# Find a number where it appears exactly N/2 times

Here is one of my interview question. Given an array of N elements and where an element appears exactly N/2 times and the rest N/2 elements are unique. How would you find the element with a better run time?

Remember the elements are not sorted and you can assume N is even. For example,

``````input array [] = { 10, 2, 3, 10, 1, 4, 10, 5, 10, 10 }
``````

So here 10 appears extactly 5 times which is N/2.

I know a solution with O(n) run time. But still looking forward to know a better solution with O(log n).

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You know it to be O(log n)? Or your hope? :P –  Jeremy Powell Jul 28 '09 at 3:11
I was told in the interview, there is a solution with O(log n) :) .. –  Ganesh M Jul 28 '09 at 3:13
But it seems in the worst case it couldn't be better than O(n) –  ZelluX Jul 28 '09 at 3:15
Are you sure we don't know anything else about these elements? Do we even know if they are numbers or could they be arbitrary elements? –  Peter Recore Jul 28 '09 at 3:31
Are we looking for log n best case, worst case, or average case? –  Peter Recore Jul 28 '09 at 3:33

There is a constant time solution if you are ready to accept a small probability of error. Randomly samples two values from the array, if they are the same, you found the value you were looking for. At each step, you have a 0.75 probability of not finishing. And because for every epsilon, there exists one n such that (3/4)^n < eps, we can sample at most n time and return an error if we did not found a matching pair.

Also remark that, if we keep sampling until we found a pair, the expected running time is constant, but the worst case running time is not bounded.

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Usually doesn't big-O imply worst-case? Otherwise this wouldn't be so hard. –  Jeremy Powell Jul 28 '09 at 3:37
You can avoid the unbounded running time by sampling the sets in groups of 3 in array order. See Ganesh M's solution and my refinement. –  Doug Currie Jul 28 '09 at 3:42
if we are ignoring worst case time, then my algorithm, which assumes the first element is the duplicate, finishes in constant time! –  Peter Recore Jul 28 '09 at 3:46
@Peter will it is 50% likely to be right. :) –  cletus Jul 28 '09 at 3:52
@Jeremy: no big-O does not imply worst case. "big-O worst case" implies worst case. The fact that big-O provides an upper bound sometimes makes people think it must be describing the worst case, but this is not so. You can have an asymptotic upper bound on the average case, without that also being an asymptotic upper bound on the worst case. That would then be "big-O average case". –  Steve Jessop Jul 28 '09 at 12:23

Here is my attempt at a proof of why this cannot be done in less than O(n) array accesses (for worst case, which surely is the only interesting case in this example):

Assume a worst case log(n) algorithm exists. This algorithm accesses the array at most log(n) times. Since it can make no assumptions about which elements are where, let me choose which log(n) elements it sees. I will choose to give it the first log(n) unique elements. It has not found the duplicate yet, and there still exist n/2 - log(n) unique elements for me to feed it if need be. In fact, I cannot be forced to feed it a duplicated number until it has read n/2 elements. Therefore such an algorithm cannot exist.

From a purely intuitive standpoint, this just seems impossible. Log(4 billion) is 32. So with an array of 4 billion numbers, 2 billion of which are unique, in no particular order, there is a way to find the duplicated element by only checking 32 elements?

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Remember that O(log.n) doesn't automatically imply that exactly log_2(n) array accesses are required. You can have a*log(n)+b accesses, for constants a and b. [not that I think it's possible either] –  John Fouhy Jul 28 '09 at 4:36
true, my formal proof skills aren't up to the task of proving that if a and b are big enough to actually let you find the duplicated numbers, then they are necessarily proportional to n. –  Peter Recore Jul 28 '09 at 17:04
+1 This is classic proof by feeding worst case numbers. –  Kirill V. Lyadvinsky Sep 3 '09 at 12:59
The unspecified problem need not be O(log(n)). If the claim is that it is better than O(n), and you have proven that, by the arrangement of supplied list, that it must perform at least n/2 lookups, then you have claimed that the algorithm is exactly O(n) or worse. –  SingleNegationElimination Feb 1 '10 at 3:41
I think I was using log(n) because that's what the OP specified as a desired target. You are correct that I could have made a stronger statement. In the end it doesn't matter, because Ganesh was apparently (based on his accepted answer) looking for average case performance, not worst case like most of us thought. –  Peter Recore Feb 1 '10 at 5:31

I think you simply need to parse through the array keeping a backlog of two elements. As N/2 are equal and the rest is guaranteed to be distinct there must be one place i in your array where

`a[i] == a[i-1] OR a[i] == a[i-2]`

iterate once through your array and you have complexity of roughly 2*N which should be well inside O(N).

