Synchronous_reactive_systems/src/passes.ml

(** This file contains simplification passes for our Lustre-like AST *)

open Ast
open Passes_utils
open Utils

let pre2vars verbose debug main_fn =
  let rec all_pre expr =
    match expr with
    | EMonOp (ty, MOp_pre, expr) -> all_pre expr
    | EMonOp _ -> false
    | EVar _ -> true
    | _ -> false
  in
  let rec pre_push expr : t_expression =
    match expr with
    | EVar _ -> EMonOp (type_exp expr, MOp_pre, expr)
    | EConst _ -> expr (** pre(c) = c for any constant c *)
    | EMonOp (ty, mop, expr) ->
      begin
        match mop with
      | MOp_pre ->
        if all_pre expr
          then EMonOp (ty, mop, EMonOp (ty, mop, expr))
          else pre_push (pre_push expr)
      | _ -> EMonOp (ty, mop, pre_push expr)
    end
  | EBinOp (ty, bop, expr, expr') ->
      let expr = pre_push expr in let expr' = pre_push expr' in
      EBinOp (ty, bop, expr, expr')
  | ETriOp (ty, top, expr, expr', expr'') ->
      let expr = pre_push expr in let expr' = pre_push expr' in
      let expr'' = pre_push expr'' in
      ETriOp (ty, top, expr, expr', expr'')
  | EComp  (ty, cop, expr, expr') ->
      let expr = pre_push expr in let expr' = pre_push expr' in
      EComp (ty, cop, expr, expr')
  | EWhen  (ty, expr, expr') ->
      let expr = pre_push expr in let expr' = pre_push expr' in
      EWhen (ty, expr, expr')
  | EReset (ty, expr, expr') ->
      let expr = pre_push expr in let expr' = pre_push expr' in
      EReset (ty, expr, expr')
  | ETuple (ty, elist) ->
      let elist =
        List.fold_right (fun expr acc -> (pre_push expr) :: acc) elist [] in
      ETuple (ty, elist)
  | EApp   (ty, node, arg) ->
      let arg = pre_push arg in
      EApp (ty, node, arg)
in
let rec aux (expr: t_expression) =
  match expr with
  | EVar   _ -> expr
  | EMonOp (ty, mop, expr) ->
    begin
      match mop with
      | MOp_pre -> pre_push expr
      | _ -> let expr = aux expr in EMonOp (ty, mop, expr)
    end
  | EBinOp (ty, bop, expr, expr') ->
      let expr = aux expr in let expr' = aux expr' in
      EBinOp (ty, bop, expr, expr')
  | ETriOp (ty, top, expr, expr', expr'') ->
      let expr = aux expr in let expr' = aux expr' in
      let expr'' = aux expr'' in
      ETriOp (ty, top, expr, expr', expr'')
  | EComp  (ty, cop, expr, expr') ->
      let expr = aux expr in let expr' = aux expr' in
      EComp (ty, cop, expr, expr')
  | EWhen  (ty, expr, expr') ->
      let expr = aux expr in let expr' = aux expr' in
      EWhen (ty, expr, expr')
  | EReset (ty, expr, expr') ->
      let expr = aux expr in let expr' = aux expr' in
      EReset (ty, expr, expr')
  | EConst (ty, c) -> EConst (ty, c)
  | ETuple (ty, elist) ->
      let elist =
        List.fold_right (fun expr acc -> (aux expr) :: acc) elist [] in
      ETuple (ty, elist)
  | EApp   (ty, node, arg) ->
      let arg = aux arg in
      EApp (ty, node, arg)
in
expression_pass (somify aux)

let chkvar_init_unicity verbose debug main_fn : t_nodelist -> t_nodelist option =
let aux (node: t_node) : t_node option =
  let incr_aux h n =
    match Hashtbl.find_opt h n with
    | None -> failwith "todo, should not happened."
    | Some num -> Hashtbl.replace h n (num + 1)
    in
  let incr_eq h (((_, patt), _): t_equation) =
    List.iter (fun v -> incr_aux h (name_of_var v)) patt
    in
  let rec incr_eqlist h = function
    | [] -> ()
    | eq :: eqs -> (incr_eq h eq; incr_eqlist h eqs)
    in
  let incr_branch h (State (_, eqs, _, _): t_state) = incr_eqlist h eqs in
  let incr_automata h ((_, states): t_automaton) =
    let acc = Hashtbl.copy h in
      List.iter
        (fun st ->
          let h_st = Hashtbl.copy h in
          incr_branch h_st st;
          Hashtbl.iter
            (fun varname num' ->
              match Hashtbl.find_opt acc varname with
              | None -> failwith "no!"
              | Some num -> Hashtbl.replace acc varname (Int.max num num')
              ) h_st) states;
        Hashtbl.iter (fun v n -> Hashtbl.replace h v n) acc
      in
  let check_now h : bool=
    Hashtbl.fold
      (fun varname num old_res ->
        if num > 1
          then (verbose (Format.asprintf "%s initialized twice!" varname); false)
          else old_res) h true
    in
  (*let purge_initialized h =
    Hashtbl.iter
      (fun varname num ->
        if num > 0
          then (verbose (Format.asprintf "Purging %s" varname); Hashtbl.remove h varname)
          else ()) h
    in*)
  let h = Hashtbl.create Config.maxvar in
  let add_var n v =
    match v with
    | IVar s -> Hashtbl.add h s n
    | BVar s -> Hashtbl.add h s n
    | RVar s -> Hashtbl.add h s n
  in
  let add_var_in = add_var 1 in
  let add_var_loc = add_var 0 in
  List.iter add_var_in (snd node.n_inputs);
  List.iter add_var_loc (snd node.n_outputs);
  List.iter add_var_loc (snd node.n_local_vars);
  (** Usual Equations *)
  incr_eqlist h node.n_equations;
  if check_now h = false
    then None
    else
      begin
        List.iter (* 0. *) (incr_automata h) node.n_automata;
        if check_now h
          then Some node
          else None
      end
  (** never purge -> failwith never executed! purge_initialized h; *)
in
node_pass aux

