# Can someone please explain how this implementation works? Also, can it be made better? How?

``````public class Main {
public static void main(String args []){
long numberOfPrimes = 0; //Initialises variable numberOfPrimes to 0 (same for all other variables)
int number = 1;
int maxLimit = 10000000;
boolean[] sieve = new boolean[maxLimit]; //creates new boolean array called sieve and allocates space on the
//stack for this array which has maxLimit spaces in it
for ( int i = 2; i < maxLimit; i++ ) { //for statement cycling from 2 to 10000000, does not execute the rest
//of the block if the boolean value in the array is true
if ( sieve[i] == true ) continue;

numberOfPrimes++; //otherwise it increments the number of prime numbers found

if ( numberOfPrimes == 10001 ) {  //if 10001st prime number is found, break from loop
number = i;
break;
}

for ( int j = i+i; j < maxLimit; j += i ) //do not understand the point of this loop logically
sieve[j] = true;                      //testing if the value in the array is true again?
}
System.out.println("10001st prime: "+ number);
}
}
``````

I don't really understand what is going on in this program and was hoping somebody could explain it to me? I have commented the specific lines causing me trouble/what I understand lines to be doing. Thank you very much for all the help! :)

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Yes, this is your basic implementation of Eratosthenes' Sieve. There are quite a few ways in which you can improve it, but let's go over the basic principle first.

What you are doing is creating an array of boolean values. The INDEX in the array represents the number which we are testing to see if it is a prime or not.

Now you are going to start checking each number to see if it is a prime. First off, the definition of a prime is "all numbers divisible ONLY by itself and 1 without fractioning".

``````for ( int i = 2; i < maxLimit; i++ )
``````

You start with the INDEX 2 (the number 3) because depending on your definition, 1 and 2 are always prime. (Some definitions say 1 is not a prime).

``````if ( sieve[i] == true ) continue;
``````

If a number has been marked as a non-prime previously, we don't bother with the current iteration.

``````numberOfPrimes++;

if ( numberOfPrimes == 10001 ) {
number = i;
break;
}
``````

If the INDEX we are at currently has not been marked as being a prime, it has to be one, so we increment the number of primes we have found. The next piece of code I'm assuming is part of the requirements of the program which states that if 10001 primes have been found, the program must exit. That part can be left out if you actually want to check for primes up to the maximum number defined in stead of for a specific number of primes.

``````for ( int j = i+i; j < maxLimit; j += i )
sieve[j] = true;
``````

This is where the actual magic of the sieve starts. From the definition of a prime, a number cannot be a prime if it is divisible by anything other than itself and 1. Therefore, for any new number we find that is a prime, we can mark all it's factors as NOT being prime. For example, the first iteration of the for loop, we start with 3. Because sieve[2] is false (have not visited before), it is a prime (AND 3 IS A PRIME!). Then, all other factors of 3 CANNOT be primes. The above mentioned for loop goes through the entire sieve and marks all factors of 3 as false. So that loop will do: sieve[5] = true; sieve[8] = true ... up until the end of the sieve.

Now, when you reach the first number greater than the maximum defined initially, you can be certain that any number that has a factor has been marked as not being a prime. What you end up with is a boolean array, where each index marked as false, represents a prime number.

You can probably get a much better description on wikipedia, but this is the jist of it. Hope it helps!

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Make yourself familiar with Eratosthenes' Sieve algorithm. Wikipedia even has animated gif demonstrating the process. And your code is just a straightforward implementation of it.

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``````for ( int j = i+i; j < maxLimit; j += i ) //dont understand the point of this loop logically
sieve[j] = true;          //testing if the value in the array is true again ?
``````

This is not a testing, but rather a setting. This loop is setting all the items in the array with indexes multiple of `i` to `true`. When `i` is 2, then the items 4, 6, 8 ... will be set to `true`. When `i` is 3, the items 6, 9, 12 ... will be set to `true` and so on.

And as you can deduce by the first `if`,

``````if ( sieve[i] == true ) continue;
``````

... all the items that are `true` correspond to non-prime numbers.

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I find the easiest way to understand something is to deconstruct it. Therefore, lets go through the loop a few times, shall we?

## Dawn of the First Iteration

− 9999998 Values Remain −

`i = 2`
`sieve[2]` is `false`, so we keep going in the current iteration.
`numberOfPrimes = 1` and thus we continue processing
Set every multiple of 2 to `true` in `sieve[]`.

## Dawn of the Second Iteration

− 9999997 Values Remain −

`i = 3`
`sieve[3]` is `false`, so we keep going in the current iteration.
`numberOfPrimes = 2` and thus we continue processing
Set every multiple of 3 to `true` in `sieve[]`.

## Dawn of the Third Iteration

− 9999996 Values Remain −

`i = 4`
`sieve[4]` is `true` (from first iteration). Skip to next iteration.

etc... but in this case, the moon doesn't crash into Termina.

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The loop in question isn't checking for true values, it's setting true values.

It's going through each multiple of the prime and marking it as non-prime up to `maxLimit`. You'll notice there's no other math in the code to determine what's prime and what's not.

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