# Prime numbers by Eratosthenes quicker sequential than concurrently?

I am currently writing a program which first generates prime numbers by the Sieve of Eratosthenes sequentially, then concurrently. The concurrent version of the algorithm is supposed to be quicker than the sequential one, but in my case the concurrent version is approx. 10 times slower. I am wondering where I am putting the extra work on my threads, compared to the main thread in the sequential solution. Here's my program (prepare to read a bit!):

Primes.java:

``````public abstract class Primes {

byte[] bitArr;
int maxNum;
final int[] BITMASK = { 1, 2, 4, 8, 16, 32, 64 };
final int[] BITMASK2 = { 255 - 1, 255 - 2, 255 - 4, 255 - 8,
255 - 16, 255 - 32, 255 - 64 };

void setAllPrime() {
for (int i = 0; i < bitArr.length; i++) {
bitArr[i] = (byte) 127;
}
}

void crossOut(int i) {
bitArr[i/14] = (byte) (bitArr[i/14] - BITMASK[((i/2)%7)]);
}

boolean isPrime(int i) {
if(i == 2){
return true;
}
if((i%2) == 0){
return false;
}

return (bitArr[i/14] & BITMASK[(i%14)>>1]) != 0;

}

int nextPrime(int i) {
int k;
if ((i%2) == 0){
k =i+1;
}
else {
k = i+2;
}
while (!isPrime(k) && k < maxNum){
k+=2;
}
return k;
}

void printAllPrimes() {
for (int i = 2; i <= maxNum; i++){
if (isPrime(i)){
System.out.println("Prime: " + i);
}
}
}
}
``````

PrimesSeq.java:

``````import java.util.ArrayList;

public class PrimesSeq extends Primes{

PrimesSeq(int maxNum) {
this.maxNum = maxNum;
bitArr = new byte[(maxNum / 14) + 1];
setAllPrime();
generatePrimesByEratosthenes();
}

void generatePrimesByEratosthenes() {
crossOut(1); // 1 is not a prime

int curr = 3;
while(curr < Math.sqrt(maxNum)){
for(int i = curr*curr; i < maxNum; i+=2*curr){
if(isPrime(i)){                // 2*curr because odd*2 = even!
crossOut(i);
}
}
curr = nextPrime(curr);
}
}
}
``````

PrimesPara.java:

``````import java.util.ArrayList;

public class PrimesPara extends Primes {

int processors;
int currentState = 0;
//0 = Init
//1 = Generate primes after thread #0 finish
//2 = Factorize

public PrimesPara(int maxNum){
this.maxNum = maxNum;
this.processors = Runtime.getRuntime().availableProcessors();
bitArr = new byte[(maxNum / 14) + 1];
setAllPrime();
generateErastothenesConcurrently();
//printAllPrimes();
}

public void generateErastothenesConcurrently(){

for(int i = 0; i < threads.length; i++){
} else {
}
}

//Start generating the first primes
crossOut(1);
th.start();
try {
th.join();
} catch (InterruptedException e) {
// TODO Auto-generated catch block
e.printStackTrace();
}
currentState = 1;

//Start generating the rest of the primes
for(int i = 0; i < thrs.length; i++){
thrs[i].start();
}
for(int i = 0; i < thrs.length; i++){
try {
thrs[i].join();
} catch (InterruptedException e) {
e.printStackTrace();
}
}
currentState = 2;
}

int[] indexes = new int[processors*2];

for(int i = 0; i < indexes.length; i++){
indexes[i] = (i*((maxNum/(processors*2))));
}

indexes[indexes.length-1]++;

return indexes;
}

public class PrimeThread implements Runnable {

int start;
int end;
int thridx;

public PrimeThread(int start, int end, int thridx){
this.start = start;
this.end = end;
this.thridx = thridx;
}

public void run() {
switch(currentState){
case 0:
generateSqrtPrimes();
break;
case 1:
generateMyPrimes();
break;
case 2:
break;
}
}

private void generateSqrtPrimes(){
int curr = 3;
while(curr < Math.sqrt(maxNum)+1){
for(int i = curr*curr; i < Math.sqrt(maxNum)+1; i+=2*curr){
if(isPrime(i)){                  // 2*curr because odd*2 = even!
crossOut(i);
}
}
curr = nextPrime(curr);
}
}

private void generateMyPrimes(){
int curr = start>(int)Math.sqrt(maxNum)?start:(int)Math.sqrt(maxNum);

while(curr < end){
for(int i = 3; i < Math.sqrt(maxNum)+1; i = nextPrime(i)){
if((curr%i) == 0){
if(isPrime(curr)){
crossOut(curr);
}
}
}
curr = nextPrime(curr);
}
}
}
}
``````

If someone could tell me where the bottleneck on the concurrent program is, I'd be very happy. Thanks in advance!

