# Algorithm: Find peak in a circle

Given n integers, arranged in a circle, show an efficient algorithm that can find one peak. A peak is a number that is not less than the two numbers next to it.

One way is to go through all the integers and check each one to see whether it is a peak. That yields O(n) time. It seems like there should be some way to divide and conquer to be more efficient though.

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Is it necessary to know the location of the peak in the circle, or just the integer value of the peak? –  CaptainMurphy Oct 12 '12 at 21:15
Both location and integer are needed. Let's assume that the integers are stored as an array A[1..n] –  Paul S. Oct 12 '12 at 21:17
–  Matthew Strawbridge Oct 12 '12 at 23:09
So a flat line is a peak? 3 3 3 3 3 3 => no element is less than its neighbours –  Skizz May 3 '13 at 9:44

Here's a recursive O(log n) algorithm.

Suppose we have an array of numbers, and we know that the middle number of that segment is no smaller than the endpoints:

A[i] <= A[m] >= A[j]

for i,j indexes into an array, and m=(i+j)/2. Examine the elements midway between the endpoints and the midpoint, i.e. those at indexes x=(3*i+j)/4 and y=(i+3*j)/4. If A[x]>=A[m], then recurse on the interval [i,m]. If A[y]>=A[m], then recurse on the interval [m,j]. Otherwise, recurse on the interval [x,y].

In every case, we maintain the invariant on the interval above. Eventually we get to an interval of size 2 which means we've found a peak (which will be A[m]).

To convert the circle to an array, take 3 equidistant samples and orient yourself so that the largest (or one tied for the largest) is in the middle of the interval and the other two points are the endpoints. The running time is O(log n) because each interval is half the size of the previous one.

I've glossed over the problem of how to round when computing the indexes, but I think you could work that out successfully.

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### EDIT

Well, Keith Randall proved me wrong. :)

Here's Keith's solution implemented in Python:

def findPeak(aBase):
N = len(aBase)
def a(i): return aBase[i % N]

i = 0
j = N / 3
k = (2 * N) / 3
if a(j) >= a(i) and a(j) >= a(k)
lo, candidate, hi = i, j, k
elif a(k) >= a(j) and a(k) >= a(i):
lo, candidate, hi = j, k, i + N
else:
lo, candidate, hi = k, i + N, j + N

# Loop invariants:
# a(lo) <= a(candidate)
# a(hi) <= a(candidate)

while lo < candidate - 1 or candidate < hi - 1:
checkRight = True
if lo < candidate - 1:
mid = (lo + candidate) / 2
if a(mid) >= a(candidate):
hi = candidate
candidate = mid
checkRight = False
else:
lo = mid
if checkRight and candidate < hi - 1:
mid = (candidate + hi) / 2
if a(mid) >= a(candidate):
lo = candidate
candidate = mid
else:
hi = mid

return candidate % N
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A peak always exists even if we allow duplicate numbers (see definition of a peak.) Also, since the problem asks only to find one peak, it might not be necessary that we always have to examine all the numbers. –  Paul S. Oct 12 '12 at 21:08
It is not necessary to ALWAYS examine all the numbers but that's not the point of average case algorithmic runtime –  im so confused Oct 12 '12 at 21:09
@AK4749 You're missing my point. I was saying that rob mayoff's argument is not sufficient to show that an algorithm better than O(N) doesn't exist. –  Paul S. Oct 12 '12 at 21:12
@PaulSeangwongree You're right, a peak always exists since it's defined as “not less than”. Anyway, big-O notation describes the asymptotic upper bound of a function. I demonstrated that the upper bound on the number of elements you examine is N. So the best possible function runs in O(N) time. –  rob mayoff Oct 12 '12 at 21:12
@robmayoff When you say "No matter what order you choose to examine the numbers in, there's an arrangement that puts the peak at the last number you examine", you neglect to consider that the order I choose to examine the numbers may depend on the numbers themselves. (If my algorithm had to examine the numbers in fixed order, then you would be right.) –  Paul S. Oct 12 '12 at 21:16

When you say "arranged in a circle", you mean like in a circular linked list or something? From the way you describe the data set, it sounds like these integers are completely unordered, and there's no way to look at N integers and come to any kind of conclusion about any of the others. If that's the case, then the brute-force solution is the only possible one.

Edit:

Well, if you're not concerned with worst-case time, there are slightly more efficient ways to do it. The naive approach would be to look at Ni, Ni-1, and Ni+1 to see if Ni is a peak, then repeat, but you can do a little better.

While not done
If N[i] < N[i+1]
i++
Else
If N[i]>N[i-1]
Done
Else
i+=2

(Well, not quite that, because you have to deal with the case where N[i]=N[i+1]. But something very similar.)

That will at least keep you from comparing Ni to Ni+1, adding 1 to i, and then redundantly comparing Ni to Ni-1. It's a distinctly marginal gain, though. You're still marching through the numbers, but there's no way around that; jumping blindly is unhelpful, and there's no way to look ahead without taking just as long as doing the actual work would be.

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This is not true; if you determine that n_i is greater than n_(i+1), you do not need to check n_(i+1). It is possible to not check all numbers. This does not change that the algorithm will always have a worst case of linear time, however. –  Stephen Garle Oct 12 '12 at 21:08