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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 Format
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open Lustre_types
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open Machine_code_types
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(*open Dimension*)
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exception Error of Location.t * Error.error_kind
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module VDeclModule =
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struct (* Node module *)
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  type t = var_decl
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  let compare v1 v2 = compare v1.var_id v2.var_id
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end
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module VMap = Map.Make(VDeclModule)
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module VSet : Set.S with type elt = var_decl = Set.Make(VDeclModule)
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let dummy_type_dec = {ty_dec_desc=Tydec_any; ty_dec_loc=Location.dummy_loc}
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let dummy_clock_dec = {ck_dec_desc=Ckdec_any; ck_dec_loc=Location.dummy_loc}
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(************************************************************)
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(* *)
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let mktyp loc d =
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  { ty_dec_desc = d; ty_dec_loc = loc }
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let mkclock loc d =
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  { ck_dec_desc = d; ck_dec_loc = loc }
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let mkvar_decl loc ?(orig=false) (id, ty_dec, ck_dec, is_const, value, parentid) =
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  assert (value = None || is_const);
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  { var_id = id;
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    var_orig = orig;
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    var_dec_type = ty_dec;
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    var_dec_clock = ck_dec;
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    var_dec_const = is_const;
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    var_dec_value = value;
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    var_parent_nodeid = parentid;
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    var_type = Types.new_var ();
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    var_clock = Clocks.new_var true;
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    var_loc = loc }
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let dummy_var_decl name typ =
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  {
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    var_id = name;
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    var_orig = false;
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    var_dec_type = dummy_type_dec;
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    var_dec_clock = dummy_clock_dec;
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    var_dec_const = false;
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    var_dec_value = None;
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    var_parent_nodeid = None;
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    var_type =  typ;
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    var_clock = Clocks.new_ck Clocks.Cvar true;
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    var_loc = Location.dummy_loc
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  }
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let mkexpr loc d =
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  { expr_tag = Utils.new_tag ();
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    expr_desc = d;
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    expr_type = Types.new_var ();
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    expr_clock = Clocks.new_var true;
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    expr_delay = Delay.new_var ();
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    expr_annot = None;
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    expr_loc = loc }
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let var_decl_of_const ?(parentid=None) c =
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  { var_id = c.const_id;
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    var_orig = true;
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    var_dec_type = { ty_dec_loc = c.const_loc; ty_dec_desc = Tydec_any };
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    var_dec_clock = { ck_dec_loc = c.const_loc; ck_dec_desc = Ckdec_any };
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    var_dec_const = true;
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    var_dec_value = None;
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    var_parent_nodeid = parentid;
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    var_type = c.const_type;
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    var_clock = Clocks.new_var false;
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    var_loc = c.const_loc }
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let mk_new_name used id =
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  let rec new_name name cpt =
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    if used name
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    then new_name (sprintf "_%s_%i" id cpt) (cpt+1)
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    else name
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  in new_name id 1
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let mkeq loc (lhs, rhs) =
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  { eq_lhs = lhs;
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    eq_rhs = rhs;
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    eq_loc = loc }
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let mkassert loc expr =
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  { assert_loc = loc;
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    assert_expr = expr
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  }
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let mktop_decl loc own itf d =
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  { top_decl_desc = d; top_decl_loc = loc; top_decl_owner = own; top_decl_itf = itf }
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let mkpredef_call loc funname args =
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  mkexpr loc (Expr_appl (funname, mkexpr loc (Expr_tuple args), None))
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let is_clock_dec_type cty =
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  match cty with
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  | Tydec_clock _ -> true
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  | _             -> false
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let const_of_top top_decl =
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  match top_decl.top_decl_desc with
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  | Const c -> c
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  | _ -> assert false
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let node_of_top top_decl =
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  match top_decl.top_decl_desc with
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  | Node nd -> nd
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  | _ -> raise Not_found
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let imported_node_of_top top_decl =
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  match top_decl.top_decl_desc with
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  | ImportedNode ind -> ind
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  | _ -> assert false
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let typedef_of_top top_decl =
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  match top_decl.top_decl_desc with
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  | TypeDef tdef -> tdef
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  | _ -> assert false
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let dependency_of_top top_decl =
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  match top_decl.top_decl_desc with
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  | Open (local, dep) -> (local, dep)
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  | _ -> assert false
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let consts_of_enum_type top_decl =
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  match top_decl.top_decl_desc with
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  | TypeDef tdef ->
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    (match tdef.tydef_desc with
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    | Tydec_enum tags ->
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       List.map
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	 (fun tag ->
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	   let cdecl = {
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	     const_id = tag;
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	     const_loc = top_decl.top_decl_loc;
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	     const_value = Const_tag tag;
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	     const_type = Type_predef.type_const tdef.tydef_id
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	   } in
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	   { top_decl with top_decl_desc = Const cdecl })
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	 tags
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     | _               -> [])
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  | _ -> assert false
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(************************************************************)
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(*   Eexpr functions *)
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(************************************************************)
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let merge_node_annot ann1 ann2 =
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  { requires = ann1.requires @ ann2.requires;
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    ensures = ann1.ensures @ ann2.ensures;
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    behaviors = ann1.behaviors @ ann2.behaviors;
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    spec_loc = ann1.spec_loc
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  }
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let mkeexpr loc expr =
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  { eexpr_tag = Utils.new_tag ();
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    eexpr_qfexpr = expr;
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    eexpr_quantifiers = [];
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    eexpr_type = Types.new_var ();
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    eexpr_clock = Clocks.new_var true;
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    eexpr_normalized = None;
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    eexpr_loc = loc }
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let extend_eexpr q e = { e with eexpr_quantifiers = q@e.eexpr_quantifiers }
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(*
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let mkepredef_call loc funname args =
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  mkeexpr loc (EExpr_appl (funname, mkeexpr loc (EExpr_tuple args), None))
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let mkepredef_unary_call loc funname arg =
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  mkeexpr loc (EExpr_appl (funname, arg, None))
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*)
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let merge_expr_annot ann1 ann2 =
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  match ann1, ann2 with
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    | None, None -> assert false
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    | Some _, None -> ann1
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    | None, Some _ -> ann2
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    | Some ann1, Some ann2 -> Some {
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      annots = ann1.annots @ ann2.annots;
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      annot_loc = ann1.annot_loc
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    }