• Can you please explain your sequential and parallel implementation concisely? I am not inclined to read through 200 lines of code to figure it out myself Mar 17, 2014 at 23:03
• Just a few thoughts: (i) your `Primes` class is not thread safe - `crossOut` for example is not thread safe - so it is very possible that your parallel threads have to do a lot more work because they don't see what the others have done (ii) even if that worked, you will do more work because you may check 17 * 19 before having crossed out 17 and 19 (whereas in the sequential algo, that can't happen) (iii) if your program completes fairly quickly (say a few 100s of ms), the time to start the thread will probably outweight any gains. Mar 17, 2014 at 23:06
• incidentally according to primesPara 35 is prime. Mar 17, 2014 at 23:32
• It's quite likely that among other problems you are experiencing false sharing. Also, `2*processors` threads is probably too many. Start with just two threads and see if that gives you correct results and a performance boost. Then increase the number of threads. Mar 18, 2014 at 1:26
• can you explain your logic so that we can discuss whether parallel algorithm is correct because sieve of eratosthenes seems difficult to parallelize without being incorrect. Mar 18, 2014 at 6:15

I am no JAVA coder so I stick with C++. Also this is not an direct answer to your question (sorry for that but I can not debug JAVA) take this as some pointers which way to go or check...

1. Sieves of Eratosthenes

Parallelization is possible but not with big enough speed gain. Instead I use more sieve-tabs where each one have its own sub-divisions and each table size is an common multiply of all its sub-divisors. This way you need initiate tables just once and then just check them in `O(1)`

2. Parallelization

After checking all of the sieves then I would use threads to do the obvious division testing for all of the unused divisors

3. Memoize

If you have active table of all found primes then divide just by primes and add all new primes found

I am using non parallel prime search which is fast enough for me ...

