The problem is here:
(Though you should be sure to always initialize your variables, e.g.
s=0 before the loop.)
Integers don't have a special value for when the number gets larger than the storage type, so they overflow.
Here's an example of that could happen. Imagine that we store integers as a series of 4 bits where the first bit means that a number is negative. If we then begin counting in our system, we get the following:
0000 = 0
0001 = 1
0010 = 2
0011 = 3
0100 = 4
0101 = 5
0110 = 6
0111 = 7
1000 = -0
1001 = -1
1010 = -2
So you can see that the numbers keep on growing inside the computer, but what they translate to suddenly becomes negative when the most significant bit is flipped on.
Computers use all kinds of different schemes for storing negative numbers, but Two's Complement is common. It's more clever than the system I've used to explain things here, but the essential point remains the same: when numbers get too big they become negative. In the case of an
int the cross-over point is often when you hit
2^31, or 2147483648.
A workaround is to use
unsigned int, which roughly doubles the largest number you can represent, or
unsigned long, or
unsigned long long. Remember, this won't solve your problem, it will just give you larger numbers you can work with before a problem appears.
You can find the largest usable value using the
limits.h header file; for an
int it is