# Finding prime numbers with the Sieve of Eratosthenes (Originally: Is there a better way to prepare this array?)

Note: Version 2, below, uses the Sieve of Eratosthenes. There are several answers that helped with what I originally asked. I have chosen the Sieve of Eratosthenes method, implemented it, and changed the question title and tags appropriately. Thanks to everyone who helped!

## Introduction

I wrote this fancy little method that generates an array of int containing the prime numbers less than the specified upper bound. It works very well, but I have a concern.

## The Method

``````private static int [] generatePrimes(int max) {
int [] temp = new int [max];
temp  = 2;
int index = 1;
int prime = 1;
boolean isPrime = false;
while((prime += 2) <= max) {
isPrime = true;
for(int i = 0; i < index; i++) {
if(prime % temp [i] == 0) {
isPrime = false;
break;
}
}
if(isPrime) {
temp [index++] = prime;
}
}
int [] primes = new int [index];
while(--index >= 0) {
primes [index] = temp [index];
}
return primes;
}
``````

## My Concern

My concern is that I am creating an array that is far too large for the final number of elements the method will return. The trouble is that I don't know of a good way to correctly guess the number of prime numbers less than a specified number.

## Focus

This is how the program uses the arrays. This is what I want to improve upon.

1. I create a temporary array that is large enough to hold every number less than the limit.
2. I generate the prime numbers, while keeping count of how many I have generated.
3. I make a new array that is the right dimension to hold just the prime numbers.
4. I copy each prime number from the huge array to the array of the correct dimension.
5. I return the array of the correct dimension that holds just the prime numbers I generated.

## Questions

1. Can I copy the whole chunk (at once) of `temp[]` that has nonzero elements to `primes[]` without having to iterate through both arrays and copy the elements one by one?
2. Are there any data structures that behave like an array of primitives that can grow as elements are added, rather than requiring a dimension upon instantiation? What is the performance penalty compared to using an array of primitives?

Version 2 (thanks to Jon Skeet):

``````private static int [] generatePrimes(int max) {
int [] temp = new int [max];
temp  = 2;
int index = 1;
int prime = 1;
boolean isPrime = false;
while((prime += 2) <= max) {
isPrime = true;
for(int i = 0; i < index; i++) {
if(prime % temp [i] == 0) {
isPrime = false;
break;
}
}
if(isPrime) {
temp [index++] = prime;
}
}
return Arrays.copyOfRange(temp, 0, index);
}
``````

Version 3 (thanks to Paul Tomblin) which uses the Sieve of Erastosthenes:

``````private static int [] generatePrimes(int max) {
boolean[] isComposite = new boolean[max + 1];
for (int i = 2; i * i <= max; i++) {
if (!isComposite [i]) {
for (int j = i; i * j <= max; j++) {
isComposite [i*j] = true;
}
}
}
int numPrimes = 0;
for (int i = 2; i <= max; i++) {
if (!isComposite [i]) numPrimes++;
}
int [] primes = new int [numPrimes];
int index = 0;
for (int i = 2; i <= max; i++) {
if (!isComposite [i]) primes [index++] = i;
}
return primes;
}
``````
• why do you need a fixed size array? Feb 25, 2009 at 14:56
• Matt Davison: I don't want to return an array that has a bunch of zero elements at the end, it feels so sloppy. Feb 25, 2009 at 14:57
• One micro-optimization I'd make: replace "for (int j = i; i*j..." with "for (int j = i; j <= max; j+=i) { isComposite[j] = true;}" Feb 25, 2009 at 23:27
• Paul Tomblin: The replacement code you provided misses several prime numbers. Feb 26, 2009 at 16:21
• Using a BitSet is 8x more efficient than a large boolean[]. Feb 6, 2010 at 11:15

Your method of finding primes, by comparing every single element of the array with every possible factor is hideously inefficient. You can improve it immensely by doing a Sieve of Eratosthenes over the entire array at once. Besides doing far fewer comparisons, it also uses addition rather than division. Division is way slower.

