Yes. You can void the for loop altogether and find the sum in constant time.

According to the Inclusion–exclusion principle summing up the multiples of `x`

and multiples of `y`

and subtracting the common multiple(s) that got added *twice* should give us the required sum.

```
Required Sum = sum of ( multiples of x that are <= N ) +
sum of ( multiples of y that are <= N ) -
sum of ( multiples of (x*y) that are <= N )
```

Example:

```
N = 15
x = 3
y = 4
Required sum = ( 3 + 6 + 9 + 12 + 15) + // multiples of 3
( 4 + 8 + 12 ) - // multiples of 4
( 12 ) // multiples of 12
```

As seen above we had to subtract `12`

as it got added twice because it is a common multiple.

**How is the entire algorithm O(1)?**

Let `sum(x, N)`

be sum of multiples of `x`

which are less than or equal to `N`

.

```
sum(x,N) = x + 2x + ... + floor(N/x) * x
= x * ( 1 + 2 + ... + floor(N/x) )
= x * ( 1 + 2 + ... + k) // Where k = floor(N/x)
= x * k * (k+1) / 2 // Sum of first k natural num = k*(k+1)/2
```

Now `k = floor(N/x)`

can be computed in constant time.

Once `k`

is known `sum(x,N)`

can be computed in constant time.

So the required sum can also be computed in constant time.

**EDIT:**

The above discussion holds true only when `x`

and `y`

are co-primes. If not we need to use `LCM(x,y)`

in place of `x*y`

. There are many ways to find LCM one of which is to divide product by GCD. Now GCD cannot be computed in constant time but its **time complexity** can be made significantly lesser than linear time.