Actually, all of this make sense.

Because *0.8* cannot be represented exactly by any series of `1 / 2 ** x`

for various `x`

, it must be represented approximately, and it happens that this is slightly less than *10015.8.*

So, when you just print it, it is rounded reasonably.

When you convert it to an integer without adding *0.5,* it truncates *.79999999...* to *.7*

When you type in *10001580.0,* well, that has an *exact* representation in all formats, including float and double. So you don't see the truncation of a value ever so slightly less than the next integral step.

Floating point is not inaccurate, it just has limitations on what can be represented. Yes, FP is *perfectly accurate* but cannot necessarily represent every number we can easily type in using base *10.* (Update/clarification: well, ironically, it can represent exactly every integer, because every integer has a `2 ** x`

composition, but "every fraction" is another story. Only certain decimal fractions can be exactly composed using a `1/2**x`

series.)

In fact, JavaScript implementations use floating point storage and arithmetic for all numeric values. This is because FP hardware produces exact results for integers, so this got the JS guys 52-bit math using existing hardware on (at the time) almost-entirely 32-bit machines.