# count distinct prime factors

I have to count number of distinct prime factors over 2 to 100000, Is there any fast method than what I am doing ? i.e.. 2 has 1 distinct prime factor 2 10 has 2 distinct prime factor (2,5) 12 has 2 distinct prime factor (2,3) My code :-

``````#include<stdio.h>
#include<math.h>
typedef unsigned long long ull;
char prime[100000]={0};
int P[10000],fact[100000],k;

void sieve()
{
int i,j;
P[k++]=2;
for(i=3;i*i<1000;i+=2)
{
if(!prime[i])
{
P[k++]=i;
for(j=i*i;j<100000;j+=i+i)
prime[j] = 1;
}
}
for(i=1001;i<100000;i+=2)
if(!prime[i])
P[k++]=i;
}

int calc_fact() {
int root,i,count,j;
fact[1]=fact[2]=fact[3]=1;
for(i=4;i<=100000;i++) {
count=0;
root=i/2+1;
for(j=0;P[j]<=root;j++) {
if(i%P[j]==0)count++;
}
if(count==0) fact[i]=1;
else fact[i]=count;
}
return 0;
}
int main(){
int i;
sieve();
calc_fact();
for(i=1;i<10000;i++) printf("%d  ,",fact[i]);
return 0;
}
``````
-

You can easily adapt the sieve of Erasthotenes to count the number of prime factors a number has.

Here's an implementation in C, along with some tests:

``````#include <stdio.h>

#define N 100000

static int factorCount[N+1];

int main(void)
{
int i, j;

for (i = 0; i <= N; i++) {
factorCount[i] = 0;
}

for (i = 2; i <= N; i++) {
if (factorCount[i] == 0) { // Number is prime
for (j = i; j <= N; j += i) {
factorCount[j]++;
}
}
}

printf("2 has %i distinct prime factors\n", factorCount[2]);
printf("10 has %i distinct prime factors\n", factorCount[10]);
printf("11111 has %i distinct prime factors\n", factorCount[11111]);
printf("12345 has %i distinct prime factors\n", factorCount[12345]);
printf("30030 has %i distinct prime factors\n", factorCount[30030]);
printf("45678 has %i distinct prime factors\n", factorCount[45678]);

return 0;
}
``````
-
BTW, the code in the answer from @v-delecroix doesn't work correctly (for example, it reports that 12345 has 4 distinct prime factors, when it has 3). (PS: I'm posting this here because of the SO reputation system) –  user2580621 Jul 14 at 9:10
Thank you for the reply –  alankrita Jul 14 at 17:24

You can definitely do better by making a sieve of Eratosthenes.

In Python

``````N = 100000
M = int(N**.5)                         # M is the floor of sqrt(N)
nb_of_fact = [0]*N
for i in xrange(2,M):
if nb_of_fact[i] == 0:             # test wether i is prime
for j in xrange(i,N,i):        # loop through the multiples of i
nb_of_fact[j] += 1
for i in xrange(M,N):
if nb_of_fact[i] == 0:
nb_of_fact[i] = 1
``````

At the end of the loop, nb_of_fact[i] is the number of prime factors of i (in particular it is 1 if and only if i is prime).

Older wrong version

``````N = 100000
nb_of_fact = [1]*N
for i in xrange(2,N):
if nb_of_fact[i] == 1:             # test wether i is prime
for j in xrange(2*i,N,i):      # loop through the multiples of i
nb_of_fact[j] += 1
``````
-
Nice, but the op asked for the number of distinct prime factors. For example, 4 has only one distinct prime factor. –  GregS Jul 14 at 17:01
As everything is initialized at 1 this is not the good answer... following @user2580621 I reviewed my code... –  V. Delecroix Jul 14 at 17:06
+1, looks very nice. It can be made more efficient by changing the first loop to stop at int(N**0.5), and then adding a final loop that goes from int(N**0.5) + 1 to N that replaces any leftover zeros with ones. –  GregS Jul 14 at 17:54
@GregS Thanks very much for making it a working code and a beautiful code! –  V. Delecroix Jul 14 at 19:29
`N//2` is bigger the than is necessary. N**0.5 (which is the same as the square root of N) is sufficient. –  GregS Jul 14 at 20:51