[Edit1] updated code

``````//---------------------------------------------------------------------------
int bits(DWORD p)
{
DWORD m=0x80000000; int b=32;
for (;m;m>>=1,b--)
if (p>=m) break;
return b;
}
//---------------------------------------------------------------------------
DWORD sqrt(const DWORD &x)
{
DWORD m,a;
m=(bits(x)>>1);
if (m) m=1<<m; else m=1;
for (a=0;m;m>>=1) { a|=m; if (a*a>x) a^=m; }
return a;
}
//---------------------------------------------------------------------------
List<int> primes_i32;                   // list of precomputed primes
const int primes_map_sz=4106301;        // max size of map for speedup search for primes max(LCM(used primes per bit)) (not >>1 because SOE is periodic at double LCM size and only odd values are stored 2/2=1)
const int primes_map_N[8]={ 4106301,3905765,3585337,4026077,3386981,3460469,3340219,3974653 };
const int primes_map_i0=33;             // first index of prime not used in mask
const int primes_map_p0=137;            // biggest prime used in mask
BYTE primes_map[primes_map_sz];         // factors map for first i0-1 primes
bool primes_i32_alloc=false;
int isprime(int p)
{
int i,j,a,b,an,im[8]; BYTE u;
an=0;
if (!primes_i32.num)                // init primes vars
{
primes_i32.allocate(1024*1024);
primes_i32.add(  2); for (i=1;i<primes_map_sz;i++) primes_map[i]=255; primes_map[0]=254;
primes_i32.add(  3); for (u=255-  1,j=  3,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add(  5); for (u=255-  2,j=  5,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add(  7); for (u=255-  4,j=  7,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 11); for (u=255-  8,j= 11,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 13); for (u=255- 16,j= 13,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 17); for (u=255- 32,j= 17,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 19); for (u=255- 64,j= 19,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 23); for (u=255-128,j= 23,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 29); for (u=255-  1,j=137,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 31); for (u=255-  2,j=131,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 37); for (u=255-  4,j=127,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 41); for (u=255-  8,j=113,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 43); for (u=255- 16,j= 83,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 47); for (u=255- 32,j= 61,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 53); for (u=255- 64,j=107,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 61); for (u=255-  1,j=103,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 67); for (u=255-  2,j= 67,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 71); for (u=255-  4,j= 37,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 73); for (u=255-  8,j= 41,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 79); for (u=255- 16,j= 43,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 83); for (u=255- 32,j= 47,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 89); for (u=255- 64,j= 53,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add( 97); for (u=255-128,j= 59,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add(101); for (u=255-  1,j= 97,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add(103); for (u=255-  2,j= 89,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add(109); for (u=255-  8,j= 79,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add(113); for (u=255- 16,j= 73,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add(127); for (u=255- 32,j= 71,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
primes_i32.add(131); for (u=255- 64,j= 31,i=j>>1;i<primes_map_sz;i+=j) primes_map[i]&=u;
}

if (!primes_i32_alloc)
{
if (p  <=1) return 0;               // ignore too small walues
if (p&1==0) return 0;               // not prime if even
if (p>primes_map_p0)
{
j=p>>1;
i=j; if (i>=primes_map_N[0]) i%=primes_map_N[0]; if (!(primes_map[i]&  1)) return 0;
i=j; if (i>=primes_map_N[1]) i%=primes_map_N[1]; if (!(primes_map[i]&  2)) return 0;
i=j; if (i>=primes_map_N[2]) i%=primes_map_N[2]; if (!(primes_map[i]&  4)) return 0;
i=j; if (i>=primes_map_N[3]) i%=primes_map_N[3]; if (!(primes_map[i]&  8)) return 0;
i=j; if (i>=primes_map_N[4]) i%=primes_map_N[4]; if (!(primes_map[i]& 16)) return 0;
i=j; if (i>=primes_map_N[5]) i%=primes_map_N[5]; if (!(primes_map[i]& 32)) return 0;
i=j; if (i>=primes_map_N[6]) i%=primes_map_N[6]; if (!(primes_map[i]& 64)) return 0;
i=j; if (i>=primes_map_N[7]) i%=primes_map_N[7]; if (!(primes_map[i]&128)) return 0;
}
}

an=primes_i32[primes_i32.num-1];
if (an>=p)
{
// linear table search
if (p<127)  // 31st prime
{
if (an>=p) for (i=0;i<primes_i32.num;i++)
{
a=primes_i32[i];
if (a==p) return 1;
if (a> p) return 0;
}
}
// approximation table search
else{
for (j=1,i=primes_i32.num-1;j<i;j<<=1); j>>=1; if (!j) j=1;
for (i=0;j;j>>=1)
{
i|=j;
if (i>=primes_i32.num) { i-=j; continue; }
a=primes_i32[i];
if (a==p) return 1;
if (a> p) i-=j;
}
return 0;
}
}
a=an; a+=2;
for (j=a>>1,i=0;i<8;i++) im[i]=j%primes_map_N[i];
an=(1<<((bits(p)>>1)+1))-1; if (an<=0) an=1;
an=an+an;
for (;a<=p;a+=2)
{
for (j=1,i=0;i<8;i++,j<<=1)                     // check if map is set
if (!(primes_map[im[i]]&j)) { j=-1; break; }   // if not dont bother with division
for (i=0;i<8;i++) { im[i]++; if (im[i]>=primes_map_N[i]) im[i]-=primes_map_N[i]; }
if (j<0) continue;
for (i=primes_map_i0;i<primes_i32.num;i++)
{
b=primes_i32[i];
if (b>an) break;
if ((a%b)==0) { i=-1; break; }
}
if (i<0) continue;
if (a==p) return 1;
if (a> p) return 0;
}
return 0;
}
//---------------------------------------------------------------------------
void getprimes(int p)                       // compute and allocate primes up to p
{
if (!primes_i32.num) isprime(3);
int p0=primes_i32[primes_i32.num-1];    // biggest prime computed yet
if (p>p0+10000)                         // if too big difference use sieves to fast precompute
{
// T((0.3516+0.5756*log10(n))*n) -> O(n.log(n))
// sieves N/16 bytes p=100 000 000 t=1903.031 ms
//  ------------------------------
//   0  1  2  3  4  5  6  7 bit
//  ------------------------------
//   1  3  5  7  9 11 13 15 +-> +2
//  17 19 21 23 25 27 29 31 |
//  33 35 37 39 41 43 45 47 V +16
//  ------------------------------
int N=(p|15),M=(N>>4);              // store only odd values 1,3,5,7,... each bit ...
char *m=new char[M+1];              // m[i] ->  is 1+i+i prime? (factors map)
int i,j,k,n;
// init sieves
m[0]=254; for (i=1;i<=M;i++) m[i]=255;
for(n=sqrt(p),i=1;i<=n;)
{
int a=m[i>>4];
if (int(a&  1)!=0) for(k=i+i,j=i+k;j<=N;j+=k) m[j>>4]&=255-(1<<((j>>1)&7)); i+=2;
if (int(a&  2)!=0) for(k=i+i,j=i+k;j<=N;j+=k) m[j>>4]&=255-(1<<((j>>1)&7)); i+=2;
if (int(a&  4)!=0) for(k=i+i,j=i+k;j<=N;j+=k) m[j>>4]&=255-(1<<((j>>1)&7)); i+=2;
if (int(a&  8)!=0) for(k=i+i,j=i+k;j<=N;j+=k) m[j>>4]&=255-(1<<((j>>1)&7)); i+=2;
if (int(a& 16)!=0) for(k=i+i,j=i+k;j<=N;j+=k) m[j>>4]&=255-(1<<((j>>1)&7)); i+=2;
if (int(a& 32)!=0) for(k=i+i,j=i+k;j<=N;j+=k) m[j>>4]&=255-(1<<((j>>1)&7)); i+=2;
if (int(a& 64)!=0) for(k=i+i,j=i+k;j<=N;j+=k) m[j>>4]&=255-(1<<((j>>1)&7)); i+=2;
if (int(a&128)!=0) for(k=i+i,j=i+k;j<=N;j+=k) m[j>>4]&=255-(1<<((j>>1)&7)); i+=2;
}
// compute primes
i=p0&0xFFFFFFF1; k=m[i>>4]; // start after last found prime in list
for(j=i>>4;j<M;i+=16,j++)   // continue with 16-blocks
{
k=m[j];
if (!k) continue;
}
k=m[j]; // do the last primes
delete[] m;
}
else{
bool b0=primes_i32_alloc;
primes_i32_alloc=true;
isprime(p);
primes_i32_alloc=false;
primes_i32_alloc=b0;
}
}
//---------------------------------------------------------------------------
``````
• solved some overflow bugs in mine code (periodicity of sieves ...)

