of S.
2. Check the length of T as well. If they differ, you are done!
3. Let Hs be a hash map with something like 2L buckets of all elements in S.
4. Let Ht be a hash map (again, with 2L buckets) of all elements in T.
5. For each element in T, check that it exists in Hs.
6. For each element in S, check that it exists in Ht.

This will work if the elements are unique in each sequence. See wcdolphin's answer for the small changes needed to make it work with non-unique sequences.

I have NOT taken memory consumption into account. Creating two hashmap of double the size of each sequence may be expensive. This is the usual tradeoff between speed and memory.

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Note that it should be a histogram map:element->int to make sure you handle duplicate elements with still getting O(n). Other than that - nice solution. –  amit Apr 1 '12 at 21:16
-1: Hash maps are not magic and are not O(1). A hash map has the same O() complexity of the collision-handling it employs. If the hash map uses chaining, then building it is O(n^2). If the hash map has a binary tree for each bin's overflow, it is O(log N). This was the issue behind the recent tomcat DoS POST vulnerability. In today's colleges, where Java 'knowledge' is dispensed as CS education, many students are misinformed into believing that hash maps can be used as you describe -- but that is wrong. You have to consider what happens if there is a hash collision. –  Heath Hunnicutt Apr 1 '12 at 21:16
@HeathHunnicutt: You forgot to read the last chapter of them maybe, k is not constant. The load balance is usually ~1/2-1/4, meaning 2n < k < 4n, which decays back to a constant. Rehashin is O(n) - but is done after O(n) OPS, which get back to O(1) amortized per OP –  amit Apr 1 '12 at 21:26
Heath, why are you assuming that the hashmap is full? Who in their right mind will create a hashmap with too few buckets? I would understand your complaints more if you pointed to the (very unlikely) scenario of hash collisions for almost every key or something like that, but with a good hashing function and a large enough hashmap, key collisions should be unlikely. –  Emil Vikström Apr 1 '12 at 21:28
I think you should also consider the count of each element. For example, your solution will answer "Yes" for A = [1, 1, 2] and B = [1, 2, 2], but the answer should be "No". –  Hadi Moshayedi Apr 1 '12 at 22:04

While Emil's answer is very good, you can do slightly better.

Fundamentally, in order for T to be a reordering of S it must contain all of the same elements. That is to say, for every element in T or S, they must occur the same number of times. Thus, we will:

Create a Hash table of all elements in S, mapping from the 'Element' to the number of occurrences.

Iterate through every element in T, decrementing the number of times the current element occurred.

If the number of occurrences is zero, remove it from the hash.

If the current element is not in the hash, T is not a reordering of S.

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-1: belief in magical hash maps. –  Heath Hunnicutt Apr 1 '12 at 21:19
@HeathHunnicutt what do you mean by 'magical hash maps'? This is a standard hash table that could be written by hand, all it requires is that the elements by hashable. Can you elaborate? –  wcdolphin Apr 1 '12 at 22:20
EDIT: (well, not permitted to edit a comment ,but anyways). Great point on the insertion complexity of a hash table! While I think you may have taken things a little bit far for this simple question, it will definitely encourage me to always think twice about asymptotic behavior of hash tables especially. –  wcdolphin Apr 1 '12 at 22:30
This is a good solution when non-unique elements can be present. I've updated my answer to refer to you :-) It's also a little better in memory consumption since it use only one hashmap. Nice! –  Emil Vikström Apr 2 '12 at 8:57

Create a hash map of both sequences. Use the character as key, and the count of the character as value. If a character has not been added yet add it with a count of 1. If a character has already been added increase its count by 1.

Verify that for each character in the input sequence that the hash map of the sorted sequence contains the character as key and has the same count as value.

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-1: belief in magical hash map. –  Heath Hunnicutt Apr 1 '12 at 21:18
huh? That's a pretty random downvote..Hash map is used to for O(1) lookup time, it's not "magic" and this algorithm should work in O(n). Can you explain your downvote? –  BrokenGlass Apr 1 '12 at 21:19
It's explained above. O() is an asymptotic measure. Hash maps devolve to their chaining strategy when evaluating O() complexity, because they are full when N is large. If you allow the hash map to resize, it's also O(N) to resize. –  Heath Hunnicutt Apr 1 '12 at 21:21
Hashmap does not have O(1) look-up time. Hashmap has O(1/k * p(N)) lookup time, where p(N) is the chaining (bin overflow) strategy and 1/k is a constant factor which disappears from O() notation. Hashmaps have average constant run time for N < k, but that is not O() notation. O() notation is for N -> infinity. –  Heath Hunnicutt Apr 1 '12 at 21:27
@HeathHunnicutt: And since usually 2n < k < 4n, and p(n) is linear, it decays back to O(1) [again, on average case, and on amortized analysis] –  amit Apr 1 '12 at 21:29

I believe it this is a O(n^2) problem because:

1. Assuming data structure you use to store elements is a linked list for minimal operations of removing an element
2. You will be doing a S.contains(element of T) for every element of T, and one to check they are the same size.
3. You cannot assume that s is ordered and therefore need to do a element by element comparison for every element.
4. worst case would be if S is reverse of T
5. This would mean that for element (0+x) of T you would do (n-x) comparisons if you remove each successful element.
6. this results in (n*(n+1))/2 operations which is O(n^2)

Might be some other cleverer algorithm out there though

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It's not really O(N^2). You can sort the second list in O(N log N), then compare the two in O(N). So it's an O(N log N) problem. You could also binary search (O log N) the sorted sequence for each element of the second sequence, but you have to be careful about counting the same number of duplicated items -- perhaps replace each matched item from the sort with a sentinel such -1, then this is destructive. It's still O(N log N). –  Heath Hunnicutt Apr 1 '12 at 21:49
Argh! yes, of course you would sort the dam thing first! –  LGW Apr 1 '12 at 22:08