This answer is somewhat similar to the answer by Ganesh M and Dougie, but I think a little simpler.

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Just make sure to initialize it correctly, check for the case of fewer than 4 elements, and start the loop at index 2. :-) –  Nosredna Jul 28 '09 at 18:29
Well, indeed, but we are not here because we are surprised by the existence of border cases and loop initialization, aren't we? –  Don Johe Jul 29 '09 at 6:25

For worst-case deterministic behavior, O(N) is correct (I've already seen more than one proof in the previous answers).

However, modern algorithmic theory isn't concerned just with worst-case behavior (that's why there are so many other big-somethings besides big-O, even though lazy programmers in a hurry often use big-O even when what they have in mind is closer to big-theta OR big-omega;-), nor just with determinism (withness the Miller-Rabin primality test...;).

Any random sample of K < N items will show no duplicates with a probabllity that < 2**K -- easily and rapidly reduced to essentially as low as you wish no matter what N is (e.g. you could reduce it to less than the probability that a random cosmic ray will accidentally and undetectably flip a bit in your memory;-) -- this observation hardly requires the creativity Rabin and Miller needed to find their probabilistic prime testing approach;-).

This would make a pretty lousy interview question. Similar less-lousy questions are often posed, often mis-answered, and often mis-remembered by unsuccessful candidates. For example, a typical question might be, given an array of N items, not knowing whether there is a majority item, to determine whether there is one, and which one it is, in O(N) time and O(1) auxiliary space (so you can't just set up a hash table or something to count occurrences of different values). "Moore's Voting Approach" is a good solution (probably the best one) to that worthy interviewing question.

Another interesting variation: what if you have `10**18` 64-bit numbers (8 Terabytes' worth of data overall, say on a bigtable or clone thereof), and as many machines as you want, each with about 4GB of RAM on a pretty fast LAN, say one that's substantially better than GB ethernet -- how do you shard the problem under those conditions? What if you have to use mapreduce / hadoop? What if you're free to design your own dedicated framework just for this one problem -- could you get better performance than with mapreduce? How much better, at the granularity of back-of-envelope estimation? I know of no published algorithm for THIS variant, so it may be a great test if you want to check general facility of a candidate with highly-distributed approaches to tera-scale computation...

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You can't do this in sublinear time because you need to read the array. To process an array of a million records in logarithmic time would require only reading ~20 (log2) elements--clearly impossible. After all if you assume the first duplicate found is repeated N/2 times it's still O(n) because you may need to look at 500,001 elements to find a duplicate.

You can do this in O(n) if you assume the integers are nonnegative. It goes like this (pseudo-Java):

``````int repeatedNumber = -1; // sentinel value
int count = 0;
BitSet bits = new BigSet(); // this bitset needs to have 2^31 bits, roughly 2.1 billion
boolean duplicate = false;
for (int i : elements) {
if (bits[i].isSet()) {
if (repeatedNumber == -1) {
repeatedNumber = i;
count = 1;
} else if (i == repeatedNumber) {
count++;
} else {
System.out.println("Array has more than one repeated element");
duplicate = true;
break;
}
} else {
bits[i].set();
}
}
if (!duplicate && repeatedNumber != -1 && count == elements.length/2) {
System.out.println(repeatedNumber + " occurred " + count + " times. The rest of the elements are unique");
} else {
System.out.println("Not true");
}
``````

A similar method is used to sort an array of unique integers in O(n) (radix sort).

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+1 for good explanation of why this is a bogus question. Perhaps the correct answer is that "You CANNOT have such a solution, here's why" –  Tom Leys Jul 28 '09 at 3:32
If we assume the problem is as described, then we can do without the bitset. 1. Examine the first three elements. If two are the same, you are done. Otherwise, iterate over the remaining list comparing each with the previous. When you find two the same, output and exit. –  John Fouhy Jul 28 '09 at 4:24
You can read an array of N elements in log time, or even constant time, given sufficient parallel process available. See my answer –  beetstra Dec 2 '11 at 17:09

1. Divide N elements into [N/3] parts (i.e) each part will have 3 elements.
2. Now compare these 3 elements among each other. - 3 comparisions
3. Atleast one of the part will have two copies of the same element. Hence the number.

