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(********************************************************************)
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(*                                                                  *)
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(*  The LustreC compiler toolset   /  The LustreC Development Team  *)
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(*  Copyright 2012 -    --   ONERA - CNRS - INPT                    *)
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(*                                                                  *)
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(*  LustreC is free software, distributed WITHOUT ANY WARRANTY      *)
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(*  under the terms of the GNU Lesser General Public License        *)
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(*  version 2.1.                                                    *)
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(*                                                                  *)
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(********************************************************************)
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open Lustre_types
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open Machine_code_types
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open Machine_code_common
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open Spec_types
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open Spec_common
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open Corelang
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open Clocks
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open Causality
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open Utils
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exception NormalizationError
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(* Questions:
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   - where are used the mconst. They contain initialization of constant in
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   nodes. But they do not seem to be used by c_backend *)
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(* translate_<foo> : vars -> context -> <foo> -> machine code/expression *)
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(* the context contains  m : state aka memory variables  *)
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(*                      si : initialization instructions *)
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(*                       j : node aka machine instances  *)
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(*                       d : local variables             *)
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(*                       s : step instructions           *)
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(* Machine processing requires knowledge about variables and local variables.
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   Local could be memories while other could not. *)
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type machine_env = { is_local : string -> bool; get_var : string -> var_decl }
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let build_env inputs locals outputs =
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  let all = List.sort_uniq VDeclModule.compare (locals @ inputs @ outputs) in
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  {
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    is_local = (fun id -> List.exists (fun v -> v.var_id = id) locals);
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    get_var =
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      (fun id ->
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        try List.find (fun v -> v.var_id = id) all
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        with Not_found ->
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          (* Format.eprintf "Impossible to find variable %s in set %a@.@?" * id
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             * VSet.pp all; *)
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          raise Not_found);
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  }
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(****************************************************************)
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(* Basic functions to translate to machine values, instructions *)
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(****************************************************************)
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let translate_ident env id =
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  (* Format.eprintf "trnaslating ident: %s@." id; *)
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  (* id is a var that shall be visible here , ie. in vars *)
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  try
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    let var_id = env.get_var id in
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    vdecl_to_val var_id
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  with Not_found -> (
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    (* id is a constant *)
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    try
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      let vdecl =
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        Corelang.var_decl_of_const
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          (const_of_top (Hashtbl.find Corelang.consts_table id))
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      in
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      vdecl_to_val vdecl
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    with Not_found -> (
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      (* id is a tag, getting its type in the list of declared enums *)
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      try id_to_tag id
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      with Not_found ->
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        Format.eprintf "internal error: Machine_code.translate_ident %s@.@?" id;
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        assert false))
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(* specialize predefined (polymorphic) operators wrt their instances, so that
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   the C semantics is preserved *)
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let specialize_to_c expr =
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  match expr.expr_desc with
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  | Expr_appl (id, e, r) ->
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    if
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      List.exists
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        (fun e -> Types.is_bool_type e.expr_type)
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        (expr_list_of_expr e)
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    then
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      let id = match id with "=" -> "equi" | "!=" -> "xor" | _ -> id in
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      { expr with expr_desc = Expr_appl (id, e, r) }
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    else expr
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  | _ ->
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    expr
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let specialize_op expr =
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  match !Options.output with "C" -> specialize_to_c expr | _ -> expr
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let rec translate_expr env expr =
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  let expr = specialize_op expr in
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  let translate_expr = translate_expr env in
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  let value_desc =
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    match expr.expr_desc with
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    | Expr_const v ->
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      Cst v
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    | Expr_ident x ->
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      (translate_ident env x).value_desc
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    | Expr_array el ->
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      Array (List.map translate_expr el)
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    | Expr_access (t, i) ->
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      Access (translate_expr t, translate_expr (expr_of_dimension i))
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    | Expr_power (e, n) ->
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      Power (translate_expr e, translate_expr (expr_of_dimension n))
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    | Expr_when (e1, _, _) ->
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      (translate_expr e1).value_desc
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    | Expr_appl (id, e, _) when Basic_library.is_expr_internal_fun expr ->
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      let nd = node_from_name id in
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      Fun (node_name nd, List.map translate_expr (expr_list_of_expr e))
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    | Expr_ite (g, t, e) when Backends.is_functional () ->
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      (* special treatment depending on the active backend. For functional ones,
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         like horn backend, ite are preserved in expression. While they are
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         removed for C or Java backends. *)
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      Fun ("ite", [ translate_expr g; translate_expr t; translate_expr e ])
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    | _ ->
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      Format.eprintf "Normalization error for backend %s: %a@." !Options.output
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        Printers.pp_expr expr;
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      raise NormalizationError
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  in
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  mk_val value_desc expr.expr_type
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let translate_guard env expr =
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  match expr.expr_desc with
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  | Expr_ident x ->
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    translate_ident env x
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  | _ ->
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    Format.eprintf "internal error: translate_guard %a@." Printers.pp_expr expr;
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    assert false
