I haven't seen this in action, but it looks like they're using chroma rather than saturation, and have mapped lightness and chroma to (sort-of) polar co-ordinates. So the chroma varies with the distance from the center and the value/brightness varies with the y-coordinate.
Essentially the result is that the middle of the circle is bright, fully saturated colour, and the edge is a greyscale. Colours are linearly interpolated from center to edge.
I originally thought this might be straight polar co-ordinates, but I suspect it's been simplified to just use y instead of the angle.
Essentially, the de-saturated greyscale at the edge is a linear white to black gradient, top to bottom (not varying with angle as a polar co-ordinate would). The colour at the center is a saturated colour chosen with the hue selector at the side, and then all colours in between are linearly interpolated.
So in pseudo-code:
let x, y be points in the circle, range -1 to 1.
let red, grn, blu be the center colour value.
let lerp(a, b, t) = (a * (1 - t) + b * t)
r = sqrt(x * x + y *y) // calculate radial co-ordinate
// reject points r > 1 (outside circle)
grey_value = (y + 1) / 2 // calculate de-saturated value, 0 to 1.
final_red = lerp(red, grey_value, r) // lerp the RGB from the center to the edge.
final_grn = lerp(grn, grey_value, r)
final_blu = lerp(blu, grey_value, r)
Obviously thats not particularly optimal and won't draw nice anti-aliased edges. It would probably be much faster to pre-calculate a texture with a greyscale gradient, and an alpha mask based on 'r', which can be alpha-blended on top of a flat-coloured circle.