For `i > b`

, we have `b % i == b`

, so that part of the sum is easily calculated in constant time (`(a-b)*b`

, if `a >= b`

, 0 otherwise).

The part for `i <= b`

remains to be calculated (`i == b`

gives 0, thus may be ignored). You can do that in O(sqrt(b)) steps,

- For
`i <= sqrt(b)`

, calculate `b % i`

and add to sum
- For
`i > sqrt(b)`

, let `k = floor(b/i)`

, then `b % i == b - k*i`

, and `k < sqrt(b)`

. So for `k = 1`

to `ceiling(sqrt(b))-1`

, let `hi = floor(b/k)`

and `lo = floor(b/(k+1))`

. There are `hi - lo`

numbers `i`

such that `k*i <= b < (k+1)*i`

, the sum of `b % i`

for them is `sum_{ lo < i <= hi } (b - k*i) = (hi - lo)*b - k*(hi-lo)*(hi+lo+1)/2`

.

If `a <= sqrt(b)`

, only the first bullet applies, stopping at `a`

. If `sqrt(b) < a < b`

, in the second bullet, run from `k = floor(b/a)`

to `ceiling(sqrt(b))-1`

and adjust the upper limit for the smallest `k`

to `a`

.

Overall complexity O(min(a,sqrt(b))).

Code (C):

```
#include <stdlib.h>
#include <stdio.h>
#include <math.h>
unsigned long long usqrt(unsigned long long n);
unsigned long long modSum(unsigned long long a, unsigned long long b);
int main(int argc, char *argv[]){
unsigned long long a, b;
b = (argc > 1) ? strtoull(argv[argc-1],NULL,0) : 10000;
a = (argc > 2) ? strtoull(argv[1],NULL,0) : b;
printf("Sum of moduli %llu %% i for 1 <= i <= %llu: %llu\n",b,a,modSum(a,b));
return EXIT_SUCCESS;
}
unsigned long long usqrt(unsigned long long n){
unsigned long long r = (unsigned long long)sqrt(n);
while(r*r > n) --r;
while(r*(r+2) < n) ++r;
return r;
}
unsigned long long modSum(unsigned long long a, unsigned long long b){
if (a < 2 || b == 0){
return 0;
}
unsigned long long sum = 0, i, l, u, r = usqrt(b);
if (b < a){
sum += (a-b)*b;
}
u = (a < r) ? a : r;
for(i = 2; i <= u; ++i){
sum += b%i;
}
if (r < a){
u = (a < b) ? a : (b-1);
i = b/u;
l = b/(i+1);
do{
sum += (u-l)*b;
sum -= i*(u-l)*(u+l+1)/2;
++i;
u = l;
l = b/(i+1);
}while(u > r);
}
return sum;
}
```