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let rec translate_act env (y, expr) =
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  let translate_act = translate_act env in
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  let translate_guard = translate_guard env in
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  (* let translate_ident = translate_ident env in *)
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  let translate_expr = translate_expr env in
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  let lustre_eq = Corelang.mkeq Location.dummy_loc ([ y.var_id ], expr) in
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  match expr.expr_desc with
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  | Expr_ite (c, t, e) ->
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    let c = translate_guard c in
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    let t, spec_t = translate_act (y, t) in
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    let e, spec_e = translate_act (y, e) in
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    mk_conditional ~lustre_eq c [ t ] [ e ], mk_conditional_tr c spec_t spec_e
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  | Expr_merge (x, hl) ->
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    let var_x = env.get_var x in
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    let hl, spec_hl =
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      List.(
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        split
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          (map
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             (fun (t, h) ->
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               let h, spec_h = translate_act (y, h) in
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               (t, [ h ]), (t, spec_h))
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             hl))
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    in
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    mk_branch' ~lustre_eq var_x hl, mk_branch_tr var_x spec_hl
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  | _ ->
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    let e = translate_expr expr in
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    mk_assign ~lustre_eq y e, mk_assign_tr y e
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let get_memory env mems eq =
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  match eq.eq_lhs, eq.eq_rhs.expr_desc with
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  | ([ x ], Expr_pre _ | [ x ], Expr_fby _) when env.is_local x ->
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    let var_x = env.get_var x in
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    VSet.add var_x mems
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  | _ ->
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    mems
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let get_memories env = List.fold_left (get_memory env) VSet.empty
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(* Datastructure updated while visiting equations *)
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type machine_ctx = {
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  (* memories *)
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  m : ISet.t;
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  (* Reset instructions *)
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  si : instr_t list;
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  (* Instances *)
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  j : (Lustre_types.top_decl * Dimension.dim_expr list) IMap.t;
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  (* Step instructions *)
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  s : instr_t list;
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  (* Memory pack spec *)
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  mp : mc_formula_t list;
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  (* Transition spec *)
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  t :
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    (var_decl list
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    (* inputs *)
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    * var_decl list
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    (* locals *)
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    * var_decl list
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    (* outputs *)
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    * ISet.t (* memory footprint *)
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    * mc_formula_t)
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    (* formula *)
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    list;
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}
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let ctx_init =
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  { m = ISet.empty; si = []; j = IMap.empty; s = []; mp = []; t = [] }
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(****************************************************************)
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(* Main function to translate equations into this machine context we are
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   building *)
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(****************************************************************)
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let mk_control v l inst = mkinstr (MBranch (vdecl_to_val v, [ l, [ inst ] ]))
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let control_on_clock env ck inst =
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  let rec aux ((fspec, inst) as acc) ck =
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    match (Clocks.repr ck).cdesc with
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    | Con (ck, cr, l) ->
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      let id = Clocks.const_of_carrier cr in
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      let v = env.get_var id in
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      aux
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        ( (fun spec -> Imply (Equal (Var v, Tag l), fspec spec)),
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          mk_control v l inst )
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        ck
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    | _ ->
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      acc
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  in
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  let fspec, inst = aux ((fun spec -> spec), inst) ck in
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  fspec, inst
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let reset_instance env i r c =
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  match r with
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  | Some r ->
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    let r = translate_guard env r in
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    let _, inst =
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      control_on_clock env c
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        (mk_conditional r [ mkinstr (MSetReset i) ] [ mkinstr (MNoReset i) ])
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    in
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    Some r, [ inst ]
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  | None ->
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    None, []
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let translate_eq env ctx id inputs locals outputs i eq =
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  let translate_expr = translate_expr env in
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  let translate_act = translate_act env in
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  let locals_pi = Lustre_live.inter_live_i_with id (i - 1) locals in
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  let outputs_pi = Lustre_live.inter_live_i_with id (i - 1) outputs in
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  let locals_i = Lustre_live.inter_live_i_with id i locals in
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  let outputs_i = Lustre_live.inter_live_i_with id i outputs in
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  let pred_mp ctx a = And [ mk_memory_pack ~i:(i - 1) id; a ] :: ctx.mp in
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  let pred_t ctx a =
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    ( inputs,
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      locals_i,
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      outputs_i,
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      ctx.m,
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      Exists
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        ( Lustre_live.existential_vars id i eq (locals @ outputs),
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          And
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            [
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              mk_transition ~i:(i - 1) id (vdecls_to_vals inputs)
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                (vdecls_to_vals locals_pi)
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                (vdecls_to_vals outputs_pi);
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              a;
260
            ] ) )
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    :: ctx.t
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  in
263
  let control_on_clock ck inst spec_mp spec_t ctx =
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    let fspec, inst = control_on_clock env ck inst in
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    {
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      ctx with
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      s =
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        {
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          inst with
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          instr_spec =
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            [
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              mk_memory_pack ~i id;
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              mk_transition ~i id (vdecls_to_vals inputs)
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                (vdecls_to_vals locals_i) (vdecls_to_vals outputs_i);
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            ];
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        }
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        :: ctx.s;
278
      mp = pred_mp ctx spec_mp;
279
      t = pred_t ctx (fspec spec_t);
280
    }
281
  in
282
  let reset_instance = reset_instance env in
283
  let mkinstr' = mkinstr ~lustre_eq:eq in
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  let ctl ?(ck = eq.eq_rhs.expr_clock) instr =
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    control_on_clock ck (mkinstr' instr)
286
  in
287

