Note that your formula isn't correct as it omits the
+0.5 needed to get round-to-nearest.
So I'll proceed assuming this corrected formula:
(unsigned long long)( ((double)partialSize)/((double)totalSize) * 100.0 + 0.5);
As I've mentioned in the comments, the straight-forward method, although simple, is not guaranteed to correctly rounded results. So your intuition is right in that it is not bullet-proof.
In the vast majority of cases, it will still be correct, but there will be a small set of borderline cases where it won't be correctly rounded. Whether or not those matter is up to you. But the straight-forward method is usually sufficient for most purposes.
Why it may fail:
There are 4 levels of rounding. (corrected from the 2 that I mentioned in the comments)
- The casts 64-bits -> 53-bits
- The division
- The multiply by 100.
- The final cast.
Whenever you have multiple sources of rounding, you suffer from the usual sources of floating-point error.
Although rare, I'll list a few examples where the straight-forward formula will give an incorrectly rounded result:
850536266682995018 / 3335436339933313800 // Correct: 25% Formula: 26%
3552239702028979196 / 10006309019799941400 // Correct: 35% Formula: 36%
1680850982666015624 / 2384185791015625000 // Correct: 70% Formula: 71%
I can't think of a clean 100% bullet-proof solution to this other than to use arbitrary precision arithmetic.
But in the end, do you really need it to always be perfectly rounded?
For smaller numbers, here's a very simple solution that rounds up on
return (x * 100 + y/2) / y;
This will work as long as
x * 100 + y/2 doesn't overflow.
@Daniel Fischer answer has a more comprehensive solution for the other rounding behaviors. Though it shouldn't be too hard to modify this one to get round-to-even.