Runtime - O(N)

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Now extrapolate that to a million records and you should see your logic is flawed. The problem with dealing with small numbers (like 10) is that you can make mistakes based on anomalies due to size. Things are often a lot clearer with larger sets. –  cletus Jul 28 '09 at 3:36
Starting from one end of the array, the probability of finding 2 elements in common in each set of 3 is 50%. So, the asymptotic complexity is smaller than O(n). –  Doug Currie Jul 28 '09 at 3:39
It depends on whether we're looking at expected case or worst case. A robust solution can be done in O(n). If you assume the array conforms and any duplicate is the N/2 element then you're basically making assumptions and restating the problem as well as looking at probablistic expected case. –  cletus Jul 28 '09 at 3:42
@cletus - what flaw? Some set of three must have a duplicate, otherwise there aren't N/2 of the same value since there are only N/3 sets. –  Doug Currie Jul 28 '09 at 3:44
Now restate the solution with an array of a million elements. –  cletus Jul 28 '09 at 3:48

Peter is exactly right. Here is a more formal way of restating his proof:

Let set S be a set containing N elements. It is the union of two sets: p, which contains a symbol α repeated N/2 times, and q, which contains N/2 unique symbols ω1..ωn/2. S = p ∪ q.

Assume there is an algorithm that can detect your duplicated number in log(n) comparisons in the worst case for all N > 2. In the worst case means that there does not exist any subset r ⊂ S such that |r| = log2 N where α ∉ r.

However because S = p ∪ q, there are |p| many elements ≠ α in S. |p| = N/2, so ∀ N/2 such that N/2 ≥ log2N, there must exist at least one set r ⊂ S such that |r| = log2N and α ∉ r. This is the case for any N ≥ 3. This contradicts the assumption above, so there cannot be any such algorithm.

QED.

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why downvote this but not explain why? –  Peter Recore Jul 28 '09 at 17:10
I like the approach. In the "Assume there is..." paragraph, I'm not sure your last sentence is 100% sound. In the least, the "a is an element of r" should be more like "a occurs more than once in r". –  Jeremy Powell Jul 28 '09 at 19:22
Also, to nitpick, you should use multisets, as 'sets' connote unique elements. –  Jeremy Powell Jul 28 '09 at 19:22
Make q not contain a. –  Jeremy Powell Jul 28 '09 at 19:29
Ok, yeah. Your 'Assume" paragraph makes a leap in logic from the statement of the algorithm being O(log n) and there being no subset blah blah blah. If this were sound, this would also work if the the problem assumed the elements were sorted (which then DOES make it sublinear). Justify that step and I think you've got a great proof. –  Jeremy Powell Jul 28 '09 at 19:32

To do it less than O(n) you would have to not read all the numbers.
If you know there is a value that satisifies the relationship then you could just sample a small subset an show that only one number appears enough times to meet the relationship. You would have to assume the values are reasonably uniformly distributed

Edit. you would have to read n/2 to prove that such a number existed, but if you knew a number existed and only wanted to find it - you could read sqrt(n) samples

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You don't have to read all the numbers. Ever. Just look at a sample of N/2 + 1 elements and the repeated one is the one you need. That sample will always have the repeated element because of pigeon-hole goodness. –  Jeremy Powell Jul 28 '09 at 3:18
N/2 + 1 is still O(n) –  Doug Currie Jul 28 '09 at 3:20
@Doug Hence the reason this is a comment and not an answer :P –  Jeremy Powell Jul 28 '09 at 3:21
How can you find it with a sample size of sqrt(n). You have to read numbers until you find a repeated value - best case is 2 elements, worst case is n/2 + 2. –  lc. Jul 28 '09 at 3:28
@mgb Could you elaborate on the sqrt answer? What's special about sqrt? –  Jeremy Powell Jul 28 '09 at 3:29

The answer is straightforward.. and can be achieved in worst case (n/2 + 1) comparisons

1. Compare pairwise first (n-2) numbers, that is, compare nos. at 0 and 1, then 2 and 3 and so on... total n/2 -1 comparisons. If we find identical numbers in any of the above comparisons.. we have the repeated number... else:

2. Take any one of the last two remaining numbers (say second last one I took) and compare it with the numbers in the second last pair.. if match occurs..second last no. is the repated one, else last one is the repeated one... in all 2 comparisons.

