I had the same question myself, and Google brought me to this SO question, so I thought I'd do a bit of digging.

Suppose we plot

```
library(ggplot2)
ggplot(mtcars, aes(x = cyl, y = mpg, size = hp)) +
geom_point()
```

which gives us the following plot, and we wish to know how the breaks for `mpg`

(10, 15, ..., 35), `cyl`

(4, 5, ..., 8), and `hp`

(100, 150, ..., 300) are derived.

Focusing on `mpg`

we inspect the code for `scale_y_continuous`

and see that it calls `continuous_scale`

. Then, calling up `?continuous_scale`

we see, under the description for the `trans`

argument, that

A transformation object bundles together a transform, it's inverse, and methods for generating breaks and labels.

Then, looking up `?scales::trans_new`

, we see that the default value for the `breaks`

argument is `extended_breaks()`

. Following the trail, we find that `scales::extended_breaks`

calls `labeling::extended(rng[1], rng[2], n, only.loose = FALSE, ...)`

. Applying this to our data,

```
with(mtcars, labeling::extended(range(mpg)[1], range(mpg)[2], m = 5))
# [1] 10 15 20 25 30 35
```

which is what we observe in the plot. This raises the question of why, despite

```
with(mtcars, labeling::extended(range(hp)[1], range(hp)[2], m = 5))
# [1] 50 100 150 200 250 300 350
```

we don't observe 50 and 350 in the legend. My understanding is that the answer is related to https://stackoverflow.com/a/13888731/6455166.