I must be missing something with my understanding of precision here, but I thought that R could represent numbers along a grid with step size `.Machine$double.eps`

, but this appears not to be the case; in fact:

```
90 - .Machine$double.eps == 90
# [1] TRUE
```

This is strange to me because these two numbers (1) can be represented and (2) are non-zero:

```
sprintf('%.16a', c(90, .Machine$double.eps))
# [1] "0x1.6800000000000000p+6" "0x1.0000000000000000p-52"
```

The first place where the difference is numerically non-zero is even more suggestive:

```
90 - 32*.Machine$double.eps < 90
# [1] FALSE
90 - 33*.Machine$double.eps < 90
# [1] TRUE
```

This kind of result points straight to precision issues but there's some gap in my understanding here...

If `90 - .Machine$double.eps == 90`

, why isn't `double.eps`

larger on my machine?

The results here suggest to me that actually I should have `.Machine$double.eps == 2^5 * .Machine$double.eps`

...

`.1 + .2 != .3`

. – MichaelChirico Dec 7 at 7:44`.Machine$double.eps`

away. Try with`91*.Machine$double.eps`

- this should give you a difference. (This is clearly a aspect of floating point representation!) Eventually read the definition of a machine.eps: it is the lowest value`eps`

for which`1+eps`

is not`1`

– jogo Dec 7 at 7:441, which for 64 bit floating point is about 2.22e-16. The spacing at 90 is about 1.421e-14. – Warren Weckesser Dec 7 at 8:20"...90 and eps are too far apart."You might be thinking about this the wrong way. Instead of thinking of values being "sent" somewhere, look at what is actually going on: the space between 90 and the next floating point number just below 90 is more than twice the size of`.Machine$double.eps`

. So the number that is closest to`90 - .Machine$double.eps`

that is representable as a 64 bit floating point number is 90. – Warren Weckesser Dec 7 at 8:45