Colour values aren't just added.

When you plot a colour `X`

on top of a colour `Y`

, the value of each colour channel of the resulting colour, `C`

, is given by:

```
C = X * a + Y * (a-1)
```

Using the floating point representation (each channel is a value from 0 to 1); where `a`

is the alpha channel of `X`

. (It's easily converted back to 0-255).

For white, `Y`

is 1 for all channels, so:

```
C = X * a + (a-1)
```

So, if `a`

is 0, you clearly can't find X, which makes sense: If the colour was totally transparent, it makes no difference to the combined colour.

Similarly, if your colour was white (`X`

=1), you couldn't determine the alpha (the combined colour would be white regardless of the alpha).

Also, you can't find either `X`

or `a`

without knowing the other.

If you knew the alpha of the colour, then you could determine what the colour was, but if your combined colour (`C`

) is a discrete value (such as an integer from 0 to 255), then it is rounded, so you can only get an approximation of the plotted colour (`X`

). How accurate it is depends on the alpha (the more transparent the plotted colour was, the less accurately you can determine the colour).

So, solving for X:

```
X * a = C - a - 1
Therefore: X = (C - a - 1 ) / a
```

For 8-bit colour channels (24-bit colour):

```
X = 255 * ( C/255 - a/255 - 1 ) / (a/255)
```

(Given a 6-digit hexadecimal value, apply this for each pair of digits, `C`

).

You could optimise it to avoid the floating point calculation.

I don't know if that's any use, but that's all you can do.