The result you’re after might be too large to represent through a 32-bit signed integer (`int`

).

Let’s first determine the result’s upper bound by assuming that *all* numbers are prime. Through summation, we know that the sum of all numbers up to `N`

(inclusive) is `N * (N + 1) / 2`

; thus, the upper bound for the sum of all primes up to 2,000,000 is 2,000,001,000,000. This is larger than the maximum value allowed by `int`

, 2,147,483,647, so you’re probably getting a numeric overflow which is silently ignored.

If you wanted a more accurate estimate of your answer, you could use the prime number theorem, which states that the probability of a random integer between 0 and `N`

being prime is approximately `1 / ln(N)`

. Combining this with our previous formula, the approximate sum of all primes up to `N`

is `N * (N + 1) / (2 * ln(N))`

. For 2,000,000, this evaluates to around 138,000,000,000, which is still larger than the maximum value for `int`

.

To resolve your problem, you could simply switch the integral data type you’re using for the `soap`

variable to a 64-bit integer representation, such as `long`

. Its maximum value is 9,223,372,036,854,775,807, so it would definitely be able to represent your number.

```
long soap = 0;
```

On a separate note: Since you’re working with *sequences* of primes, you could achieve a huge performance gain (at least 100×) if you change your implementation to a Sieve of Eratosthenes.