• Yes, that was just a placeholder until I could look it up on Wikipedia. Feb 25, 2009 at 14:59
• Paul Tomblin: My method just returns an array of int representing the prime numbers less than the specified upper bound, I don't think I need to sieve anything. Feb 25, 2009 at 14:59
• The problem is the use of arrays - you can't actually remove an element from a Java array, just 0/null it out. The Sieve is orthogonal. Feb 25, 2009 at 15:00
• But you're checking every value of the array against every possible factor. By doing a Sieve, you check the whole array for primes in one shot, reducing the complexity from O(n^2) to O((nlogn)(loglogn)) Feb 25, 2009 at 15:02
• @Hank, no, the problem is that he's trying to optimize the half a millisecond it will take to convert his array, instead of the several seconds it will take to generate primes his way. Feb 25, 2009 at 15:16

### `ArrayList<>` Sieve of Eratosthenes

``````// Return primes less than limit
static ArrayList<Integer> generatePrimes(int limit) {
final int numPrimes = countPrimesUpperBound(limit);
ArrayList<Integer> primes = new ArrayList<Integer>(numPrimes);
boolean [] isComposite    = new boolean [limit];   // all false
final int sqrtLimit       = (int)Math.sqrt(limit); // floor
for (int i = 2; i <= sqrtLimit; i++) {
if (!isComposite [i]) {
for (int j = i*i; j < limit; j += i) // `j+=i` can overflow
isComposite [j] = true;
}
}
for (int i = sqrtLimit + 1; i < limit; i++)
if (!isComposite [i])
return primes;
}
``````

Formula for upper bound of number of primes less than or equal to `max` (see wolfram.com):

``````static int countPrimesUpperBound(int max) {
return max > 1 ? (int)(1.25506 * max / Math.log((double)max)) : 0;
}
``````
• prime counting function was one very interesting thing in your answer Oct 18, 2020 at 7:45

Create an `ArrayList<Integer>` and then convert to an `int[]` at the end.

There are various 3rd party `IntList` (etc) classes around, but unless you're really worried about the hit of boxing a few integers, I wouldn't worry about it.

You could use `Arrays.copyOf` to create the new array though. You might also want to resize by doubling in size each time you need to, and then trim at the end. That would basically be mimicking the `ArrayList` behaviour.

• I like java.util.Arrays.copyOfRange(int [] original, int from, int to); Feb 25, 2009 at 15:04

Algo using Sieve of Eratosthenes

``````public static List<Integer> findPrimes(int limit) {

List<Integer> list = new ArrayList<>();

boolean [] isComposite = new boolean [limit + 1]; // limit + 1 because we won't use '0'th index of the array
isComposite = true;

// Mark all composite numbers
for (int i = 2; i <= limit; i++) {
if (!isComposite[i]) {
// 'i' is a prime number
int multiple = 2;
while (i * multiple <= limit) {
isComposite [i * multiple] = true;
multiple++;
}
}
}

return list;
}
``````

Image depicting the above algo (Grey color cells represent prime number. Since we consider all numbers as prime numbers intially, the whole is grid is grey initially.) Image Source: WikiMedia

The easiest solution would be to return some member of the Collections Framework instead of an array.

Are you using Java 1.5? Why not return `List<Integer>` and use `ArrayList<Integer>`? If you do need to return an `int[]`, you can do it by converting List to `int[]` at the end of processing.

As Paul Tomblin points out, there are better algorithms.

But keeping with what you have, and assuming an object per result is too big:

You are only ever appending to the array. So, use a relatively small int[] array. When it's full use append it to a List and create a replacement. At the end copy it into a correctly sized array.

Alternatively, guess the size of the int[] array. If it is too small, replace by an int[] with a size a fraction larger than the current array size. The performance overhead of this will remain proportional to the size. (This was discussed briefly in a recent stackoverflow podcast.)

