Here it seems the inpainting task is combined with some blurring filter, so it looks like we need a filter kernel that is at least as big as the largest "hole", is that correct?

@flawr Yes, that's right. And then you want to use only the part of the result that fills the hole, so that the rest of the picture doesn't become blurry.

@flawr This makes quite a lot of mathematical sense, I think. If you random sample, then "scattering" those values around is close to an adjoint operation, and the convolution does that for you

@flawr problem is that you'd need shitton of data to propose the solution, no?

I am not sure if anyone tried it, but my PI did her PhD and wrote a book in PDE based inpaiting. Performance-wise they are not great nowadays, but they are great mathematically

@flawr maybe some of that nosie2self kind of stuff also works for inpainting. The self-supervised stuff. Who knows

@flawr I was just trying it out. Indeed, the results are not at all great. But it does work. Ideally you want a small sigma, so you smooth less, but a larger kernel, so you spread information as far as possible. The holes in the question are quite large, so you end up having to do multiple iterations if using a Gaussian kernel. And that detracts from the simplicity of the operation. So now you've got a not simple operation that is not good... :)

Here you can see what it does with sigma=1. Stuff at the edges of the hole is propagated straight inward.

With a larger sigma it looks a little bit like the solution that uses cv2.inpaintcodegolf.stackexchange.com/a/71787/91877 -- mostly because we're propagating from the edges and meet in the middle, leaving a sharper edge there.