`pow`

returns a double, and with doubles you must always worry about precision. The product `number * pow(...)`

may not return *exactly* 1. It could be 0.99 or something else that's almost 1 but not quite. When this value gets assigned back to the unsigned integer `number`

, it would get demoted to become an int, and rounded down to 0.

To get around this, you can always implement your own `pow`

function with integers. I'd recommend implementing with longs, though, because your integers can overflow fast (e.g. base = 50, exponent = 6 easily exceeds 32-bits typically allotted to ints).

See answers to this SO question for more details on the `pow`

issue.

**Wait, what's precision?**

Many numbers cannot be expressed with a finite binary representation. The `float`

type is one such finite binary representation. A float can only store a certain number of bits of information (which you can think of as precision), so any bits that don't fit are discarded. This loss of information is why floating point numbers can have errors like these. You can read more about this here.

`#include <math.h>`

? I got the correct answer. – unxnut Jan 11 '14 at 2:15`pow`

will necessarily be an approximation. It's unlikely that multiplying this approximation by 1000000000 will yield exactly 1. – R.. Jan 11 '14 at 2:25`number = round(number * pow(10, -9));`

to avoid fraction truncation and get round to nearest. – chux - Reinstate Monica Jan 11 '14 at 3:30