Well, mathematically it's just:

```
min_value + (max_value - min_value) * (my_random() / (long double)ULONG_MAX)
```

(Assuming my_random() returns a uniformly distributed number between 0 and ULONG_MAX)

However, depending on the exact values of `min_value`

, `max_value`

, and `ULONG_MAX`

, some floating point numbers will almost certainly be more likely than others.

Each possible random unsigned long maps to a float by this formula. But since the number of distinct floating point numbers between `min_value`

and `max_value`

is almost certainly not exactly `ULONG_MAX`

, some unsigned longs will map to the same floating point number or some floating point numbers will have no unsigned long map to them or both.

Fixing this to make the result truly uniform is... non-trivial, I think. Maybe someone better read than I can cite a paper.

[edit]

Or see the answer to this question:

Generating random floating-point values based on random bit stream

That answer depends on the internals of the IEEE `double`

representation. I am also not sure I fully understand how it works.

[edit 2]

OK now I understand how it works. The idea is to pick a random floating point *representation* between the min and the max, and then to throw it out with probability inversely proportional to its scale as represented by its exponent. Because for a uniform distribution, numbers between (say) 1/2 and 1 need to be half as likely as those between 1 and 2, but the number of floating point representations in those ranges is the same.

I think you could make that code more efficient by first picking the exponent on a logarithmic scale -- say, by using `ffs`

on a randomly-chosen integer -- and then picking the mantissa at random. Hm...