Now that you've got a basic sieve in place, note that the inner loop need only continue until `temp[i]*temp[i] > prime`.

I have a really efficient implementation:

1. we don't keep the even numbers, therefore halving the memory usage.
2. we use `BitSet`, requiring only one bit per number.
3. we estimate the upper bound for number of primes on the interval, thus we can set the `initialCapacity` for the Array appropriately.
4. we don't perform any kind of division in the loops.

Here's the code:

``````public ArrayList<Integer> sieve(int n) {
int upperBound = (int) (1.25506 * n / Math.log(n));
ArrayList<Integer> result = new ArrayList<Integer>(upperBound);
if (n >= 2)

int size = (n - 1) / 2;
BitSet bs = new BitSet(size);

int i = 0;
while (i < size) {
int p = 3 + 2 * i;

for (int j = i + p; j < size; j += p)
bs.set(j);

i = bs.nextClearBit(i + 1);
}

return result;
}
``````

Restructure your code. Throw out the temporary array, and instead write function that just prime-tests an integer. It will be reasonably fast, since you're only using native types. Then you can, for instance, loop and build a list of integers that are prime, before finally converting that to an array to return.

Not sure if this will suite your situation but you can take a look at my approach. I used mine using Sieve of Eratosthenes.

``````  public static List<Integer> sieves(int n) {

List<Integer> primes = new ArrayList<>();

//First generate a list of integers from 2 to 30
for(int i=2; i<n;i++){
numbers.put(i,true);
}

for(int i : numbers.keySet()){
/**
* The first number in the list is 2; cross out every 2nd number in the list after 2 by
* counting up from 2 in increments of 2 (these will be all the multiples of 2 in the list):
*
* The next number in the list after 2 is 3; cross out every 3rd number in the list after 3 by
* counting up from 3 in increments of 3 (these will be all the multiples of 3 in the list):
* The next number not yet crossed out in the list after 5 is 7; the next step would be to cross out every
* 7th number in the list after 7, but they are all already crossed out at this point,
* as these numbers (14, 21, 28) are also multiples of smaller primes because 7 × 7 is greater than 30.
* The numbers not crossed out at this point in the list are all the prime numbers below 30:
*/
if(numbers.get(i)){
for(int j = i+i; j<n; j+=i) {
numbers.put(j,false);
}
}
}

for(int i : numbers.keySet()){
for(int j = i+i; j<n && numbers.get(i); j+=i) {
numbers.put(j,false);
}
}

for(int i : numbers.keySet()){
if(numbers.get(i)) {
}
}
return primes;
}
``````

Added comment for each steps that has been illustrated in wikipedia

I have done using HashMap and found it very simple

``````import java.util.HashMap;
import java.util.Map;

/*Using Algorithms such as sieve of Eratosthanas */

public static void main(String[] args) {

int prime = 15;
HashMap<Integer, Integer> hashMap = new HashMap<Integer, Integer>();

hashMap.put(0, 0);
hashMap.put(1, 0);
for (int i = 2; i <= prime; i++) {

hashMap.put(i, 1);// Assuming all numbers are prime
}

}

private static void printPrimeNumberEratoshanas(HashMap<Integer, Integer> hashMap, int prime) {

System.out.println("Printing prime numbers upto" + prime + ".....");
for (Map.Entry<Integer, Integer> entry : hashMap.entrySet()) {
if (entry.getValue().equals(1)) {
System.out.println(entry.getKey());
for (int j = entry.getKey(); j < prime; j++) {
for (int k = j; k * j <= prime; k++) {
hashMap.put(j * k, 0);
}
}

}
}

}

}
``````

Think this is effective

``````public static void primes(int n) {
boolean[] lista = new boolean[n+1];
for (int i=2;i<lista.length;i++) {
if (lista[i]==false) {
System.out.print(i + " ");
}
for (int j=i+i;j<lista.length;j+=i) {
lista[j]=true;
}
}
}
``````