This is guaranteed by the construction of IEEE-754 numbers. (To be clear: C does not guarantee IEEE-754, but the following analysis holds for all other floating-point formats with which I am familiar as well; the crucial property is that all sufficiently large numbers in the format are integers).

Recall that a normal IEEE-754 number has the form `±1.xxx...xxx * 2^n`

, where the width of the significand field (the `xxx...xxx`

part) is defined by the type of the number (23 binary digits for single precision, 52 binary digits for double precision). All such numbers with an exponent (`n`

) within the allowed range are representable.

Assume WLOG that `v`

is positive (if `v`

were negative, we could swap `ceil`

and `floor`

in the following analysis).

Let `v`

have `k`

significant bits, and write `v`

out as a binary fixed point number; there are three possibilities:

Case 1: All significand bits are integral. When we write out `v`

, it looks like this

```
xxxxxxxxxxxxxxxxxxxxxxxx000000...00000.0
```

then `v`

is an integer, and so `ceil(v) = floor(v) = v`

, and so both are trivially representable.

Case 2: All significand bits are fractional. When we write out `v`

, it looks like

```
0.000000...00000xxxxxxxxxxxxxxxxxxxxxxxx
```

then `v`

is in the range [0,1), and so `floor(v) = 0`

, which is representable, and `ceil(v)`

is either zero or one, both of which are representable.

Case 3: `v`

contains both integral and fractional significand bits:

```
xxxxxxxxxxxxxx.xxxxxxxxxx
```

then `floor(v)`

is just:

```
xxxxxxxxxxxxxx.
```

because we have thrown away at least one fractional bit, `floor(v)`

has at most `k-1`

significant bits, and the same exponent as `v`

, so it is representable.

If `v`

is an integer, then `ceil(v) = floor(v) = v`

, so `ceil(v)`

is representable. Otherwise, `ceil(v) = floor(v) + 1`

, and so also has at most `k-1`

significant bits and is also representable.