0.2 is not a double precision floating-point number, so it is rounded to the nearest double precision number, which is:

```
0.200000000000000011102230246251565404236316680908203125
```

That's rather unwieldy, so let's look at it in hex instead:

```
0x0.33333333333334
```

Now, let's follow what happens when this value is repeatedly subtracted from 1.0:

```
0x1.00000000000000
- 0x0.33333333333334
--------------------
0x0.cccccccccccccc
```

The exact result is not representable in double precision, so it is rounded, which gives:

```
0x0.ccccccccccccd
```

In decimal, this is exactly:

```
0.8000000000000000444089209850062616169452667236328125
```

Now we repeat the process:

```
0x0.ccccccccccccd
- 0x0.33333333333334
--------------------
0x0.9999999999999c
rounds to 0x0.999999999999a
(0.600000000000000088817841970012523233890533447265625 in decimal)
0x0.999999999999a
- 0x0.33333333333334
--------------------
0x0.6666666666666c
rounds to 0x0.6666666666666c
(0.400000000000000077715611723760957829654216766357421875 in decimal)
0x0.6666666666666c
- 0x0.33333333333334
--------------------
0x0.33333333333338
rounds to 0x0.33333333333338
(0.20000000000000006661338147750939242541790008544921875 in decimal)
0x0.33333333333338
- 0x0.33333333333334
--------------------
0x0.00000000000004
rounds to 0x0.00000000000004
(0.000000000000000055511151231257827021181583404541015625 in decimal)
```

Thus, we see that the accumulated rounding that is required by floating-point arithmetic produces the very small **non-zero** result that you are observing. Rounding is subtle, but it is deterministic, not magic, and not a bug. It's worth taking the time to learn about.