    
288
  (* Format.eprintf "translate_eq %a with clock %a@." Printers.pp_node_eq eq
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     Clocks.print_ck eq.eq_rhs.expr_clock; *)
290
  match eq.eq_lhs, eq.eq_rhs.expr_desc with
291
  | [ x ], Expr_arrow (e1, e2) ->
292
    let var_x = env.get_var x in
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    let td = Arrow.arrow_top_decl () in
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    let inst = new_instance td eq.eq_rhs.expr_tag in
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    let c1 = translate_expr e1 in
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    let c2 = translate_expr e2 in
297
    assert (c1.value_desc = Cst (Const_tag "true"));
298
    assert (c2.value_desc = Cst (Const_tag "false"));
299
    let ctx =
300
      ctl
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        (MStep ([ var_x ], inst, [ c1; c2 ]))
302
        (mk_memory_pack ~inst (node_name td))
303
        (mk_transition ~inst (node_name td) [] [] [ vdecl_to_val var_x ])
304
        ctx
305
    in
306
    {
307
      ctx with
308
      si = mkinstr (MSetReset inst) :: ctx.si;
309
      j = IMap.add inst (td, []) ctx.j;
310
    }
311
  | [ x ], Expr_pre e when env.is_local x ->
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    let var_x = env.get_var x in
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    let e = translate_expr e in
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    ctl
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      (MStateAssign (var_x, e))
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      (mk_state_variable_pack var_x)
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      (mk_state_assign_tr var_x e)
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      { ctx with m = ISet.add x ctx.m }
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  | [ x ], Expr_fby (e1, e2) when env.is_local x ->
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    let var_x = env.get_var x in
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    let e2 = translate_expr e2 in
322
    let ctx =
323
      ctl
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        (MStateAssign (var_x, e2))
325
        (mk_state_variable_pack var_x)
326
        (mk_state_assign_tr var_x e2)
327
        { ctx with m = ISet.add x ctx.m }
328
    in
329
    {
330
      ctx with
331
      si = mkinstr' (MStateAssign (var_x, translate_expr e1)) :: ctx.si;
332
    }
333
  | p, Expr_appl (f, arg, r)
334
    when not (Basic_library.is_expr_internal_fun eq.eq_rhs) ->
335
    let var_p = List.map (fun v -> env.get_var v) p in
336
    let el = expr_list_of_expr arg in
337
    let vl = List.map translate_expr el in
338
    let node_f = node_from_name f in
339
    let call_f = node_f, NodeDep.filter_static_inputs (node_inputs node_f) el in
340
    let inst = new_instance node_f eq.eq_rhs.expr_tag in
341
    let env_cks =
342
      List.fold_right
343
        (fun arg cks -> arg.expr_clock :: cks)
344
        el [ eq.eq_rhs.expr_clock ]
345
    in
346
    let call_ck =
347
      Clock_calculus.compute_root_clock (Clock_predef.ck_tuple env_cks)
348
    in
349
    let r, reset_inst = reset_instance inst r call_ck in
350
    let ctx =
351
      ctl ~ck:call_ck
352
        (MStep (var_p, inst, vl))
353
        (mk_memory_pack ~inst (node_name node_f))
354
        (mk_transition ?r ~inst (node_name node_f) vl [] (vdecls_to_vals var_p))
355
        ctx
356
    in
357
    (*Clocks.new_var true in Clock_calculus.unify_imported_clock (Some call_ck)
358
      eq.eq_rhs.expr_clock eq.eq_rhs.expr_loc; Format.eprintf "call %a: %a:
359
      %a@," Printers.pp_expr eq.eq_rhs Clocks.print_ck (Clock_predef.ck_tuple
360
      env_cks) Clocks.print_ck call_ck;*)
361
    {
362
      ctx with
363
      si =
364
        (if Stateless.check_node node_f then ctx.si
365
        else mkinstr (MSetReset inst) :: ctx.si);
366
      j = IMap.add inst call_f ctx.j;
367
      s = (if Stateless.check_node node_f then [] else reset_inst) @ ctx.s;
368
    }
369
  | [ x ], _ ->
370
    let var_x = env.get_var x in
371
    let instr, spec = translate_act (var_x, eq.eq_rhs) in
372
    control_on_clock eq.eq_rhs.expr_clock instr True spec ctx
373
  | _ ->
374
    Format.eprintf "internal error: Machine_code.translate_eq %a@?"
375
      Printers.pp_node_eq eq;
376
    assert false
377

