I'm trying to solve the problem PRIME1 using segmented sieve of Eratosthenes. My program works correctly with the normal sieve that is up to `NEW_MAX`

. But there is some problem with cases `n > NEW_MAX`

, where segmented sieving comes into play. In such cases it merely prints all the numbers. Here is the link to the code with relevant test cases: http://ideone.com/8H5lK#view_edit_box

```
/* segmented sieve */
#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#define MAX_LIMIT 1000000000 //10^9
#define NEW_MAX 31623 /*SQUARE ROOT OF 1000000000*/
#define MAX_WIDTH 100000 //10^5
char flags[NEW_MAX+100]; /*TO PREVENT SEGMENTATION FAULT*/
void initialise(char flagarr[], long int n) //initialise all elements to true from 1 to n
{
long int i;
for (i = 1; i <= n; i++)
flagarr[i] = 't';
}
void sieve(unsigned long long m, unsigned long long n, char seg_flags[])
{
unsigned long long p, i, limit;
if (m == 1)
seg_flags[1] = 'f';
/*Seperate inner loop for p=2 so that evens are not iterated*/
for (i = 4; i >= m && i <= n; i += 2)
{
seg_flags[i-m+1] = 'f';
}
if (seg_flags == flags)
limit = NEW_MAX;
else
limit = sqrt(n);
for (p = 3; p <= limit+1; p += 2) //initial p+=2 bcoz we need not check even
{
if (flags[p] == 't')
{
for (i = p*p; i >= m && i <= n; i += p) //start from p square since under it would have been cut
seg_flags[i-m+1] = 'f'; /*p*p, p*p+p, p*p + 2p are not primes*/
}
}
}
void print_sieve(unsigned long long m,unsigned long long n,char flagarr[])
{
unsigned long long i;
if (flags == flagarr) //print non-segented sieve
{
for (i = m; i <= n; i++)
if (flagarr[i] == 't')
printf("%llu\n", i);
}
else
{
//print segmented
for (i = m; i <= n; i++)
if (flagarr[i-m+1] == 't')
printf("%llu\n", i);
}
}
int main()
{
unsigned long long m, n;
int t;
char seg_flags[MAX_WIDTH+100];
/*setting of flags for prime nos. by sieve of erasthromas upto NEW_MAX*/
initialise(flags, NEW_MAX);
flags[1] = 'f'; /*1 is not prime*/
sieve(1, NEW_MAX, flags);
/*end of initial sieving*/
scanf("%d", &t);
while (t--)
{
scanf("%llu %llu", &m, &n);
if (n <= NEW_MAX)
print_sieve(m, n, flags); //NO SEGMENTED SIEVING NECESSARY
else if (m > NEW_MAX)
{
initialise(seg_flags, n-m+1); //segmented sieving necessary
sieve(m, n, seg_flags);
print_sieve(m, n, seg_flags);
}
else if (m <= NEW_MAX && n > NEW_MAX) //PARTIAL SEGMENTED SIEVING NECESSARY
{
print_sieve(m, NEW_MAX, flags);
/*now lower bound for seg sieving is new_max+1*/
initialise(seg_flags, n-NEW_MAX);
sieve(NEW_MAX+1, n, seg_flags);
print_sieve(NEW_MAX+1, n, seg_flags);
}
putchar('\n');
}
system("pause");
return 0;
}
```

Update: Thanks fr your response Daniel. I implemented some of ur suggestions, my code now produces correct output :-

```
/*segmented sieve*/
#include<math.h>
#include<stdio.h>
#include<stdlib.h>
#define MAX_LIMIT 1000000000 /*10^9*/
#define NEW_MAX 31623 /*SQUARE ROOT OF 1000000000*/
#define MAX_WIDTH 100000 /*10^5*/
int flags[NEW_MAX+1]; /*TO PREVENT SEGMENTATION FAULT goblal so initialised to 0,true*/
void initialise(int flagarr[],long int n)
/*initialise all elements to true from 1 to n*/
{
long int i;
for(i=3;i<=n;i+=2)
flagarr[i]=0;
}
void sieve(unsigned long m,unsigned long n,int seg_flags[])
{
unsigned long p,i,limit;
/*Seperate inner loop for p=2 so that evens are not iterated*/
if(m%2==0)
i=m;
else
i=m+1;
/*i is now next even > m*/
for(;i<=n;i+=2)
{
seg_flags[i-m+1]=1;
}
if(seg_flags==flags)
limit=NEW_MAX;
else
limit=sqrt(n);
for(p=3;p<=limit+1;p+=2) /*initial p+=2 bcoz we need not check even*/
{
if(flags[p]==0)
{
for(i=p*p; i<=n ;i+=p)
/*start from p square since under it would have been cut*/
{
if(i<m)
continue;
seg_flags[i-m+1]=1;
/*p*p, p*p+p, p*p + 2p are not primes*/
}
}
}
}
void print_sieve(unsigned long m,unsigned long n,int flagarr[])
{
unsigned long i;
if(m<3)
{printf("2\n");m=3;}
if(m%2==0)
i=m+1;
else
i=m;
if(flags==flagarr) /*print non-segented sieve*/
{
for(;i<=n;i+=2)
if(flagarr[i]==0)
printf("%lu\n",i);
}
else {
//print segmented
for(;i<=n;i+=2)
if(flagarr[i-m+1]==0)
printf("%lu\n",i);
}}
int main()
{
unsigned long m,n;
int t;
int seg_flags[MAX_WIDTH+100];
/*setting of flags for prime nos. by sieve of erasthromas upto NEW_MAX*/
sieve(1,NEW_MAX,flags);
/*end of initial sieving*/
scanf("%d",&t);
while(t--)
{
scanf("%lu %lu",&m,&n);
if(n<=NEW_MAX)
print_sieve(m,n,flags);
/*NO SEGMENTED SIEVING NECESSARY*/
else if(m>NEW_MAX)
{
initialise(seg_flags,n-m+1);
/*segmented sieving necessary*/
sieve(m,n,seg_flags);
print_sieve(m,n,seg_flags);
}
else if(m<=NEW_MAX && n>NEW_MAX)
/*PARTIAL SEGMENTED SIEVING NECESSARY*/
{
print_sieve(m,NEW_MAX,flags);
/*now lower bound for seg sieving is new_max+1*/
initialise(seg_flags,n-NEW_MAX);
sieve(NEW_MAX+1,n,seg_flags);
print_sieve(NEW_MAX+1,n,seg_flags);
}
putchar('\n');
}
system("pause");
return 0;
}
```

but my sieve function below further taking into account ur other suggestions produces incorrect output:-

```
void sieve(unsigned long m,unsigned long n,int seg_flags[])
{
unsigned long p,i,limit;
p=sqrt(m);
while(flags[p]!=0)
p++;
/*we thus get the starting prime, the first prime>sqrt(m)*/
if(seg_flags==flags)
limit=NEW_MAX;
else
limit=sqrt(n);
for(;p<=limit+1;p++) /*initial p+=2 bcoz we need not check even*/
{
if(flags[p]==0)
{
if(m%p==0) /*to find first multiple of p>=m*/
i=m;
else
i=(m/p+1)*p;
for(; i<=n ;i+=p)
/*start from p square since under it would have been cut*/
{
seg_flags[i-m+1]=1;
/*p*p, p*p+p, p*p + 2p are not primes*/
}
}
}
}
```