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let update_expr_annot node_id e annot =
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  List.iter (fun (key, _) -> 
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    Annotations.add_expr_ann node_id e.expr_tag key
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  ) annot.annots;
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  e.expr_annot <- merge_expr_annot e.expr_annot (Some annot);
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  e
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let mkinstr ?lustre_expr ?lustre_eq i =
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  {
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    instr_desc = i;
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    (* lustre_expr = lustre_expr; *)
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    lustre_eq = lustre_eq;
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  }
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let get_instr_desc i = i.instr_desc
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let update_instr_desc i id = { i with instr_desc = id }
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(***********************************************************)
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(* Fast access to nodes, by name *)
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let (node_table : (ident, top_decl) Hashtbl.t) = Hashtbl.create 30
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let consts_table = Hashtbl.create 30
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let print_node_table fmt () =
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  begin
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    Format.fprintf fmt "{ /* node table */@.";
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    Hashtbl.iter (fun id nd ->
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      Format.fprintf fmt "%s |-> %a"
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	id
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	Printers.pp_short_decl nd
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    ) node_table;
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    Format.fprintf fmt "}@."
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  end
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let print_consts_table fmt () =
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  begin
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    Format.fprintf fmt "{ /* consts table */@.";
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    Hashtbl.iter (fun id const ->
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      Format.fprintf fmt "%s |-> %a"
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	id
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	Printers.pp_const_decl (const_of_top const)
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    ) consts_table;
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    Format.fprintf fmt "}@."
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  end
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let node_name td =
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    match td.top_decl_desc with 
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    | Node nd         -> nd.node_id
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    | ImportedNode nd -> nd.nodei_id
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    | _ -> assert false
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let is_generic_node td =
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  match td.top_decl_desc with 
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  | Node nd         -> List.exists (fun v -> v.var_dec_const) nd.node_inputs
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  | ImportedNode nd -> List.exists (fun v -> v.var_dec_const) nd.nodei_inputs
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  | _ -> assert false
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let node_inputs td =
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  match td.top_decl_desc with 
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  | Node nd         -> nd.node_inputs
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  | ImportedNode nd -> nd.nodei_inputs
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  | _ -> assert false
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let node_from_name id =
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  try
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    Hashtbl.find node_table id
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  with Not_found -> (Format.eprintf "Unable to find any node named %s@ @?" id;
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		     assert false)
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let is_imported_node td =
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  match td.top_decl_desc with 
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  | Node nd         -> false
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  | ImportedNode nd -> true
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  | _ -> assert false
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(* alias and type definition table *)
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let mktop = mktop_decl Location.dummy_loc !Options.dest_dir false
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let top_int_type = mktop (TypeDef {tydef_id = "int"; tydef_desc = Tydec_int})
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let top_bool_type = mktop (TypeDef {tydef_id = "bool"; tydef_desc = Tydec_bool})
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(* let top_float_type = mktop (TypeDef {tydef_id = "float"; tydef_desc = Tydec_float}) *)
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let top_real_type = mktop (TypeDef {tydef_id = "real"; tydef_desc = Tydec_real})
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let type_table =
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  Utils.create_hashtable 20 [
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    Tydec_int  , top_int_type;
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    Tydec_bool , top_bool_type;
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    (* Tydec_float, top_float_type; *)
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    Tydec_real , top_real_type
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  ]
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let print_type_table fmt () =
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  begin
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    Format.fprintf fmt "{ /* type table */@.";
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    Hashtbl.iter (fun tydec tdef ->
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      Format.fprintf fmt "%a |-> %a"
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	Printers.pp_var_type_dec_desc tydec
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	Printers.pp_typedef (typedef_of_top tdef)
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    ) type_table;
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    Format.fprintf fmt "}@."
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  end
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let rec is_user_type typ =
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  match typ with
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  | Tydec_int | Tydec_bool | Tydec_real 
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  (* | Tydec_float *) | Tydec_any | Tydec_const _ -> false
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  | Tydec_clock typ' -> is_user_type typ'
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  | _ -> true
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let get_repr_type typ =
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  let typ_def = (typedef_of_top (Hashtbl.find type_table typ)).tydef_desc in
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  if is_user_type typ_def then typ else typ_def
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let rec coretype_equal ty1 ty2 =
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  let res =
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  match ty1, ty2 with
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  | Tydec_any           , _
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  | _                   , Tydec_any             -> assert false
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  | Tydec_const _       , Tydec_const _         -> get_repr_type ty1 = get_repr_type ty2
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  | Tydec_const _       , _                     -> let ty1' = (typedef_of_top (Hashtbl.find type_table ty1)).tydef_desc
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	       					   in (not (is_user_type ty1')) && coretype_equal ty1' ty2
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  | _                   , Tydec_const _         -> coretype_equal ty2 ty1
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  | Tydec_int           , Tydec_int
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  | Tydec_real          , Tydec_real
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  (* | Tydec_float         , Tydec_float *)
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  | Tydec_bool          , Tydec_bool            -> true
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  | Tydec_clock ty1     , Tydec_clock ty2       -> coretype_equal ty1 ty2
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  | Tydec_array (d1,ty1), Tydec_array (d2, ty2) -> Dimension.is_eq_dimension d1 d2 && coretype_equal ty1 ty2
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  | Tydec_enum tl1      , Tydec_enum tl2        -> List.sort compare tl1 = List.sort compare tl2
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  | Tydec_struct fl1    , Tydec_struct fl2      ->
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       List.length fl1 = List.length fl2
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    && List.for_all2 (fun (f1, t1) (f2, t2) -> f1 = f2 && coretype_equal t1 t2)
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      (List.sort (fun (f1,_) (f2,_) -> compare f1 f2) fl1)
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      (List.sort (fun (f1,_) (f2,_) -> compare f1 f2) fl2)
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  | _                                  -> false
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  in ((*Format.eprintf "coretype_equal %a %a = %B@." Printers.pp_var_type_dec_desc ty1 Printers.pp_var_type_dec_desc ty2 res;*) res)
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let tag_true = "true"
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let tag_false = "false"
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let tag_default = "default"
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347
let const_is_bool c =
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 match c with
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 | Const_tag t -> t = tag_true || t = tag_false
350
 | _           -> false
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(* Computes the negation of a boolean constant *)
353
let const_negation c =
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  assert (const_is_bool c);
355
  match c with
356
  | Const_tag t when t = tag_true  -> Const_tag tag_false
357
  | _                              -> Const_tag tag_true
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359
let const_or c1 c2 =
360
  assert (const_is_bool c1 && const_is_bool c2);
361
  match c1, c2 with
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  | Const_tag t1, _            when t1 = tag_true -> c1
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  | _           , Const_tag t2 when t2 = tag_true -> c2
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  | _                                             -> Const_tag tag_false
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let const_and c1 c2 =
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  assert (const_is_bool c1 && const_is_bool c2);
368
  match c1, c2 with
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  | Const_tag t1, _            when t1 = tag_false -> c1
370
  | _           , Const_tag t2 when t2 = tag_false -> c2
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  | _                                              -> Const_tag tag_true
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let const_xor c1 c2 =
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  assert (const_is_bool c1 && const_is_bool c2);
375
   match c1, c2 with
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  | Const_tag t1, Const_tag t2 when t1 <> t2  -> Const_tag tag_true
377
  | _                                         -> Const_tag tag_false
378

