# Understanding the semantics behind the code

I have an OCaml code, and I have a hard time to formalize the function `mi_pol` into Coq because I am not understand clearly what exactly this code working, for example at the

``````aux (vec_add add const (vector ci v)) args ps
``````

and

``````args.(i-1) <- mat_add add args.(i-1) (matrix ci m); aux const args ps
``````

and

``````aux (vec_0 z dim) (Array.make n (mat_0 z dim)) ps
``````

This is the code:

``````let vector = List.map;;

let clist x =
let rec aux k = if k <= 0 then [] else x :: aux (k-1) in aux;;

with Invalid_argument _ ->
error_fmt "sum of two vectors of different size";;

with Invalid_argument _ ->
error_fmt "sum of two matrices of different size";;

(*vector zero *)
let vec_0 z dim = clist z dim;;

(* matrix zero *)
let mat_0 z dim = clist (vec_0 z dim) dim;;
let comp f g x = f (g x);;

(* matrix transpose *)
let transpose ci =
let rec aux = function
| [] | [] :: _ -> []
| cs -> List.map (comp ci List.hd) cs :: aux (List.map List.tl cs)
in aux;;

(* matrix *)
let matrix ci m =
try transpose ci m
with Failure _ -> error_fmt "ill-formed matrix";;

let mi_pol z add ci =
let rec aux const args = function
| [] -> { mi_const = const; mi_args = Array.to_list args }
| Polynomial_sum qs :: ps -> aux const args (qs @ ps)
| Polynomial_coefficient (Coefficient_matrix [v]) :: ps
| Polynomial_coefficient (Coefficient_vector v) :: ps ->
| Polynomial_product [p] :: ps -> aux const args (p :: ps)
| Polynomial_product [Polynomial_coefficient (Coefficient_matrix m);
Polynomial_variable i] :: ps ->
aux const args ps
| _ -> not_supported "todo"
in fun dim n -> function
| Polynomial_sum ps -> aux (vec_0 z dim) (Array.make n (mat_0 z dim)) ps
| _ -> not_supported
"todo";;
``````

Any help is very appreciate. If you can have a Coq code for `mi_pol` it will help me a lot.

-
This question is very badly ask. You admit to not even understanding the code, yet you want to formalize it? I think you got the cart before the horse. –  Andrej Bauer May 6 '13 at 5:50
Voted for close as "too localised" - unlikely to help any future visitors. –  Robin Green May 6 '13 at 14:49
It appears to take a polynomial on a vector space, and compute the sum of all the (transpose of) (matrix) coefficients attached to each variable. `args` is an array such that `args.(i)` is the sum of all coefficients on the `i`-th variable, and `const` the sum of constant scalars.