A quick trip out to google brought http://sourceforge.net/projects/fixedptc/ to my attention

It's a c library in a header for managing fixed point math in 32 or 64 bit integers.

A little bit of experimentation with the following code:

```
#include <stdio.h>
#include <stdint.h>
#define FIXEDPT_BITS 64
#include "fixedptc.h"
int main(int argc, char ** argv)
{
unsigned int input = 536838144; // min 0, max 1073676289
unsigned int range = 1155625; // min 0, max 1155625
// Conversion
unsigned int tmp = (input >> 16) * ((range) >> 3u);
unsigned int output = (tmp / ((1073676289) >> 16u)) << 3u;
double output2 = (double)input * ((double)range / 1073676289.0);
uint32_t output3 = fixedpt_toint(fixedpt_xmul(fixedpt_fromint(input), fixedpt_xdiv(fixedpt_fromint(range), fixedpt_fromint(1073676289))));
printf("baseline = %g, better = %d, library = %d\n", output2, output, output3);
return 0;
}
```

Got me the following results:

```
baseline = 577812, better = 577776, library = 577812
```

Showing better precision (matching the floating point) than you were getting with your code. Under the hood it's not doing anything terribly complicated (and doesn't work at all in 32 bits)

```
/* Multiplies two fixedpt numbers, returns the result. */
static inline fixedpt
fixedpt_mul(fixedpt A, fixedpt B)
{
return (((fixedptd)A * (fixedptd)B) >> FIXEDPT_FBITS);
}
/* Divides two fixedpt numbers, returns the result. */
static inline fixedpt
fixedpt_div(fixedpt A, fixedpt B)
{
return (((fixedptd)A << FIXEDPT_FBITS) / (fixedptd)B);
}
```

But it does show that you can get the precision you want. You'll just need 64 bits to do it