let pass_linearization verbose debug main_fn =
let node_lin (node: t_node): t_node option =
  let rec tpl ((pat, exp): t_equation) =
    match exp with
    | ETuple (_, hexps :: texps) ->
        debug "An ETuple has been recognized, inlining...";
        let p1, p2 =
          list_select
            (List.length (type_exp hexps))
            (snd pat) in
        let t1 = List.flatten (List.map type_var p1) in
        let t2 = List.flatten (List.map type_var p2) in
        ((t1, p1), hexps)
          :: (tpl ((t2, p2),
              ETuple (List.flatten (List.map type_exp texps), texps)))
    | ETuple (_, []) -> []
    | _ -> [(pat, exp)]
  in
  let new_locvars = node.n_local_vars in
  let new_equations = List.flatten
    begin
    List.map
      tpl
      node.n_equations
    end in
  Some
    {
      n_name = node.n_name;
      n_inputs = node.n_inputs;
      n_outputs = node.n_outputs;
      n_local_vars = new_locvars;
      n_equations = new_equations;
      n_automata = node.n_automata;
    }
in
node_pass node_lin

let pass_eq_reordering verbose debug main_fn ast =
let rec pick_equations init_vars eqs remaining_equations =
  match remaining_equations with
  | [] -> Some eqs
  | _ ->
    begin
      match List.filter
              (fun (patt, expr) ->
                List.for_all
                  (fun v -> List.mem v init_vars)
                  (vars_of_expr expr))
              remaining_equations with
      | [] -> raise (PassExn "[equation ordering] The equations cannot be ordered.")
      | h :: t ->
          let init_vars =
            List.fold_left
              (fun acc vs ->
                acc @ (vars_of_patt (fst vs))) init_vars (h :: t) in
          pick_equations init_vars (eqs@(h :: t))
            (List.filter (fun eq -> List.for_all (fun e -> eq <> e) (h :: t)) remaining_equations)
    end
  in
let node_eq_reorganising  (node: t_node): t_node option =
  let init_vars = List.map name_of_var (snd node.n_inputs) in
  try
    begin
    match pick_equations init_vars [] node.n_equations with
    | None -> None
    | Some eqs -> Some { node with n_equations = eqs }
    end
  with PassExn err -> (verbose err; None)
in
node_pass node_eq_reorganising ast

let pass_typing verbose debug main_fn ast =
  let htbl = Hashtbl.create (List.length ast) in
  let () = debug "[typing verification]" in
  let () = List.iter
    (fun n -> Hashtbl.add htbl n.n_name (fst n.n_inputs, fst n.n_outputs))
    ast in
  let rec check_varlist vl =
    let t = fst vl in
    let l = snd vl in
    match t, l with
    | [], [] -> true
    | TInt  :: t, IVar _ :: l -> check_varlist (t, l)
    | TBool :: t, BVar _ :: l -> check_varlist (t, l)
    | TReal :: t, RVar _ :: l -> check_varlist (t, l)
    | _, _ -> false
    in
  let rec check_expr vl = function
    | EVar   (t, v) -> t = type_var v
    | EMonOp (t, _, e) -> check_expr vl e && type_exp e = t
    | EBinOp (t, _, e, e') -> check_expr vl e && check_expr vl e'
                              && t = type_exp e && t = type_exp e'
    | ETriOp (t, _, c, e, e') ->
        check_expr vl e && check_expr vl e' && check_expr vl c
        && type_exp c = [TBool] && type_exp e = t && type_exp e' = t
    | EComp  (t, _, e, e') ->
        check_expr vl e && check_expr vl e' && t = [TBool]
    | EWhen  (t, e, e') ->
        check_expr vl e && check_expr vl e'
        && t = type_exp e && [TBool] = type_exp e'
    | EReset (t, e, e') ->
        check_expr vl e && check_expr vl e' && t = type_exp e && type_exp e' = [TBool]
    | EConst (t, c) -> type_const c = t
    | ETuple (t, l) ->
        List.for_all (check_expr vl) l
        && t = List.flatten (List.map type_exp l)
    | EApp   (t, n, e) ->
        check_expr vl e && t = (fst n.n_outputs) && type_exp e = (fst n.n_inputs)
  in
  let check_equation vl ((peq, eeq): t_equation) =
    if check_varlist peq
      then
        if check_expr vl eeq
          then fst peq = type_exp eeq
          else false
      else false
  in
  let rec check_equations vl = function
    | [] -> true
    | eq :: eqs ->
        if check_equation vl eq
          then check_equations vl eqs
          else false
  in
  let check_one_node node =
    check_varlist (node.n_inputs)
    && check_varlist (node.n_outputs)
    && check_varlist (node.n_local_vars)
    && check_equations
        (varlist_concat node.n_inputs
          (varlist_concat node.n_outputs node.n_local_vars))
        node.n_equations
    in
  let rec aux = function
    | [] -> Some ast
    | n :: nodes ->
        if check_one_node n
          then aux nodes
          else None
  in aux ast