Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm looking for a data structure with which I can find the most frequently occuring number (among an array of numbers) in a given, variable range.

Let's consider the following 1 based array:

1 2 3 1 1 3 3 3 3 1 1 1 1

If I query the range (1,4), the data structure must retun 1, which occurs twice. Several other examples:

(1,13) = 1

(4,9) = 3

(2,2) = 2

(1,3) = 1 (all of 1,2,3 occur once, so return the first/smallest one. not so important at the moment)

I have searched, but could not find anything similar. I'm looking (ideally) a data structure with minimal space requirement, fast preprocessing, and/or query complexities.

Thanks in advance!

share|improve this question
    
Is there a limit on the maximal value that can be in the array ? –  Loïc Février Oct 6 '10 at 16:33
    
Good question. It is better to think that it can either be at most K, or unbounded. So, we can have a better complexity at the more restricted former case(I suppose). –  kolistivra Oct 6 '10 at 19:11

2 Answers 2

You could create a binary partition tree where each node represents a histogram map of {value -> frequency} for a given range, and has two child nodes which represent the upper half and lower half of the range.

Querying is then just a case of recursively adding together a small number of these histograms to cover the range required, and scanning the resulting histogram once to find the highest occurrence count.

Useful optimizations include:

  • Using a histogram with mutable frequency counts as an "accumulator" while you add histograms together
  • Stop using precomputed histograms once you get down to a certain size (maybe a range less than the total number of possible values M) and just counting the numbers directly. It's a time/space trade-off that I think will pay off a lot of the time.
  • If you have a fixed small number of possible values, use an array rather than a map to store the frequency counts at each node

UPDATE: my thinking on algorithmic complexity assuming a bounded small number of possible values M and a total of N values in the complete range:

  • Preprocessing is O(N log N) - basically you need to traverse the complete list and build a binary tree, building one node for every M elements in order to amortise the overhead of each node
  • Querying is O(M log N) - basically adding up O(log N) histograms each of size M, plus counting O(M) values on either side of the range
  • Space requirement is O(N) - approx. 2N/M histograms each of size M. The 2 factor is the sum from having N/M histograms at the bottom level, 0.5N/M histograms at the next level, 0.25N/M at the third level etc...
share|improve this answer
    
Can you provide me with preprocessing and query complexities of your idea? Especially preprocessing seemed high for me... –  kolistivra Oct 10 '10 at 12:30
    
Depends on your data distribution . With M possibles values and N total elements in the array, I think it's M log N for preprocessing and M log N for queries. Space is also M log N. Hence this approach is best (and I believe asymptotically better than all the other solutions posted) in the case that N is very large compared to M. –  mikera Oct 11 '10 at 11:05
    
Sorry meant to say O(N log N) for preprocessing. That's assuming M is small and bounded compared to N of course. –  mikera Oct 11 '10 at 11:14
    
Ahh actually it's harder than I thought because of the amortisation. Updated my latest thinking in the answer. –  mikera Oct 11 '10 at 11:24

Let N be the size of the array and M the number of different values in that array.

I'm considering two complexities : pre-processing and querying an interval of size n, each must be spacial and temporal.


Solution 1 :

  • Spacial : O(1) and O(M)
  • Temporal : O(1) and O(n + M)

No pre-processing, we look at all values of the interval and find the most frequent one.


Solution 2 :

  • Spacial : O(M*N) and O(1)
  • Temporal : O(M*N) and O(min(n,M))

For each position of the array, we have an accumulative array that gives us for each value x, how many times x is in the array before that position.

Given an interval we just need for each x to subtract 2 values to find the number of x in that interval. We iterate over each x and find the maximum value. If n < M we iterate over each value of the interval, otherwise we iterate over all possible values for x.


Solution 3 :

  • Spacial : O(N) and O(1)
  • Temporal : O(N) and O(min(n,M)*log(n))

For each value x build a binary heap of all the position in the array where x is present. The key in your heap is the position but you also store the total number of x between this position and the begin of the array.

Given an interval we just need for each x to subtract 2 values to find the number of x in that interval : in O(log(N)) we can ask the x's heap to find the two positions just before the start/end of the interval and substract the numbers. Basically it needs less space than a histogram but the query in now in O(log(N)).

share|improve this answer
    
Thanks for different solutions, but I'm looking for something with better worst case complexities. +1 for good organization of diverse ideas. –  kolistivra Oct 10 '10 at 12:29
    
What are your constraints in term of space/time ? I admin that O(min(n,M)*log(n)) can still be big, what is the maximum you can do ? –  Loïc Février Oct 10 '10 at 16:43
    
Think of this problem as more of theoretical interest of me, rather than a practical thing. I don't know how best we can get, but I keep on thinking =) –  kolistivra Oct 10 '10 at 16:58
    
Alright ;) I think we can improve time complexity but we'll need more space. If you have a solution with better complexity than mine, I'm interested. –  Loïc Février Oct 10 '10 at 17:40

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.