    
379
let const_impl c1 c2 =
380
  assert (const_is_bool c1 && const_is_bool c2);
381
  match c1, c2 with
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  | Const_tag t1, _ when t1 = tag_false           -> Const_tag tag_true
383
  | _           , Const_tag t2 when t2 = tag_true -> Const_tag tag_true
384
  | _                                             -> Const_tag tag_false
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386
(* To guarantee uniqueness of tags in enum types *)
387
let tag_table =
388
  Utils.create_hashtable 20 [
389
   tag_true, top_bool_type;
390
   tag_false, top_bool_type
391
  ]
392

    
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(* To guarantee uniqueness of fields in struct types *)
394
let field_table =
395
  Utils.create_hashtable 20 [
396
  ]
397

    
398
let get_enum_type_tags cty =
399
(*Format.eprintf "get_enum_type_tags %a@." Printers.pp_var_type_dec_desc cty;*)
400
 match cty with
401
 | Tydec_bool    -> [tag_true; tag_false]
402
 | Tydec_const _ -> (match (typedef_of_top (Hashtbl.find type_table cty)).tydef_desc with
403
                     | Tydec_enum tl -> tl
404
                     | _             -> assert false)
405
 | _            -> assert false
406

    
407
let get_struct_type_fields cty =
408
 match cty with
409
 | Tydec_const _ -> (match (typedef_of_top (Hashtbl.find type_table cty)).tydef_desc with
410
                     | Tydec_struct fl -> fl
411
                     | _               -> assert false)
412
 | _            -> assert false
413

    
414
let const_of_bool b =
415
 Const_tag (if b then tag_true else tag_false)
416

    
417
(* let get_const c = snd (Hashtbl.find consts_table c) *)
418

    
419
let ident_of_expr expr =
420
 match expr.expr_desc with
421
 | Expr_ident id -> id
422
 | _             -> assert false
423

    
424
(* Generate a new ident expression from a declared variable *)
425
let expr_of_vdecl v =
426
  { expr_tag = Utils.new_tag ();
427
    expr_desc = Expr_ident v.var_id;
428
    expr_type = v.var_type;
429
    expr_clock = v.var_clock;
430
    expr_delay = Delay.new_var ();
431
    expr_annot = None;
432
    expr_loc = v.var_loc }
433

    
434
(* Caution, returns an untyped and unclocked expression *)
435
let expr_of_ident id loc =
436
  {expr_tag = Utils.new_tag ();
437
   expr_desc = Expr_ident id;
438
   expr_type = Types.new_var ();
439
   expr_clock = Clocks.new_var true;
440
   expr_delay = Delay.new_var ();
441
   expr_loc = loc;
442
   expr_annot = None}
443

