As Don Roby said, there is a plain old arithmetic solution to your problem. Let me show you how to do it for the first values of i.

*** EDIT 2 : CODE FOR THE LOWER PART ***

```
for(int i=m ; i<= n+1 ; i+=m)//old computation
s+=(i-1)/2 ;
int a = (n+1)/m; // maximum value of i
int b = (a*(a+1))/2; //
int v = 0;
int p;
if(m % 2 == 0){
p = m/2;
v = b*p-a; // this term is always here
}
else{
p = (m - 1)/2;
int sum1 = ((a/2)*(a/2 +1))/2;
int sum2 = (((a-1)/2)*((a-1)/2 +1))/2;
v = b*p -a ;// this term is always here
v+= sum1 + a/2; //sum( 1 <= j <= a )(j-1), j pair
v+= sum2; //sum( 1 <= j <= a )(j-1), j impair
}
System.out.println( " Are both result equals ? "+ (s == v));
```

How do I come up with it? I take

```
for(i=m ; i<= n+1 ; i+=m)
s+=(i-1)/2 ;
```

I make a change

```
for(j=1 ; j*m <= n-1 ; j++)
s+=(j*m-1)/2 ;
```

I pose `a=Math.floor(n+1/m)`

. There are 3 cases :

m is pair, then interior of the loop is `s+= p*j`

. The result is

```
b(a*(a+1))/2 -a
```

m is impair and the iterator j is pair

m is impair and the iterator j is impair
When m is impair, you can write `m = 2p + 1`

and the interior of the loop becomes

```
s+= p*j + (j-1)/2
```

`p*j`

is the same as before, now you need to break the division by assuming j is always pair or j always impair and summing both values.

The next loop you need to compute is

```
for(int i=a+1 ; i<= (2*n-1) ; i+=m)// a is (n+1)/m
s+=(2*n-i+1)/2;
```

which is the same as

```
for(int i=1 ; i<= (2*n-1)-a ; i+=m)
s+= (2n-a)/2 - (i-1)/2;
```

This loop is similar to the first one, so there is not much work to do...
Indeed this is tedious..