I'm looking to adapt the 3D Perlin noise algorithm to lower dimensions, but I'm having trouble with the gradient function, since I don't fully understand the reasoning.

The original Perlin gradient function takes four arguments: a `hash` and a three-dimensional coordinate `(x, y, z)`. The result of the function is returned based on the value of `hash mod 16`, as listed below.

• `0`: `x + y`
• `1`: `-x + y`
• `2`: `x - y`
• `3`: `-x - y`
• `4`: `x + z`
• `5`: `-x + z`
• `6`: `x - z`
• `7`: `-x - z`
• `8`: `y + z`
• `9`: `-y + z`
• `10`: `y - z`
• `11`: `-y - z`
• `12`: `y + x`
• `13`: `-y + z`
• `14`: `y - x`
• `15`: `-y - z`

The return values from `0` to `11` make a kind of pattern, since every combination is represented once. The last four, however, are duplicates. Why were they chosen to fit the last four return values? And what would be the analagous cases with two `(x, y)` and one `(x)` dimensions?

• I still don't understand the purpose of this gradient function, even for 2D. I just use the dot product things on the 4 near vectors, I don't see what this gradient is for. – jokoon Jun 30 at 17:07
• @jokoon I was playing with a terrain generation seven years ago and this function was close to hand. Not sure what you mean by "dot product things". – Matthew Piziak Jun 30 at 21:39

The `grad` function in the "improved noise" implementation calculates a dot product between the vector x, y, z and a pseudo random gradient vector.
In this implementation, the gradient vector is selected from 12 options. They drop uniformity of the selection and add numbers 12 and 14, because it is faster to do `hash & 15` than `hash % 12`
``````return ((hash & 1) ? x : -x) + ((hash & 2) ? y : -y);