Total comparisons = n/2 - 1 + 2 =n/2 + 1 (worst case) I dont think there is any O(log n) method to achieve this

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It's fairly simple to see that no O(log n) algorithm exists. Clearly you have to look at the array elements to figure out which is the repeated element, but no matter what order you choose to look at the elements, the first floor(n/2) elements you look at might all be unique. You could simply be unlucky. If that happened, you would have no way of knowing which was the repeated element. Since no algorithm that uses less than floor(n/2) array references or fewer on every run will work, there is definitely no sub-linear algorithm.

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If I'm understanding the problem correctly: all we know about the array is it's length and it has (N/2)+1 unique elements, where 1 element is repeated N/2 times(in no specific order).

I think this suffers a hard limit of O(N) for the solution as you can't really assert (for a generic array) that you've found the number without finding at least 2 of the same number. I dont think there exists a search for an unordered array that can detect a duplicate in O(logN) (please correct me if i'm wrong). You will always need to read at least N/2 +1 elements in the worst case.

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You won't always need to read at least N/2 + 1 elements. The best case is the first two elements are duplicate, which means you read 2 elements. The worst case is the first N/2 + 1 elements are all unique, meaning the (N/2 + 2)th element is the answer, so you'll have to read N/2 + 2 at worst. –  lc. Jul 28 '09 at 3:37
Oops, you're right, I meant in the worst case. YOu're right if the first 2 elements were duplicates we'd be done. –  Falaina Jul 28 '09 at 3:42

Restating my solution from a comment to Ganesh's version so I can format it:

``````for (i=0; i<N-2; i+=3) {
if a[i] == a[1+1] || a[i] == a[i+2] return a[i];
if a[i+1] == a[i+2] return a[i+1];
}
return a[N-1]; // for very small N
``````

Probability of winning after 1 iteration: 50%

Probability of winning after 2 iterations: 75%

Etc.

Worst case, O(n) time O(1) space.

Note that after N/4 iterations you've used up all the N/2 unique numbers, so this loop will never iterate through more than 3/4 of the array if it is as specified.

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Doesn't work on an array of 4 elements if the second match appears in the last position. Why look at three at once -- why not two? –  hughdbrown Jul 28 '09 at 4:40
Thanks, changed last line to return a[N-1] -- that fixes the N=4 case and a few others for N<12. I think N=5 is the only special case now. Re 3 vs 2: Looking at pairs rather than triples doesn't work if the values are perfectly distributed (even values random, odd values X, or visa versa). –  Doug Currie Jul 28 '09 at 7:17

Suppose you have a python algorithm like this:

``````import math
import random

def find_duplicate(arr, gap):
cost, reps = 0, 0
while True:
indexes = sorted((random.randint(0,len(arr)-i-1) for i in xrange(gap)), reverse=True)
selection = [arr.pop(i) for i in indexes]
selection_set = set(selection)
cost += len(selection)
reps += 1
if len(selection) > len(selection_set):
return cost, reps
``````

The idea is that arr is your set of values and gap is the log base-2 of the size. Each time you select gap elements and see if there are duplicated values. If so, return your cost (in count of elements examined) and the number of iterations (where you examine log2(size) elements per iteration). Otherwise, look at another gap-sized set.

The problem with benchmarking this algorithm is that the creation of the data each time through the loop and alteration of the data is expensive, assuming a large amount of data. (Initially, I was doing 1 000 000 elements with 10 000 000 iterations.)

So let's reduce to an equivalent problem. The data is passed in as n/2 unique elements and n/2 repeated elements. The algorithm picks the random indexes of log2(n) elements and checks for duplicates. Now we don't even have to create the data and to remove elements examined: we can just check if we have two or more indexes over the halfway point. Select gap indexes, check for 2 or more over the halfway point: return if found, otherwise repeat.

``````import math
import random

def find_duplicate(total, half, gap):
cost, reps = 0, 0
while True:
indexes = [random.randint(0,total-i-1) for i in range(gap)]
cost += gap
reps += 1
above_half = [i for i in indexes if i >= half]
if len(above_half) >= 2:
return cost, reps
else:
total -= len(indexes)
half -= (len(indexes) - len(above_half))
``````

Now drive the code like this:

``````if __name__ == '__main__':
import sys
import collections
import datetime
for total in [2**i for i in range(5, 21)]:
half = total // 2
gap = int(math.ceil(math.log10(total) / math.log10(2)))
d = collections.defaultdict(int)
total_cost, total_reps = 0, 1000*1000*10
s = datetime.datetime.now()
for _ in xrange(total_reps):
cost, reps = find_duplicate(total, half, gap)
d[reps] += 1
total_cost += cost
e = datetime.datetime.now()
print "Elapsed: ", (e - s)
print "%d elements" % total
print "block size %d (log of # elements)" % gap
for k in sorted(d.keys()):
print k, d[k]
average_cost = float(total_cost) / float(total_reps)
average_logs = average_cost / gap
print "Total cost: ", total_cost
print "Average cost in accesses: %f" % average_cost
print "Average cost in logs: %f" % average_logs
print
``````

If you try this test, you'll find that the number of times the algorithm has to do multiple selections declines with the number of elements in the data. That is, your average cost in logs asymptotically approaches 1.

``````elements    accesses    log-accesses
32          6.362279    1.272456
64          6.858437    1.143073
128         7.524225    1.074889
256         8.317139    1.039642
512         9.189112    1.021012
1024        10.112867   1.011287
2048        11.066819   1.006075
4096        12.038827   1.003236
8192        13.022343   1.001719
16384       14.013163   1.000940
32768       15.007320   1.000488
65536       16.004213   1.000263
131072      17.002441   1.000144
262144      18.001348   1.000075
524288      19.000775   1.000041
1048576     20.000428   1.000021
``````

Now is this an argument for the ideal algorithm being log2(n) in the average case? Perhaps. It certainly is not so in the worst case.

Also, you don't have to pick log2(n) elements at once. You can pick 2 and check for equality (but in the degenerate case, you will not find the duplication at all), or check any other number greater for duplication. At this point, all the algorithms that select elements and check for duplication are identical, varying only in how many they pick and how they identify duplication.

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If you are told that the element you are looking for is the non-unique one surely the quickest way to do it is to iterate along the array until you find two the same and then return that element and stop looking. At most you have to search half the array.

I think this is O(n) so I guess it doesn't really help.

It seems too simple so I think I don't understand the problem correctly.

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This solution is O(n^2) because as you read each number you have to compare it to all the previous numbers. –  Tom Leys Jul 28 '09 at 3:31
@Tom Leys - Not if you store the numbers in a hash table as you go. –  lc. Jul 28 '09 at 3:34
@Tom good point. But maybe its just O(n log n) since you can create a sorted tree to find duplicates. –  Jeremy Powell Jul 28 '09 at 3:34
@lc ah. hash would definitely have to have no collisions. otherwise it degenerates –  Jeremy Powell Jul 28 '09 at 3:35
A bitset with 2^31 elements can be stored in ~67 million 32 bit ints or ~270M of storage. That's entirely doable. –  cletus Jul 28 '09 at 3:44

Here is Don Johe's answer in Ruby:

``````#!/usr/bin/ruby1.8

def find_repeated_number(a)
return nil unless a.size >= 3
(0..a.size - 3).each do |i|
[
[0, 1],
[0, 2],
[1, 2],
].each do |j1, j2|
return a[i + j1] if a[i + j1] == a[i + j2]
end
end
end

p find_repeated_number([1, 1, 2])   # => 1
p find_repeated_number([2, 3, 2])   # => 1
p find_repeated_number([4, 3, 3])   # => 1
``````

O(n)

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Algorithm `RepeatedElement(a, n)`

``````while (true) do
{
i=Random() mod n+1; j=Random() mod n+1;
// i and j are random numbers in the range [1,n]
if ((i ≠ j) and a[i]=a[j])) then return;
}
``````
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Similar to http://stackoverflow.com/a/1191881/199556 explanation.

Let's compare 3 elements(3 comparison operation) in worse case "same" element will appear once. So we reduce the tail by 3 and reduce count of "same" elements by one.

In final step(after k iterations) our tail will contain (n/2) - k "same" elements. Let's compare the length of the tail.

On the one hand it will n-3k on the other hand (n/2) - k + 1. Last unsame elements may exist.

n-3k = (n/2) - k + 1

k = 1/4*(n-2)

After k iterations we'll surely get result.

Number of comparisons 3/4*(n-2)

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First off, it's past my bed time and I should know better than to post code in public without trying it first, yada, yada. I hope the criticism I'll get will at least be educational. :-)

I believe the problem can be restated as: "Find the number that occurs more than once."

In the absolute worst case, we would need to iterate through a little more than half the list (1 + N/2) before we found the 2nd instance of a non-unique number.

Worst case example: array [] = { 1, 2, 3, 4, 5, 10, 10, 10, 10, 10 }

On average though, we'd only need to iterate though 3 or 4 elements since half of the elements will contain the non-unique number i.e roughly every other number.

Perfectly even distribution examples:

• array [] = { 1, 10, 2, 10, 3, 10, 4, 10, 5, 10 }
• array [] = { 10, 1, 10, 2, 10, 3, 10, 4, 10, 5 }

In other words even if N = 1 million you would still only need to search; on average, the first 3 or 4 elements before you discovered a duplicate.

What's the big O notation for a fixed/constant runtime that doesn't increase with N?

Code:

``````int foundAt = -1;

for (int i=0; (i<N) && (foundAt==-1); i++)
{
for (int j=i+1; j<N; j++)
{
if (array[i] == array[j])
{
foundAt = i;
break;
}
}
}

int uniqueNumber = array[foundAt];
``````
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This is an O(nn) algorithm, right? Change your inner loop to an exchange and you have an insertion sort, a known O(nn) sorting algorithm. –  hughdbrown Jul 28 '09 at 4:50
Constant runtime is O(1). But big-O is about worst-case. That's why everyone's saying this is O(n). You can't make statements like "on average, the first 3 or 4 elements" without knowing something about the distribution of numbers. [Incidentally, your solution is O(n^2).] –  John Fouhy Jul 28 '09 at 4:54

This is a poor interview question.

1. You don't know the answer yourself.
2. It doesn't have any business case behind it, so you will have difficulty explaining it to the candidate.

Mostly because of the first one. What are you looking for? That the candidate should come up with this O(log n) solution you don't know exists? If you have to ask StackOverflow, is this something you can reasonably expect a candidate to come up with in an interview?

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This is an interview question he was asked, not one he gave. –  Jeremy Stein Jul 28 '09 at 14:43
Sorry Kevin, I didn't ask this question, I was asked by the interviewers .. –  Ganesh M Jul 28 '09 at 15:51
This is a poor SO answer. I think the purpose of SO is to ask questions one doesn't know the answer to. While it's fun to ask everyone a neat question and then post the right answer, that's definitely not required. I imagine most of the SO community would have asked this question if they were in Ganesh's shoes. –  Jeremy Powell Jul 28 '09 at 19:46
Jeremy, it's a perfectly fine answer to the question I thought was being asked. Sorry for providing an answer before the comments clarified what question it was. In an interview, it's important to know what you are looking for in an answer. –  Kevin Peterson Jul 29 '09 at 1:10

Contrary to answers above, there is a solution with worst case behavior as requested, O(log n) RUN TIME. The problem is not to find a solution with O(log N) comparisons worst case (which is impossible), but to do it O(log N) time.

If you can do N comparisons in parallel, the solution is a trivial divide-and-conquer. Not very practical in the real world, but it's an interview question, not a real-world problem.

Update: I think you can do it in constant time with O(N) processors

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I think you have just redefined what is meant when people talk about big o notation. Normally you are not allowed to cheat by giving yourself processing capabilities that scale with your problem size. –  Peter Recore Dec 2 '11 at 19:04
@PeterRecore, I don't think I redefined it; check igoro.com/archive/big-oh-in-the-parallel-world and the paragraph on parallelization of Quicksort in en.wikipedia.org/wiki/Quicksort#Parallelization –  beetstra Dec 3 '11 at 13:54
OK, maybe we should say you are exploiting a loophole in a poorly specified question. Both of your links treat parallel performance as an add on, non normal thing. Normally, when someone asks for big O runtime, the assumption is that they want it for a non parallel conventional processor. Not a N processor system, and not a system with a quantum math daughterboard, and not a system powered by dilithium crystals and positronic neural networks. Yes, a thorough question would have mentioned that all these things are not allowed. But surely that would get tedious? –  Peter Recore Dec 5 '11 at 0:40
BTW, I am not saying that the parallel question isn't interesting or unimportant. I just think that in this particular case it is not in the spirit of the question. Then again, I think the question is bogus to begin with because it doesn't say whether it wants worst case, best case, average case, nor does it define what it actually wants to measure - comparisons, array accesses, etc. –  Peter Recore Dec 5 '11 at 0:44
@PeterRecore With many interview questions, it's not the answer that is important but the thought process. Bogus questions with insufficient information are just ways to get this started. Asking for details and challenging assumptions are A Good Thing. –  beetstra Dec 5 '11 at 13:46