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I'm having a hard time solving this problem.

A[1..n] is an array of real numbers which is partially sorted:
There are some p,q  (1 <= p <= q <=n) so:
A[1] <= ... <= A[p]
A[p] >= ... >= A[q]
A[q] <= ... <= A[n]

How can we find a value in this array in O(lgn)?
(You can assume that the value exists in the array)
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Your problem is similar to searching in an array that is increasing and then decreasing. stackoverflow.com/q/17351325/56778 might be helpful. –  Jim Mischel Jul 8 '13 at 22:27
@JimMischel This is a very different problem! –  ElKamina Jul 9 '13 at 0:00

3 Answers 3

up vote 7 down vote accepted

Make 3 binary searches: from 1 to p, p to q and q to n. The complexity is still O(logn).

Since we don't know p and q:

You cannot solve this problem in logn time. Assume a case where you have a sorted list of positive numbers with one zero mixed in (p+1=q and A[q]=0). This situation satisfies all the criteria you mentioned. Now, the problem of finding where that zero is located cannot be solved in sub O(n) time. Therefore your problem cannot be solved in O(logn) time.

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We don't know p and q. –  Yoni Jul 8 '13 at 23:20
without knowing p and q. It's impossible to find in O(log n). Worst case will be O(n). so you can't rely on any implementation. –  Reddy Jul 9 '13 at 6:28
You are right, thank you. –  Yoni Jul 9 '13 at 7:08

Despite the "buried zero" worst case already pointed out, I would still recommend implementing an algorithm that can often speed things up, depending on p,q. For example, suppose that you have n numbers, and each increasing and decreasing region has size at least k. Then if you check 2^m elements in your array, including the first and last element and the rest of the elements as equally spaced as possible, starting with m=2 and then iteratively increasing m by 1, eventually you will reach m when you find 3 pairs of consecutive elements (A,B),(C,D),(E,F) from left-to-right out of the 2^m elements that you have checked, which satisfy A < B, C > D, E < F (some pairs may share elements). If my back-of-the-envelope calculation is correct, then the worst-case m you will need to achieve this will have you checking no more than 4n/k elements, so e.g. if k=100 you are much faster than checking all n elements. Then you know everything before A and everything after F are increasing sequences, and you can binary search through them. Now, if m got big enough that you checked at least sqrt(n) elements, then you can finish up by doing a brute-force search between A and F and the overall running time will be O(n/k + sqrt(n)). On the other hand, if the final m had you check fewer than sqrt(n) elements, then you can further increase m until you have checked sqrt(n) elements. Then there will be 2 pairs of consecutive checked elements (A,B),(C,D) that satisfy A < B, C > D, and there will also be 2 pairs of consecutive checked elements (W,X),(Y,Z) later in the array that satisfy W > X, Y < Z. Then everything before A is increasing, everything between D and W is decreasing, and everything after Z is increasing. So you can binary search these 3 regions in the array. The remaining part of the array that you haven't entirely searched through has size O(sqrt(n)), so you can use brute-force search the unchecked regions and the overall running time is O(sqrt(n)). Thus the bound O(n/k + sqrt(n)) holds in general. I have a feeling this is worst-case optimal, but I don't have a proof.

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Note that for this solution to work, you need to first scan through the array and collapse consecutive sequences of duplicate values by representing them as just one value (and you can record the number or range of indices that have this value). I.e., you need O(n) pre-processing to make searches achieve the O(n/k + sqrt(n)) running time. Otherwise, e.g. if you have an array of all 1's except for one hidden zero, the solution won't work as fast -- you'll have to check all elements in the worst case. –  user2566092 Jul 12 '13 at 18:16
Or, since you don't know p and q and presumably don't have time to find p and q, then you need to assume that consecutive sequences of duplicates have length O(1). –  user2566092 Jul 12 '13 at 18:40

It's solvable in O(log2n).

  1. if at midpoint the slope is decreasing we're in the p..q range.
  2. if at midpoint the slope is increasing, we're either in 1..p or in q..n range.
    • perform a binary search in 1.. mid point and mid point..n ranges to seek for a value where the slope is decreasing. It will be found only in one of the ranges. Now we know in which of the 1..p and q..n subranges the mid point is located.
  3. repeat the process from (1) for the subrange with the peaks until hitting the p..q range.
  4. find the peaks in the subranges by applying algorithm in Divide and conquer algorithm applied in finding a peak in an array.
  5. perform 3 binary searches in the ranges 1..p, p..q, q..n.

==> Overall complexity is O(log2n).

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If there is one peak, the solution you mentioned works. If there is a peak and a bottom it might not. You say "easily extended" could you please elaborate? –  ElKamina Jul 12 '13 at 18:02
@ElKamina I've elaborated - find one peak (let's say it's p) and search in the subranges 1..p, p..n to find the second one. What is "bottom"? –  icepack Jul 12 '13 at 18:05
How do you find one peak? In that answer you pick a 'mid' and see if it is increasing or decreasing at the 'mid'. If it is increasing you set new 'start' to 'mid'. Otherwise 'end' to 'mid'. And recursively check. Here you cannot do the same. If it is increasing at the mid you cannot be sure that peak is after mid and so on. –  ElKamina Jul 12 '13 at 18:11
This solution doesn't work, look at the counter-example in one of the answers. It's possible that the entire array is increasing positive except for one zero buried somewhere in the array. If you find 2 peaks, you'll just get the last two elements in the array (assuming the zero is not there) and you'll have no information about where the zero is. I think at the very least you are going to need some heavy assumptions to make something like you proposed work. –  user2566092 Jul 12 '13 at 18:11
@ElKamina That's correct. In this case the condition should be the decrease, not increase - this will ensure that the currently checked value is in the p..q range. I agree that the algorithm should be adapted a bit - find the decrease at first and apply the original algorithm after that for the 2 subranges –  icepack Jul 12 '13 at 18:19

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