# searching a prime number

I hope I am not duplication any question but the suggested topic did not provide with any similar problem. I have a function that check if a number is a prime one. Now this is the slowest possible way to search for a prime.

subroutine is_prime_slow(num, stat)
implicit none
logical :: stat
integer :: num
integer :: i
if ((num .le. 3) .and. (num .gt. 1)) then
stat = .true.
return
end if

! write(*,*) 'limit = ',limit
do i = 2,num - 1
! write(*,*) 'mod(',limit,i,') = ',mod(limit,i)
if (mod(num,i) == 0) then
stat = .false.
return
end if
end do
stat = .true.
return
end

Now let's say that I do some improvement to it.

subroutine is_prime_slow(num, stat)
implicit none
logical :: stat
integer :: num
integer :: i
if ((num .le. 3) .and. (num .gt. 1)) then
stat = .true.
return
end if
! IMPROVEMENT
if ((mod(num,2) == 0) .or. (mod(num,3) == 0) .or. (mod(num,5) == 0) .or. (mod(num,7) == 0)) then
stat = .false.
return
end if

! write(*,*) 'limit = ',limit
do i = 2,num - 1
! write(*,*) 'mod(',limit,i,') = ',mod(limit,i)
if (mod(num,i) == 0) then
stat = .false.
return
end if
end do
stat = .true.
return
end

Now the second version excludes more than half of numbers e.g. all that are divisible by 2,3,5,7. How is it possible that when I time the execution with the linux 'time' program, the 'improved' version performs just as slowly? Am I missing some obvious trick?

Searching the first 900000 numbers:
1st: 4m28sec
2nd  4m26sec
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You just need to check prime divisors up to sqrt(num) (exercise: prove it). To speed up: first find all primes in the range [2, sqrt(num)] using a sieve, then search for divisors in those primes. If none is found, num is prime. Your code is slow for a reason: your mod doesn't help because your method is SLOW for prime numbers, and your mod check speed up the code for composite numbers only. – Haile Sep 22 '13 at 18:00
I know that [2,sqrt(num)] would speed it up. But let's say I'm checking the numbers 2311 (prime) and 2312 (not a prime). Sqrt(2311) is 48.073 and sqrt(2312) is 48.083. And after floor, both are 48. Wouldn't I be searching the same two sets of numbers, i.e. find the they are either both prime or both not prime? – Andro Sep 22 '13 at 18:12
On one hand, if you find that 2311 is not divisible by any number from 2 to 48, you have proved that it's prime. On the other hand, 2312 is divisible by 2 so you will find that it's composite immediately. – Joni Sep 22 '13 at 18:14
Yes, I get it now! Thanks! – Andro Sep 22 '13 at 18:19
in fortran you can not count on those conditionals being evaluated in the listed order or on the compiler skipping the remaining .or. conditions after one returns false. Your improvement could actually make things worse by computing mod3,5,7..on an even number... – agentp Sep 23 '13 at 4:09

The multiples of 2, 3, 5, and 7 are quickly rejected by the original algorithm anyway, so jumping over them does not improve the performance at all. Where the algorithm spends most of its time is in proving that numbers with large prime factors are composite. To radically improve the performance you should use a better primality test, such as Miller-Rabin.

A simpler improvement is testing factors only up to sqrt(num), not num-1. If that doesn't make immediate sense, think about how big the smallest prime factor of a composite number can be. Also, if you are looking for primes from 1 to N, it may be more efficient to use a prime number sieve, or testing divisibility only by primes you have already found.

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I just recently coded something similar ;-)

! Algorithm taken from https://en.wikipedia.org/wiki/Sieve_of_Eratosthenes
subroutine eratosthenes_sieve(n, primes)
implicit none
integer,intent(in)    :: n
integer,allocatable,intent(out)   :: primes(:)
integer               :: i, j, maxPrime, stat
logical               :: A(n)

maxPrime = floor(sqrt(real(n)))
A = .true.

do i=2,maxPrime
j = i*i
do
A(j) = .false.
j = j + i ; if ( j .gt. n ) exit
enddo
enddo !i

allocate( primes( count(A)-1 ), stat=stat )
if ( stat /= 0 ) stop 'Cannot allocate memory!'

j = 1
do i=2,n ! Skip 1
if ( .not. A(i) ) cycle
primes( j ) = i
j = j + 1 ; if ( j > size(primes) ) exit
enddo
end subroutine

This algorithm gives you all prime numbers up to a certain number, so you can easily check whether your prime is included or not:

if ( any(number == prime) ) write(*,*) 'Prime found:',number
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