    
378
let constant_equations locals =
379
  List.fold_left
380
    (fun eqs vdecl ->
381
      if vdecl.var_dec_const then
382
        {
383
          eq_lhs = [ vdecl.var_id ];
384
          eq_rhs = desome vdecl.var_dec_value;
385
          eq_loc = vdecl.var_loc;
386
        }
387
        :: eqs
388
      else eqs)
389
    [] locals
390

    
391
let translate_eqs env ctx id inputs locals outputs eqs =
392
  List.fold_left
393
    (fun (ctx, i) eq ->
394
      let ctx = translate_eq env ctx id inputs locals outputs i eq in
395
      ctx, i + 1)
396
    (ctx, 1) eqs
397
  |> fst
398

    
399
(****************************************************************)
400
(* Processing nodes *)
401
(****************************************************************)
402

    
403
let process_asserts nd =
404
  let exprl = List.map (fun assert_ -> assert_.assert_expr) nd.node_asserts in
405
  if Backends.is_functional () then [], [], exprl
406
  else
407
    (* Each assert(e) is associated to a fresh variable v and declared as v=e;
408
       assert (v); *)
409
    let _, vars, eql, assertl =
410
      List.fold_left
411
        (fun (i, vars, eqlist, assertlist) expr ->
412
          let loc = expr.expr_loc in
413
          let var_id = nd.node_id ^ "_assert_" ^ string_of_int i in
414
          let assert_var =
415
            mkvar_decl loc ~orig:false
416
              (* fresh var *)
417
              ( var_id,
418
                mktyp loc Tydec_bool,
419
                mkclock loc Ckdec_any,
420
                false,
421
                (* not a constant *)
422
                None,
423
                (* no default value *)
424
                Some nd.node_id )
425
          in
426
          assert_var.var_type <- Type_predef.type_bool
427
          (* Types.new_ty (Types.Tbool) *);
428
          let eq = mkeq loc ([ var_id ], expr) in
429
          ( i + 1,
430
            assert_var :: vars,
431
            eq :: eqlist,
432
            { expr with expr_desc = Expr_ident var_id } :: assertlist ))
433
        (1, [], [], []) exprl
434
    in
435
    vars, eql, assertl
436

    
437
let translate_core env nid sorted_eqs inputs locals outputs =
438
  let constant_eqs = constant_equations locals in
439

    
440
  (* Compute constants' instructions *)
441
  let ctx0 =
442
    translate_eqs env ctx_init nid inputs locals outputs constant_eqs
443
  in
444
  assert (ctx0.si = []);
445
  assert (IMap.is_empty ctx0.j);
446

    
447
  (* Compute ctx for all eqs *)
448
  let ctx = translate_eqs env ctx_init nid inputs locals outputs sorted_eqs in
449

    
450
  ctx, ctx0.s
451

    
452
let zero = mk_val (Cst (Const_int 0)) Type_predef.type_int
453

    
454
let memory_pack_0 nd =
455
  {
456
    mpname = nd;
457
    mpindex = Some 0;
458
    mpformula =
459
      And [ StateVarPack ResetFlag; Equal (Memory ResetFlag, Val zero) ];
460
  }
461

    
462
let memory_pack_toplevel nd i =
463
  {
464
    mpname = nd;
465
    mpindex = None;
466
    mpformula =
467
      Ternary
468
        (Memory ResetFlag, StateVarPack ResetFlag, mk_memory_pack ~i nd.node_id);
469
  }
470

    
471
let transition_0 nd =
472
  {
473
    tname = nd;
474
    tindex = Some 0;
475
    tinputs = nd.node_inputs;
476
    tlocals = [];
477
    toutputs = [];
478
    tformula = True;
479
    tfootprint = ISet.empty;
480
  }
481

    
482
let transition_toplevel nd i =
483
  {
484
    tname = nd;
485
    tindex = None;
486
    tinputs = nd.node_inputs;
487
    tlocals = [];
488
    toutputs = nd.node_outputs;
489
    tformula =
490
      ExistsMem
491
        ( nd.node_id,
492
          Predicate (ResetCleared nd.node_id),
493
          mk_transition nd.node_id ~i
494
            (vdecls_to_vals nd.node_inputs)
495
            []
496
            (vdecls_to_vals nd.node_outputs) );
497
    tfootprint = ISet.empty;
498
  }
499

    
500
let translate_decl nd sch =
501
  (* Format.eprintf "Translating node %s@." nd.node_id; *)
502
  (* Extracting eqs, variables ..  *)
503
  let eqs, auts = get_node_eqs nd in
504
  assert (auts = []);
505

    
506
  (* Automata should be expanded by now *)
507

    
508
  (* In case of non functional backend (eg. C), additional local variables have
509
     to be declared for each assert *)
510
  let new_locals, assert_instrs, nd_node_asserts = process_asserts nd in
511

    
512
  (* Build the env: variables visible in the current scope *)
513
  let locals = nd.node_locals @ new_locals in
514
  (* let locals = VSet.of_list locals_list in *)
515
  (* let inout_vars = nd.node_inputs @ nd.node_outputs in *)
516
  let env = build_env nd.node_inputs locals nd.node_outputs in
517

    
518
  (* Format.eprintf "Node content is %a@." Printers.pp_node nd; *)
519

    
520
  (* Computing main content *)
521
  (* Format.eprintf "ok1@.@?"; *)
522
  let schedule = sch.Scheduling_type.schedule in
523
  (* Format.eprintf "ok2@.@?"; *)
524
  let sorted_eqs, unused =
525
    Scheduling.sort_equations_from_schedule eqs schedule
526
  in
527

    
528
  (* Format.eprintf "ok3@.locals=%a@.inout:%a@?"
529
   *   VSet.pp locals
530
   *   VSet.pp inout_vars
531
   * ; *)
532
  let equations = assert_instrs @ sorted_eqs in
533
  let mems = get_memories env equations in
534
  (* Removing computed memories from locals. We also removed unused variables. *)
535
  let locals =
536
    List.filter
537
      (fun v -> (not (VSet.mem v mems)) && not (List.mem v.var_id unused))
538
      locals
539
  in
540
  (* Compute live sets for spec *)
541
  Lustre_live.set_live_of nd.node_id nd.node_outputs locals equations;
542

    
543
  (* Translate equations *)
544
  let ctx, ctx0_s =
545
    translate_core env nd.node_id equations nd.node_inputs locals
546
      nd.node_outputs
547
  in
548

    
549
  (* Format.eprintf "ok4@.@?"; *)
550

    
551
  (* Build the machine *)
552
  let mmap = IMap.bindings ctx.j in
553
  let mmemory_packs =
554
    memory_pack_0 nd
555
    ::
556
    List.mapi
557
      (fun i f -> { mpname = nd; mpindex = Some (i + 1); mpformula = red f })
558
      (List.rev ctx.mp)
559
    @ [ memory_pack_toplevel nd (List.length ctx.mp) ]
560
  in
561
  let mtransitions =
562
    transition_0 nd
563
    ::
564
    List.mapi
565
      (fun i (tinputs, tlocals, toutputs, tfootprint, f) ->
566
        {
567
          tname = nd;
568
          tindex = Some (i + 1);
569
          tinputs;
570
          tlocals;
571
          toutputs;
572
          tformula = red f;
573
          tfootprint;
574
        })
575
      (List.rev ctx.t)
576
    @ [ transition_toplevel nd (List.length ctx.t) ]
577
  in
578
  let clear_reset =
579
    mkinstr
580
      ~instr_spec:
581
        [
582
          mk_memory_pack ~i:0 nd.node_id;
583
          mk_transition ~i:0 nd.node_id (vdecls_to_vals nd.node_inputs) [] [];
584
        ]
585
      MClearReset
586
  in
587
  {
588
    mname = nd;
589
    mmemory = VSet.elements mems;
590
    mcalls = mmap;
591
    minstances =
592
      List.filter (fun (_, (n, _)) -> not (Stateless.check_node n)) mmap;
593
    minit = List.rev ctx.si;
594
    mconst = List.rev ctx0_s;
595
    mstatic = List.filter (fun v -> v.var_dec_const) nd.node_inputs;
596
    mstep =
597
      {
598
        step_inputs = nd.node_inputs;
599
        step_outputs = nd.node_outputs;
600
        step_locals = locals;
601
        step_checks =
602
          List.map
603
            (fun d ->
604
              d.Dimension.dim_loc, translate_expr env (expr_of_dimension d))
605
            nd.node_checks;
606
        step_instrs =
607
          clear_reset
608
          ::
609
          (* special treatment depending on the active backend. For horn
610
             backend, common branches are not merged while they are in C or Java
611
             backends. *)
612
          (if !Backends.join_guards then join_guards_list (List.rev ctx.s)
613
          else List.rev ctx.s);
614
        step_asserts = List.map (translate_expr env) nd_node_asserts;
615
      };
616
    (* Processing spec: there is no processing performed here. Contract have
617
       been processed already. Either one of the other machine is a cocospec
618
       node, or the current one is a cocospec node. Contract do not contain any
619
       statement or import. *)
620
    mspec = { mnode_spec = nd.node_spec; mtransitions; mmemory_packs };
621
    mannot = nd.node_annot;
622
    msch = Some sch;
623
  }
624

    
625
(** takes the global declarations and the scheduling associated to each node *)
626
let translate_prog decls node_schs =
627
  let nodes = get_nodes decls in
628
  let machines =
629
    List.map
630
      (fun decl ->
631
        let node = node_of_top decl in
632
        let sch = IMap.find node.node_id node_schs in
633
        translate_decl node sch)
634
      nodes
635
  in
636
  machines
637

    
638
(* Local Variables: *)
639
(* compile-command:"make -C .." *)
640
(* End: *)
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