I've always done `round(f * 255.0)`

.

There is no need for the testing (special case for 1) and/or clamping in other answers. Whether this is a desirable answer for your purposes depends on whether your goal is to match input values as closely as possible [my formula], or to divide each component into 256 equal intervals [other formulas].

The possible downside of my formula is that the 0 and 255 intervals only have half the width of the other intervals. Over years of usage, I have yet to see any visual evidence that that is bad. On the contrary, I've found it preferable to not hit either extreme until the input is quite close to it - but that is a matter of taste.

The possible upside is that [I believe] the *relative* values of R-G-B components are (slightly) more accurate, for a wider range of input values.

Though I haven't tried to prove this, that is my intuitive sense, given that for each component I round to get the closest available integer. (E.g. I believe that if a color has G ~= 2 x R, this formula will more often stay close to that ratio; though the difference is quite small, and there are many other colors that the `256`

formula does better on. So it may be a wash.)

In practice, either `256`

or `255`

-based approaches seem to provide good results.

**Another way to evaluate** `255`

vs `256`

, is to examine the *other* direction -

converting from 0..255 byte to 0.0..1.0 float.

The formula that converts 0..255 integer values to equally spaced values in range 0.0..1.0 is:

```
f = b / 255.0
```

Going in this direction, there is no question as to whether to use `255`

or `256`

: the above formula *is* the formula that yields equally spaced results. Observe that it uses `255`

.

To understand the relationship between the `255`

formulas in the two directions, consider this diagram, if you only had 2 bits, hence values integer values 0..3:

Diagram using `3`

for two bits, analogous to `255`

for 8 bits. Conversion can be from top to bottom, or from bottom to top:

```
0 --|-- 1 --|-- 2 --|-- 3
0 --|--1/3--|--2/3--|-- 1
1/6 1/2 5/6
```

The `|`

are the boundaries between the 4 ranges. Observe that in the interior, the float values and the integer values are at the midpoints of their ranges. Observe that the *spacing* between all values is constant in both representations.

If you grasp these diagrams, you will understand why I favor `255`

-based formulas over `256`

-based formulas.

**Claim**: If you use `/ 255.0`

when going *from* byte to float, but you don't use `round(f * 255.0)`

when going *to* byte from float, **then the "average round-trip" error is increased**. Details follow.

This is most easily measured by starting from float, going to byte, then back to float. For a simple analysis, use the 2-bit "0..3" diagrams.

Start with a large number of float values, evenly spaced from 0.0 to 1.0.
THe round-trip will group all these values at the `4`

values.

The diagram has 6 half-interval-length ranges:

0..1/6, 1/6..1/3, .., 5/6..1

For each range, the average round-trip error is half the range, so `1/12`

(Minimum error is zero, maximum error is 1/6, evenly distributed).

All the ranges give that same error; `1/12`

is the overall average error when round trip.

If you instead use any of the `* 256`

or `* 255.999`

formulas, *most* of the round-trip results are the same, but a few are moved to the adjacent range.

**Any change to another range increases the error**; for example if the error for a single float input previously was slightly *less* than 1/6, returning the center of an adjacent range results in an error slightly *more* than 1/6. E.g. 0.18 in optimal formula => byte 1 => float 1/3 ~= 0.333, for error |`0.33-0.18|`

= `0.147`

; using a `256`

formula => byte 0 => float 0 , for error `0.18`

, which is an increase from the optimal error `0.147`

.

Diagrams using `* 4`

with `/ 3`

. Conversion is from one line to the next.

Notice the uneven spacing of the first line: 0..3/8, 3/8..5/8, 5/8..1. Those distances are 3/8, 2/8, 3/8.
Notice the interval boundaries of last line are different than first line.

```
0------|--3/8--|--5/8--|------1
1/4 1/2 3/4
=> 0------|-- 1 --|-- 2 --|------3
=> 0----|---1/3---|---2/3---|----1
1/6 1/2 5/6
```

The only way to avoid this increased error, is to use some different formula when going from byte to float. If you strongly believe in one of the `256`

formulas, then I'll leave it to you to determine the optimal inverse formula.

(Per byte value, it should return the midpoint of the float values which became that byte value. Except 0 to 0, and 3 to 1. Or perhaps 0 to 1/8, 3 to 7/8! In the diagram above, it should take you from middle line back to top line.)

But now you will have the difficult-to-defend situation that you have taken equally-spaced byte values, and converted them to non-equally-spaced float values.

**Those are your options if you use any value other than exactly **`255`

, for integers 0..255: Either an increase in average round-trip error, or non-uniformly-spaced values in the float domain.

`0.9999`

is extremely close to`1.0`

, and should definitely be converted to`255`

. Any solution that fails to do so would be wrong.`* 256`

or`*255.999`

. (Though in practice, its usually not significant - the accepted answer's formula is fine. Its also fine to substitute`255.999`

for`256`

in that answer. My analysis shows that neither of those is optimal - any change from the optimal formula increases the error for some values - but the error increase is minor.)summarizedthe benefits and drawbacks of the top 3 methods in this answer.