    
444
let is_tuple_expr expr =
445
 match expr.expr_desc with
446
  | Expr_tuple _ -> true
447
  | _            -> false
448

    
449
let expr_list_of_expr expr =
450
  match expr.expr_desc with
451
  | Expr_tuple elist -> elist
452
  | _                -> [expr]
453

    
454
let expr_of_expr_list loc elist =
455
 match elist with
456
 | [t]  -> { t with expr_loc = loc }
457
 | t::_ ->
458
    let tlist = List.map (fun e -> e.expr_type) elist in
459
    let clist = List.map (fun e -> e.expr_clock) elist in
460
    { t with expr_desc = Expr_tuple elist;
461
	     expr_type = Type_predef.type_tuple tlist;
462
	     expr_clock = Clock_predef.ck_tuple clist;
463
	     expr_tag = Utils.new_tag ();
464
	     expr_loc = loc }
465
 | _    -> assert false
466

    
467
let call_of_expr expr =
468
 match expr.expr_desc with
469
 | Expr_appl (f, args, r) -> (f, expr_list_of_expr args, r)
470
 | _                      -> assert false
471

    
472
    
473
(* Conversion from dimension expr to standard expr, for the purpose of printing, typing, etc... *)
474
let rec expr_of_dimension dim =
475
  let open Dimension in
476
  match dim.dim_desc with
477
 | Dbool b        ->
478
     mkexpr dim.dim_loc (Expr_const (const_of_bool b))
479
 | Dint i         ->
480
     mkexpr dim.dim_loc (Expr_const (Const_int i))
481
 | Dident id      ->
482
     mkexpr dim.dim_loc (Expr_ident id)
483
 | Dite (c, t, e) ->
484
     mkexpr dim.dim_loc (Expr_ite (expr_of_dimension c, expr_of_dimension t, expr_of_dimension e))
485
 | Dappl (id, args) ->
486
     mkexpr dim.dim_loc (Expr_appl (id, expr_of_expr_list dim.dim_loc (List.map expr_of_dimension args), None))
487
 | Dlink dim'       -> expr_of_dimension dim'
488
 | Dvar
489
 | Dunivar          -> (Format.eprintf "internal error: Corelang.expr_of_dimension %a@." Dimension.pp_dimension dim;
490
			assert false)
491

    
492
let dimension_of_const loc const =
493
  let open Dimension in
494
 match const with
495
 | Const_int i                                    -> mkdim_int loc i
496
 | Const_tag t when t = tag_true || t = tag_false -> mkdim_bool loc (t = tag_true)
497
 | _                                              -> raise InvalidDimension
498

    
499
(* Conversion from standard expr to dimension expr, for the purpose of injecting static call arguments 
500
   into dimension expressions *)
501
let rec dimension_of_expr expr =
502
  let open Dimension in
503
  match expr.expr_desc with
504
  | Expr_const c  -> dimension_of_const expr.expr_loc c
505
  | Expr_ident id -> mkdim_ident expr.expr_loc id
506
  | Expr_appl (f, args, None) when Basic_library.is_expr_internal_fun expr ->
507
      let k = Types.get_static_value (Env.lookup_value Basic_library.type_env f) in
508
      if k = None then raise InvalidDimension;
509
      mkdim_appl expr.expr_loc f (List.map dimension_of_expr (expr_list_of_expr args))
510
  | Expr_ite (i, t, e)        ->
511
      mkdim_ite expr.expr_loc (dimension_of_expr i) (dimension_of_expr t) (dimension_of_expr e)
512
  | _ -> raise InvalidDimension (* not a simple dimension expression *)
513

    
514

    
515
let sort_handlers hl =
516
 List.sort (fun (t, _) (t', _) -> compare t t') hl
517

    
518
let num_10 = Num.num_of_int 10
519
  
520
let rec is_eq_const c1 c2 =
521
  match c1, c2 with
522
  | Const_real (n1, i1, _), Const_real (n2, i2, _)
523
    -> Num.(let n1 = n1 // (num_10 **/ (num_of_int i1)) in
524
	    let n2 = n2 // (num_10 **/ (num_of_int i2)) in
525
	    eq_num n1 n2)
526
  | Const_struct lcl1, Const_struct lcl2
527
    -> List.length lcl1 = List.length lcl2
528
    && List.for_all2 (fun (l1, c1) (l2, c2) -> l1 = l2 && is_eq_const c1 c2) lcl1 lcl2
529
  | _  -> c1 = c2
530

