**Why is this?**

Because floating-point numbers are stored in binary, in which 0.3 is 0.01001100110011001... repeating just like 1/3 is 0.333333... is repeating in decimal. When you write 0.3, you actually get 0.299999999999999988897769753748434595763683319091796875.

Keep in mind that for the applications for which floating-point is designed, it's not a problem that you can't represent 0.3 exactly. Floating-point was designed to be used with:

- Physical measurements, which are often measured to only 4 sig figs and
*never* to more than 15.
- Transcendental functions like logarithms and the trig functions, which are only approximated anyway.

For which binary-decimal conversions are pretty much irrelevant compared to other sources of error.

Now, if you're writing financial software, for which $0.30 means *exactly* $0.30, it's different. There are decimal arithmetic classes designed for this situation.

**And how to get correct result in this case?**

Limiting the precision to 15 significant digits is usually enough to hide the "noise" digits. Unless you actually *need* an exact answer, this is usually the best approach.