# find nth prime number

I've written the following code below to find the nth prime number. Can this be improved in time complexity?

Description:

The ArrayList arr stores the computed prime numbers. Once arr reaches a size 'n', the loop exits and we retrieve the nth element in the ArrayList. Numbers 2 and 3 are added before the prime numbers are calculated, and each number starting from 4 is checked to be prime or not.

``````public void calcPrime(int inp) {
ArrayList<Integer> arr = new ArrayList<Integer>(); // stores prime numbers
// calculated so far
// add prime numbers 2 and 3 to prime array 'arr'
arr.add(2);
arr.add(3);

// check if number is prime starting from 4
int counter = 4;
// check if arr's size has reached inp which is 'n', if so terminate while loop
while(arr.size() <= inp) {
// dont check for prime if number is divisible by 2
if(counter % 2 != 0) {
// check if current number 'counter' is perfectly divisible from
// counter/2 to 3
int temp = counter/2;
while(temp >=3) {
if(counter % temp == 0)
break;
temp --;
}
if(temp <= 3) {
arr.add(counter);
}
}
counter++;
}

System.out.println("finish" +arr.get(inp));
}
}
``````
• Please give us an intuitive description of what your program does, or at least provide comments. Giving us a block of code and asking us to analyze it makes it extremely difficult for anyone to figure out what it means. – templatetypedef Feb 7 '13 at 2:26
• It may be open to question whether it improves the computational complexity, but a sieve of Eratosthenes is quite a bit faster anyway. – Jerry Coffin Feb 7 '13 at 2:37
• @templatetypedef: added comments to code. – codewarrior Feb 7 '13 at 2:56
• The full answer is stackoverflow.com/a/9704912/849891 . – Will Ness Feb 7 '13 at 9:54
• Also, it is good to search the SO first: stackoverflow.com/tags/primes/hot?filter=year . – Will Ness Feb 7 '13 at 10:07

## 3 Answers

Yes.

Your algorithm make O(n^2) operations (maybe I'm not accurate, but seems so), where n is result.

There are http://en.wikipedia.org/wiki/Sieve_of_Eratosthenes algorithm that takes O(ipn* log(log(n))). You can make only inp steps in it, and assume that n = 2ipn*ln(ipn). n just should be greater then ipn-prime. (we know distributions of prime numbers http://en.wikipedia.org/wiki/Prime_number_theorem)

Anyway, you can improve existing solution:

``````public void calcPrime(int inp) {
ArrayList<Integer> arr = new ArrayList<Integer>();
arr.add(2);
arr.add(3);

int counter = 4;

while(arr.size() < inp) {
if(counter % 2 != 0 && counter%3 != 0) {
int temp = 4;
while(temp*temp <= counter) {
if(counter % temp == 0)
break;
temp ++;
}
if(temp*temp > counter) {
arr.add(counter);
}
}
counter++;
}

System.out.println("finish" +arr.get(inp-1));
}
}
``````
• could you tell me how this works, specifically why do you check using temp*temp? thats going to check if the counter is divisible by 16,25,36.. – codewarrior Feb 7 '13 at 3:16
• He checks temp*temp against counter since that implies that temp <= sqrt(counter). It's enough to check up to that point since multiplication is commutative. – G. Bach Feb 7 '13 at 3:26
• Brilliant. thanks! – codewarrior Feb 7 '13 at 3:43
• what is n? what is ipn? Is inp `inp`? Is this the Sieve of Eratosthenes? – Will Ness Feb 7 '13 at 9:46
• Keegan, prime numbers start from 2. en.wikipedia.org/wiki/Prime_number#Definition_and_examples – xvorsx Aug 14 '13 at 20:56

A few things you can do to speed it up:

1. Start counter at 5 and increment it by 2 instead of 1, then don't check mod 2 in the loop.
2. Instead of starting temp at counter / 2, start it at the first odd <= int(sqrt(counter))
3. decrement temp by 2.

I'm not sure whether it counts as improving complexity, but (2) above will go from O(n^2) to O(n*sqrt(n))

• testing by `temp` from the `sqrt` down is very inefficient. I suspect it even changes the complexity for the worse. – Will Ness Feb 7 '13 at 9:50
• @Will It does indeed. I haven't analysed it in detail, but the semiprimes whose larger factor is at least four times the smaller factor alone give an additional `log log n` factor. I expect that the constant factor slowdown is much worse for a long long time, though. – Daniel Fischer Feb 14 '13 at 23:03
• @Daniel empirically ideone.com/iNxOrC indeed the counting-down code seems to run in `m^1.5`, where m is the top limit. The ratios of actual run times are `2.6x ... 3.6x` and worsening, for top limit 100k ... 1.2mln. `m^1.5` for counting-down code actually makes sense - there's no early cut-off so it's as if testing each odd by all odds below sqrt. While in counting-up the cost for non-prime odds is at the most the same as for primes (as shows M. O'Neill), giving the `m^1.5/log(m)`. – Will Ness Feb 15 '13 at 12:48
• @Will What do you mean with "early cut-off"? You divide until you find the first divisor or hit the limit, whether you count up or down, in that respect, both ways are similar. Counting down, you generally have a much longer way to the first divisor, though. I sort-of expect it to be `Θ(√n)` on average (so the empirical `m^1.5` fits), but I don't see an easy way to prove it (closest divisor to `√n` is harder to grip than smallest prime divisor). – Daniel Fischer Feb 15 '13 at 13:35
• @Daniel that's what I meant, yes, the much longer way is almost "all the way". It is of course not rigorous in any way. Try finding the "expected value" of biggest factor for a randomly-chosen composite in the range 2..n, something to that effect (it will be our cut-off point, on average, counting down). `n` or `sqrt(n)`, I expect won't make much of a difference. – Will Ness Feb 15 '13 at 13:59
``````public static void Main()
{
Console.Write("Enter a Number : ");
int num;
int[] arr = new int;
num = Convert.ToInt32(Console.ReadLine());
int k;
k = 0;
int t = 1;
for (int j = 1; j < 10000; j++)
{
for (int i = 1; i <= j; i++)
{
if (j % i == 0)
{
k++;
}
}
if (k == 2)
{
arr[t] = j;
t++;
k = 0;
}
else
{
k = 0;
}
}
Console.WriteLine("Nth Prime number. {0}", arr[num]);
Console.ReadLine();
}
``````
• Can you include an indication of the improvement? – belwood Jan 15 at 14:20
• How does this `[improve] time complexity [of find the nth prime over counting primes identified by trial division]`? – greybeard Jan 15 at 14:27