• also some further optimizations

• added `getprimes(p)` function which add all `primes<=p` to the list fast as it can if they are not there yet

• tested correctness on first 1 000 000 primes (up to 15 485 863)

• `getprimes(15 485 863)` solves it on 175.563 ms on mine setup

• `isprime` is way slower for this of coarse

• `primes_i32` is a dynamic list of `int`s

• `primes_i32.num` is the number of `int`s in the list

• `primes_i32[i]` is the `i`-th `int i = <0,primes_i32.num-1>`

• `primes_i32.add(x)` add `x` to the end of list

• `primes_i32.allocate(N)` preallocates space for `N` items in list to avoid reallocation slowdowns

[notes]

I have used this non parallel version for Euler problem 10 (sum of all primes below 2000000)

``````    ----------------------------------------------------------------------------------
Time         ID      Reference    | My solution   | Note
----------------------------------------------------------------------------------
[  35.639 ms] Problem010. 142913828922 | 142913828922  | 64_bit
``````
• The sieve tabs are each one as a bit slice in the `primes_map[]` array and only the odd values are used (no need to remember even sieves).
• if you want maximize speed for all primes found then just call `isprime(max value)` and read the contents of `primes_i32[]`
• I use half of the bit-size instead of sqrt for speed

Hope I did not forget to copy something here