The number is well past the limit of int on positive side.
You can run following codes to know the limits on integers in your OS

**C:**

```
#include <limits.h>
const int min_int = INT_MIN;
const int max_int = INT_MAX;
```

**C++:**

```
#include <limits>
const int min_int = std::numeric_limits<int>::min();
const int max_int = std::numeric_limits<int>::max();
```

**What you need to do:**

Choose another data type like `double`

. You can also choose something like `long int`

or simply `long`

or `size_t`

or `int64_t`

which are each at least 64 bits.

For comparison:

- signed int: -32767 to 32767
- unsigned int: 0 to 65535
- signed long:-2147483647 to 2147483647
- unsigned long: 0 to 4294967295

**Why negative?**

The negative number happens because a typical `signed int`

lies between `-32767 to 32767`

and then 32767 is represented as overflow. So this will be a negative number after truncating the overflow.

Also note that the `sizeof`

a type is determined by the compiler,
which doesn't have to have anything to do with the actual hardware
(though it typically does); in fact, different compilers on the same
machine can have different values for these.

`10000000000`

is larger than a 32-bit value (`0x2540BE400`

), so`int`

won't hold it. You're getting something different in`n`

. – lurker Feb 25 '14 at 12:21`%`

is the "remainder" operator. The subtle difference are most apparent when at least one of the operands is negative. – chux Feb 25 '14 at 15:07