It depends on the definition of "functional". I would say that a "functional" function means that it always returns the same result for the same parameters and that it doesn't modify any global state (or the value of parameters if they are mutable). I think this is a sensible definition for F#, but it also means that there is nothing "dis-functional" with using mutation locally.

In my point of view, the following function is "functional", because it creates and returns a new matrix instead of modifying an existing one, but of course, the implementation of the function uses mutation.

```
let performStep m =
let res = Matrix.Generic.create 6 6 []
let pos = [(1.3,4.3); (5.6,5.4); (1.5,4.8)]
for pz, py in pos do
let z, y = int pz, int py
res.[z,y] <- (pz,py) :: m.[z,y]
res
```

**Mutation-free version:**
Now, if you wanted to make the implementation fully functional, then I would start by creating a matrix that contains `Some(pz, py)`

in the places where you want to add the new list element to the element of the matrix and `None`

in all other places. I guess this could be done by initializing a sparse matrix. Something like this:

```
let sp = pos |> List.map (fun (pz, py) -> int pz, int py, (pz, py))
let elementsToAdd = Matrix.Generic.initSparse 6 6 sp
```

Then you should be able to combine the original matrix `m`

with the newly created `elementsToAdd`

. This can be certainly done using `init`

(however, having something like `map2`

would be maybe nicer):

```
let res = Matrix.init 6 6 (fun i j ->
match elementsToAdd.[i, j], m.[i, j] with
| Some(n), res -> n::res
| _, res -> res )
```

There is still quite likely some mutation hidden in the F# library functions (such as `init`

and `initSparse`

), but at least it shows one way to implement the operation using more primitive operations.

**EDIT:** This will work only if you need to add at most single element to each matrix cell. If you wanted to add multiple elements, you'd have to group them first (e.g. using `Seq.groupBy`

)