    
531
let rec is_eq_expr e1 e2 = match e1.expr_desc, e2.expr_desc with
532
  | Expr_const c1, Expr_const c2 -> is_eq_const c1 c2
533
  | Expr_ident i1, Expr_ident i2 -> i1 = i2
534
  | Expr_array el1, Expr_array el2 
535
  | Expr_tuple el1, Expr_tuple el2 -> 
536
    List.length el1 = List.length el2 && List.for_all2 is_eq_expr el1 el2 
537
  | Expr_arrow (e1, e2), Expr_arrow (e1', e2') -> is_eq_expr e1 e1' && is_eq_expr e2 e2'
538
  | Expr_fby (e1,e2), Expr_fby (e1',e2') -> is_eq_expr e1 e1' && is_eq_expr e2 e2'
539
  | Expr_ite (i1, t1, e1), Expr_ite (i2, t2, e2) -> is_eq_expr i1 i2 && is_eq_expr t1 t2 && is_eq_expr e1 e2
540
  (* | Expr_concat (e1,e2), Expr_concat (e1',e2') -> is_eq_expr e1 e1' && is_eq_expr e2 e2' *)
541
  (* | Expr_tail e, Expr_tail e' -> is_eq_expr e e' *)
542
  | Expr_pre e, Expr_pre e' -> is_eq_expr e e'
543
  | Expr_when (e, i, l), Expr_when (e', i', l') -> l=l' && i=i' && is_eq_expr e e'
544
  | Expr_merge(i, hl), Expr_merge(i', hl') -> i=i' && List.for_all2 (fun (t, h) (t', h') -> t=t' && is_eq_expr h h') (sort_handlers hl) (sort_handlers hl')
545
  | Expr_appl (i, e, r), Expr_appl (i', e', r') -> i=i' && r=r' && is_eq_expr e e'
546
  | Expr_power (e1, i1), Expr_power (e2, i2)
547
  | Expr_access (e1, i1), Expr_access (e2, i2) -> is_eq_expr e1 e2 && is_eq_expr (expr_of_dimension i1) (expr_of_dimension i2)
548
  | _ -> false
549

    
550
let get_node_vars nd =
551
  nd.node_inputs @ nd.node_locals @ nd.node_outputs
552

    
553
let mk_new_node_name nd id =
554
  let used_vars = get_node_vars nd in
555
  let used v = List.exists (fun vdecl -> vdecl.var_id = v) used_vars in
556
  mk_new_name used id
557

    
558
let get_var id var_list =
559
  List.find (fun v -> v.var_id = id) var_list
560

    
561
let get_node_var id node =
562
  try
563
    get_var id (get_node_vars node)
564
  with Not_found -> begin
565
    (* Format.eprintf "Unable to find variable %s in node %s@.@?" id node.node_id; *)
566
    raise Not_found
567
  end
568

    
569

    
570
let get_node_eqs =
571
  let get_eqs stmts =
572
    List.fold_right
573
      (fun stmt (res_eq, res_aut) ->
574
	match stmt with
575
	| Eq eq -> eq :: res_eq, res_aut
576
	| Aut aut -> res_eq, aut::res_aut)
577
      stmts
578
      ([], []) in
579
  let table_eqs = Hashtbl.create 23 in
580
  (fun nd ->
581
    try
582
      let (old, res) = Hashtbl.find table_eqs nd.node_id
583
      in if old == nd.node_stmts then res else raise Not_found
584
    with Not_found -> 
585
      let res = get_eqs nd.node_stmts in
586
      begin
587
	Hashtbl.replace table_eqs nd.node_id (nd.node_stmts, res);
588
	res
589
      end)
590

    
591
let get_node_eq id node =
592
  let eqs, auts = get_node_eqs node in
593
  try
594
    List.find (fun eq -> List.mem id eq.eq_lhs) eqs
595
  with
596
    Not_found -> (* Shall be defined in automata auts *) raise Not_found
597
      
598
let get_nodes prog = 
599
  List.fold_left (
600
    fun nodes decl ->
601
      match decl.top_decl_desc with
602
	| Node _ -> decl::nodes
603
	| Const _ | ImportedNode _ | Open _ | TypeDef _ -> nodes  
604
  ) [] prog
605

    
606
let get_imported_nodes prog = 
607
  List.fold_left (
608
    fun nodes decl ->
609
      match decl.top_decl_desc with
610
	| ImportedNode _ -> decl::nodes
611
	| Const _ | Node _ | Open _ | TypeDef _-> nodes  
612
  ) [] prog
613

    
614
let get_consts prog = 
615
  List.fold_right (
616
    fun decl consts ->
617
      match decl.top_decl_desc with
618
	| Const _ -> decl::consts
619
	| Node _ | ImportedNode _ | Open _ | TypeDef _ -> consts  
620
  ) prog []
621

    
622
let get_typedefs prog = 
623
  List.fold_right (
624
    fun decl types ->
625
      match decl.top_decl_desc with
626
	| TypeDef _ -> decl::types
627
	| Node _ | ImportedNode _ | Open _ | Const _ -> types  
628
  ) prog []
629

    
630
let get_dependencies prog =
631
  List.fold_right (
632
    fun decl deps ->
633
      match decl.top_decl_desc with
634
	| Open _ -> decl::deps
635
	| Node _ | ImportedNode _ | TypeDef _ | Const _ -> deps  
636
  ) prog []
637

    
638
let get_node_interface nd =
639
 {nodei_id = nd.node_id;
640
  nodei_type = nd.node_type;
641
  nodei_clock = nd.node_clock;
642
  nodei_inputs = nd.node_inputs;
643
  nodei_outputs = nd.node_outputs;
644
  nodei_stateless = nd.node_dec_stateless;
645
  nodei_spec = nd.node_spec;
646
  (* nodei_annot = nd.node_annot; *)
647
  nodei_prototype = None;
648
  nodei_in_lib = [];
649
 }
650

    
651
(************************************************************************)
652
(*        Renaming                                                      *)
653

    
654
let rec rename_static rename cty =
655
 match cty with
656
 | Tydec_array (d, cty') -> Tydec_array (Dimension.expr_replace_expr rename d, rename_static rename cty')
657
 | Tydec_clock cty       -> Tydec_clock (rename_static rename cty)
658
 | Tydec_struct fl       -> Tydec_struct (List.map (fun (f, cty) -> f, rename_static rename cty) fl)
659
 | _                      -> cty
660

    
661
let rec rename_carrier rename cck =
662
 match cck with
663
 | Ckdec_bool cl -> Ckdec_bool (List.map (fun (c, l) -> rename c, l) cl)
664
 | _             -> cck
665

    
666
 (*Format.eprintf "Types.rename_static %a = %a@." print_ty ty print_ty res; res*)
667

    
668
(* applies the renaming function [fvar] to all variables of expression [expr] *)
669
 (* let rec expr_replace_var fvar expr = *)
670
 (*  { expr with expr_desc = expr_desc_replace_var fvar expr.expr_desc } *)
671

    
672
 (* and expr_desc_replace_var fvar expr_desc = *)
673
 (*   match expr_desc with *)
674
 (*   | Expr_const _ -> expr_desc *)
675
 (*   | Expr_ident i -> Expr_ident (fvar i) *)
676
 (*   | Expr_array el -> Expr_array (List.map (expr_replace_var fvar) el) *)
677
 (*   | Expr_access (e1, d) -> Expr_access (expr_replace_var fvar e1, d) *)
678
 (*   | Expr_power (e1, d) -> Expr_power (expr_replace_var fvar e1, d) *)
679
 (*   | Expr_tuple el -> Expr_tuple (List.map (expr_replace_var fvar) el) *)
680
 (*   | Expr_ite (c, t, e) -> Expr_ite (expr_replace_var fvar c, expr_replace_var fvar t, expr_replace_var fvar e) *)
681
 (*   | Expr_arrow (e1, e2)-> Expr_arrow (expr_replace_var fvar e1, expr_replace_var fvar e2)  *)
682
 (*   | Expr_fby (e1, e2) -> Expr_fby (expr_replace_var fvar e1, expr_replace_var fvar e2) *)
683
 (*   | Expr_pre e' -> Expr_pre (expr_replace_var fvar e') *)
684
 (*   | Expr_when (e', i, l)-> Expr_when (expr_replace_var fvar e', fvar i, l) *)
685
 (*   | Expr_merge (i, hl) -> Expr_merge (fvar i, List.map (fun (t, h) -> (t, expr_replace_var fvar h)) hl) *)
686
 (*   | Expr_appl (i, e', i') -> Expr_appl (i, expr_replace_var fvar e', Utils.option_map (expr_replace_var fvar) i') *)
687

    
688

    
689

    
690
 let rec rename_expr  f_node f_var expr =
691
   { expr with expr_desc = rename_expr_desc f_node f_var expr.expr_desc }
692
 and rename_expr_desc f_node f_var expr_desc =
693
   let re = rename_expr  f_node f_var in
694
   match expr_desc with
695
   | Expr_const _ -> expr_desc
696
   | Expr_ident i -> Expr_ident (f_var i)
697
   | Expr_array el -> Expr_array (List.map re el)
698
   | Expr_access (e1, d) -> Expr_access (re e1, d)
699
   | Expr_power (e1, d) -> Expr_power (re e1, d)
700
   | Expr_tuple el -> Expr_tuple (List.map re el)
701
   | Expr_ite (c, t, e) -> Expr_ite (re c, re t, re e)
702
   | Expr_arrow (e1, e2)-> Expr_arrow (re e1, re e2) 
703
   | Expr_fby (e1, e2) -> Expr_fby (re e1, re e2)
704
   | Expr_pre e' -> Expr_pre (re e')
705
   | Expr_when (e', i, l)-> Expr_when (re e', f_var i, l)
706
   | Expr_merge (i, hl) -> 
707
     Expr_merge (f_var i, List.map (fun (t, h) -> (t, re h)) hl)
708
   | Expr_appl (i, e', i') -> 
709
     Expr_appl (f_node i, re e', Utils.option_map re i')
710

    
711
 let rename_dec_type f_node f_var t = assert false (*
712
						     Types.rename_dim_type (Dimension.rename f_node f_var) t*)
713

    
714
 let rename_dec_clock f_node f_var c = assert false (* 
715
					  Clocks.rename_clock_expr f_var c*)
716
   
717
 let rename_var f_node f_var v = {
718
   v with
719
     var_id = f_var v.var_id;
720
     var_dec_type = rename_dec_type f_node f_var v.var_type;
721
     var_dec_clock = rename_dec_clock f_node f_var v.var_clock
722
 } 
723

    
724
 let rename_vars f_node f_var = List.map (rename_var f_node f_var) 
725

    
726
 let rec rename_eq f_node f_var eq = { eq with
727
   eq_lhs = List.map f_var eq.eq_lhs; 
728
   eq_rhs = rename_expr f_node f_var eq.eq_rhs
729
 } 
730
 and rename_handler f_node f_var  h = {h with
731
   hand_state = f_var h.hand_state;
732
   hand_unless = List.map (
733
     fun (l,e,b,id) -> l, rename_expr f_node f_var e, b, f_var id
734
   ) h.hand_unless;
735
   hand_until = List.map (
736
     fun (l,e,b,id) -> l, rename_expr f_node f_var e, b, f_var id
737
   ) h.hand_until;
738
   hand_locals = rename_vars f_node f_var h.hand_locals;
739
   hand_stmts = rename_stmts f_node f_var h.hand_stmts;
740
   hand_annots = rename_annots f_node f_var h.hand_annots;
741
   
742
 } 
743
 and rename_aut f_node f_var  aut = { aut with
744
   aut_id = f_var aut.aut_id;
745
   aut_handlers = List.map (rename_handler f_node f_var) aut.aut_handlers;
746
 }
747
 and rename_stmts f_node f_var stmts = List.map (fun stmt -> match stmt with
748
   | Eq eq -> Eq (rename_eq f_node f_var eq)
749
   | Aut at -> Aut (rename_aut f_node f_var at))
750
   stmts
751
 and rename_annotl f_node f_var  annots = 
752
   List.map 
753
     (fun (key, value) -> key, rename_eexpr f_node f_var value) 
754
     annots
755
 and rename_annot f_node f_var annot =
756
   { annot with annots = rename_annotl f_node f_var annot.annots }
757
 and rename_annots f_node f_var annots =
758
   List.map (rename_annot f_node f_var) annots
759
and rename_eexpr f_node f_var ee =
760
   { ee with
761
     eexpr_tag = Utils.new_tag ();
762
     eexpr_qfexpr = rename_expr f_node f_var ee.eexpr_qfexpr;
763
     eexpr_quantifiers = List.map (fun (typ,vdecls) -> typ, rename_vars f_node f_var vdecls) ee.eexpr_quantifiers;
764
     eexpr_normalized = Utils.option_map 
765
       (fun (vdecl, eqs, vdecls) ->
766
	 rename_var f_node f_var vdecl,
767
	 List.map (rename_eq f_node f_var) eqs,
768
	 rename_vars f_node f_var vdecls
769
       ) ee.eexpr_normalized;
770
     
771
   }
772
 
773
     
774
     
775
   
776
 let rename_node f_node f_var nd =
777
   let rename_var = rename_var f_node f_var in
778
   let rename_expr = rename_expr f_node f_var in
779
   let rename_stmts = rename_stmts f_node f_var in
780
   let inputs = List.map rename_var nd.node_inputs in
781
   let outputs = List.map rename_var nd.node_outputs in
782
   let locals = List.map rename_var nd.node_locals in
783
   let gen_calls = List.map rename_expr nd.node_gencalls in
784
   let node_checks = List.map (Dimension.rename f_node f_var)  nd.node_checks in
785
   let node_asserts = List.map 
786
     (fun a -> 
787
       {a with assert_expr = 
788
	   let expr = a.assert_expr in
789
	   rename_expr expr})
790
     nd.node_asserts
791
   in
792
   let node_stmts = rename_stmts nd.node_stmts
793

    
794
     
795
   in
796
   let spec = 
797
     Utils.option_map 
798
       (fun s -> assert false; (*rename_node_annot f_node f_var s*) ) (* TODO: implement! *) 
799
       nd.node_spec 
800
   in
801
   let annot = rename_annots f_node f_var nd.node_annot in
802
   {
803
     node_id = f_node nd.node_id;
804
     node_type = nd.node_type;
805
     node_clock = nd.node_clock;
806
     node_inputs = inputs;
807
     node_outputs = outputs;
808
     node_locals = locals;
809
     node_gencalls = gen_calls;
810
     node_checks = node_checks;
811
     node_asserts = node_asserts;
812
     node_stmts = node_stmts;
813
     node_dec_stateless = nd.node_dec_stateless;
814
     node_stateless = nd.node_stateless;
815
     node_spec = spec;
816
     node_annot = annot;
817
   }
818

    
819

    
820
let rename_const f_const c =
821
  { c with const_id = f_const c.const_id }
822

    
823
let rename_typedef f_var t =
824
  match t.tydef_desc with
825
  | Tydec_enum tags -> { t with tydef_desc = Tydec_enum (List.map f_var tags) }
826
  | _               -> t
827

    
828
let rename_prog f_node f_var f_const prog =
829
  List.rev (
830
    List.fold_left (fun accu top ->
831
      (match top.top_decl_desc with
832
      | Node nd -> 
833
	 { top with top_decl_desc = Node (rename_node f_node f_var nd) }
834
      | Const c -> 
835
	 { top with top_decl_desc = Const (rename_const f_const c) }
836
      | TypeDef tdef ->
837
	 { top with top_decl_desc = TypeDef (rename_typedef f_var tdef) }
838
      | ImportedNode _
839
      | Open _       -> top)
840
      ::accu
841
) [] prog
842
		   )
843

    
844
(* Applies the renaming function [fvar] to every rhs
845
   only when the corresponding lhs satisfies predicate [pvar] *)
846
 let eq_replace_rhs_var pvar fvar eq =
847
   let pvar l = List.exists pvar l in
848
   let rec replace lhs rhs =
849
     { rhs with expr_desc =
850
     match lhs with
851
     | []  -> assert false
852
     | [_] -> if pvar lhs then rename_expr_desc (fun x -> x) fvar rhs.expr_desc else rhs.expr_desc
853
     | _   ->
854
       (match rhs.expr_desc with
855
       | Expr_tuple tl ->
856
	 Expr_tuple (List.map2 (fun v e -> replace [v] e) lhs tl)
857
       | Expr_appl (f, arg, None) when Basic_library.is_expr_internal_fun rhs ->
858
	 let args = expr_list_of_expr arg in
859
	 Expr_appl (f, expr_of_expr_list arg.expr_loc (List.map (replace lhs) args), None)
860
       | Expr_array _
861
       | Expr_access _
862
       | Expr_power _
863
       | Expr_const _
864
       | Expr_ident _
865
       | Expr_appl _   ->
866
	 if pvar lhs
867
	 then rename_expr_desc (fun x -> x) fvar rhs.expr_desc
868
	 else rhs.expr_desc
869
       | Expr_ite (c, t, e)   -> Expr_ite (replace lhs c, replace lhs t, replace lhs e)
870
       | Expr_arrow (e1, e2)  -> Expr_arrow (replace lhs e1, replace lhs e2) 
871
       | Expr_fby (e1, e2)    -> Expr_fby (replace lhs e1, replace lhs e2)
872
       | Expr_pre e'          -> Expr_pre (replace lhs e')
873
       | Expr_when (e', i, l) -> let i' = if pvar lhs then fvar i else i
874
				 in Expr_when (replace lhs e', i', l)
875
       | Expr_merge (i, hl)   -> let i' = if pvar lhs then fvar i else i
876
				 in Expr_merge (i', List.map (fun (t, h) -> (t, replace lhs h)) hl)
877
       )
878
     }
879
   in { eq with eq_rhs = replace eq.eq_lhs eq.eq_rhs }
880

    
881
    
882
(**********************************************************************)
883
(* Pretty printers *)
884

    
885
let pp_decl_type fmt tdecl =
886
  match tdecl.top_decl_desc with
887
  | Node nd ->
888
    fprintf fmt "%s: " nd.node_id;
889
    Utils.reset_names ();
890
    fprintf fmt "%a@ " Types.print_ty nd.node_type
891
  | ImportedNode ind ->
892
    fprintf fmt "%s: " ind.nodei_id;
893
    Utils.reset_names ();
894
    fprintf fmt "%a@ " Types.print_ty ind.nodei_type
895
  | Const _ | Open _ | TypeDef _ -> ()
896

    
897
let pp_prog_type fmt tdecl_list =
898
  Utils.fprintf_list ~sep:"" pp_decl_type fmt tdecl_list
899

    
900
let pp_decl_clock fmt cdecl =
901
  match cdecl.top_decl_desc with
902
  | Node nd ->
903
    fprintf fmt "%s: " nd.node_id;
904
    Utils.reset_names ();
905
    fprintf fmt "%a@ " Clocks.print_ck nd.node_clock
906
  | ImportedNode ind ->
907
    fprintf fmt "%s: " ind.nodei_id;
908
    Utils.reset_names ();
909
    fprintf fmt "%a@ " Clocks.print_ck ind.nodei_clock
910
  | Const _ | Open _ | TypeDef _ -> ()
911

    
912
let pp_prog_clock fmt prog =
913
  Utils.fprintf_list ~sep:"" pp_decl_clock fmt prog
914

    
915

    
916
(* filling node table with internal functions *)
917
let vdecls_of_typ_ck cpt ty =
918
  let loc = Location.dummy_loc in
919
  List.map
920
    (fun _ -> incr cpt;
921
              let name = sprintf "_var_%d" !cpt in
922
              mkvar_decl loc (name, mktyp loc Tydec_any, mkclock loc Ckdec_any, false, None, None))
923
    (Types.type_list_of_type ty)
924

    
925
let mk_internal_node id =
926
  let spec = None in
927
  let ty = Env.lookup_value Basic_library.type_env id in
928
  let ck = Env.lookup_value Basic_library.clock_env id in
929
  let (tin, tout) = Types.split_arrow ty in
930
  (*eprintf "internal fun %s: %d -> %d@." id (List.length (Types.type_list_of_type tin)) (List.length (Types.type_list_of_type tout));*)
931
  let cpt = ref (-1) in
932
  mktop
933
    (ImportedNode
934
       {nodei_id = id;
935
	nodei_type = ty;
936
	nodei_clock = ck;
937
	nodei_inputs = vdecls_of_typ_ck cpt tin;
938
	nodei_outputs = vdecls_of_typ_ck cpt tout;
939
	nodei_stateless = Types.get_static_value ty <> None;
940
	nodei_spec = spec;
941
	(* nodei_annot = []; *)
942
	nodei_prototype = None;
943
       	nodei_in_lib = [];
944
       })
945

    
946
let add_internal_funs () =
947
  List.iter
948
    (fun id -> let nd = mk_internal_node id in Hashtbl.add node_table id nd)
949
    Basic_library.internal_funs
950

    
951

    
952

    
953
(* Replace any occurence of a var in vars_to_replace by its associated
954
   expression in defs until e does not contain any such variables *)
955
let rec substitute_expr vars_to_replace defs e =
956
  let se = substitute_expr vars_to_replace defs in
957
  { e with expr_desc = 
958
      let ed = e.expr_desc in
959
      match ed with
960
      | Expr_const _ -> ed
961
      | Expr_array el -> Expr_array (List.map se el)
962
      | Expr_access (e1, d) -> Expr_access (se e1, d)
963
      | Expr_power (e1, d) -> Expr_power (se e1, d)
964
      | Expr_tuple el -> Expr_tuple (List.map se el)
965
      | Expr_ite (c, t, e) -> Expr_ite (se c, se t, se e)
966
      | Expr_arrow (e1, e2)-> Expr_arrow (se e1, se e2) 
967
      | Expr_fby (e1, e2) -> Expr_fby (se e1, se e2)
968
      | Expr_pre e' -> Expr_pre (se e')
969
      | Expr_when (e', i, l)-> Expr_when (se e', i, l)
970
      | Expr_merge (i, hl) -> