# Why is the Big-O of this algorithm N^2*log N

Fill array a from a[0] to a[n-1]: generate random numbers until you get one that is not already in the previous indexes.

This is my implementation:

``````public static int[] first(int n) {
int[] a = new int[n];
int count = 0;

while (count != n) {
boolean isSame = false;
int rand = r.nextInt(n) + 1;

for (int i = 0; i < n; i++) {
if(a[i] == rand) isSame = true;
}

if (isSame == false){
a[count] = rand;
count++;
}
}

return a;
}
``````

I thought it was N^2 but it's apparently N^2logN and I'm not sure when the log function is considered.

• Looks to me it doesn't have an upper bound in time complexity. You can keep failing to generate a unique number. Can you give a reference where it says this is O(n^2 log n)? Commented Feb 18, 2015 at 20:33
• are we talking about average time? Commented Feb 18, 2015 at 20:34
• Can't say I have much interest in analyzing the big-O of a hideous algorithm for which a trivial O(n) replacement exists. Commented Feb 18, 2015 at 20:41
• This is a textbook probabilistic algorithm, you wouldn't actually implement it
– dfb
Commented Feb 18, 2015 at 20:53
• @rpattiso what if the range over which you are selecting random numbers greatly exceeds the size of a list you are willing to create? Commented Feb 18, 2015 at 21:21

The `0` entry is filled immediately. The `1` entry has probability `1 - 1 / n = (n - 1) / n` of getting filled by a random number. So we need on average `n / (n - 1)` random numbers to fill the second position. In general, for the `k` entry we need on average `n / (n - k)` random numbers and for each number we need `k` comparisons to check if it's unique.

So we need

n * 1 / (n - 1) + n * 2 / (n - 2) + ... + n * (n - 1) / 1

comparisons on average. If we consider the right half of the sum, we see that this half is greater than

n * (n / 2) * (1 / (n / 2) + 1 / (n / 2 - 1) + ... + 1 / 1)

The sum of the fractions is known to be `Θ(log(n))` because it's an harmonic series. So the whole sum is `Ω(n^2*log(n))`. In a similar way, we can show the sum to be `O(n^2*log(n))`. This means on average we need

Θ(n^2*log(n))

operations.

• Now, this is a proper explanation. Commented Feb 19, 2015 at 1:00

This is similar to the Coupon Collector problem. You pick from n items until you get one you don't already have. On average, you have O(n log n) attempts (see the link, the analysis is not trivial). and in the worst case, you examine n elements on each of those attempts. This leads to an average complexity of O(N^2 log N)

• Why? This analysis doesn't have anything to do with the inner loop. The outer loop runs on average O(n lg n) times, The extra n factor is from the inner loop, whether it breaks or not
– dfb
Commented Feb 18, 2015 at 20:44
• "average" "O(n lg n)" uhhh, Big O notation is for the worst case not the average case. =\ Commented Feb 18, 2015 at 23:17
• @corsiKa - Big-O is an asymptotic bound on a function. It's perfectly valid to say that the expected runtime of a function is upper bounded, just like you might bound the worst case runtime.
– dfb
Commented Feb 18, 2015 at 23:35
• There is nothing in the definition of Big-O notation that says it's about the worst case. Tilde notation, which is not widely used, is actually more restrictive; 2x is O(x), but it is not the case that 2x ~ x. Commented Feb 19, 2015 at 0:49
• @JeroenVannevel You are wrong. Commented Feb 19, 2015 at 8:10

The algorithm you have is not `O(n^2 lg n)` because the algorithm you have may loop forever and not finish. Imagine on your first pass, you get some value \$X\$ and on every subsequent pass, trying to get the second value, you continue to get \$X\$ forever. We're talking worst case here, after all. That would loop forever. So since your worst case is never finishing, you can't really analyze.

In case you're wondering, if you know that `n` is always both the size of the array and the upper bound of the values, you can simply do this:

``````int[] vals = new int[n];
for(int i = 0; i < n; i++) {
vals[i] = i;
}
// fischer yates shuffle
for(int i = n-1; i > 0; i--) {
int idx = rand.nextInt(i + 1);
int t = vals[idx];
vals[idx] = vals[i];
vals[i] = t;
}
``````

One loop down, one loop back. `O(n)`. Simple.

• A random number generator that generates the same number every time is not a random number generator. Commented Feb 19, 2015 at 11:07
• @JackAidley a random number generator that cannot generate the same number every time is not a random number generator. (But a PRNG would not have this behaviour). Commented Feb 19, 2015 at 11:50
• David is correct that modern implementations of it would not behave that way, but we can not guarantee it. After all, we're talking about worst possible case, not worst expected case. Commented Feb 19, 2015 at 15:18

If I'm not mistaken, the log N part comes from this part:

``````for(int i = 0; i < count; i++){
if(a[i] == rand) isSame = true;
}
``````

Notice that I changed `n` for `count` because you know that you have only `count` elements in your array on each loop.

• you're gonna need to explain why. Commented Feb 18, 2015 at 20:38
• This would mean the original algorithm is actually N³ Commented Feb 18, 2015 at 20:39
• @rpattiso : dfb pretty much explained it in his answer below. Commented Feb 18, 2015 at 20:44
• @ManuelRamírez, indeed, no reason to revise now, but you posted and i commented before that. Commented Feb 18, 2015 at 20:46