Unsigned integer normalization is based on the formula `f = i/INT_MAX`

, where `f`

is the floating point value (after clamping to [0, 1]), `i`

is the integer value, and `INT_MAX`

is the maximum integer value for the integer's bitdepth (255) in this case.

So if you have a float, and want the unsigned, normalized integer value of it, you use `i = f * INT_MAX`

. Of course... integers do not have the same precision as floats. So if the result of `f * INT_MAX`

is 0.5, what is the integer value of that? It could be 0, or it could be 1, depending on how things are rounded.

Implementations are permitted to round integer values in any way they prefer. They are encouraged to use nearest rounding (the post-conversion 0.49 would become 0, and 0.5 would become 1), but that is *not a requirement*. The only requirements are that it must pick one of the two nearest values (it can't turn 0.5 into 3) and that the exact floating-point values of 0.0 and 1.0 (which includes any values clamped to them) must be exactly represented as integer 0 and `INT_MAX`

.

If you have an explicit *need* to have direct rounding, you can always do the normalization yourself. In fact, GLSL has specific functions to help you. The following assumes that you are trying to write to a texture with the Vulkan format `R8G8B8A8_UNORM`

, and we're assuming you're writing to a storage image, not via outputs from the fragment shader (you can do that too, but you lose blending).

So, step 1 is to change your `layout`

format to be `r32ui`

. That is, you are now writing an unsigned 32-bit value, rather than 4 unsigned 8-bit normalized values. That's perfectly valid.

Step 2 is to employ the `packUNorm4x8`

function. This function does float-to-integer normalization, but the specification *explicitly* performs rounding correctly. Use the return value of that function in your `imageStore`

function, and you're fine.

If you want to write to a fragment shader output, that's a bit more complex. There, you will need to use a different image view, one that uses the `R32_UINT`

format. So you're creating a 32-bit unsigned integer view of a 4x8-bit normalized texture. That has to become a render target, so you're going to have to do subpass surgery. From there, just write the result of `packUNorm4x8`

.

Of course, you immediately lose blending and similar operations, since you're writing integers values. And since you had to do that subpass surgery, it's likely that any shader writing to it will need to do this too.

Also, note that in both cases, you will likely need to adjust the order of the components of the value you write. `packUNorm4x8`

is explicitly defined to be little endian, whereas (I believe?) `R8G8B8A8`

is specified to be in that order, most-significant to least. So you'll probably need to essentially do endian swapping with `packUNorm4x8(value.abgr)`

.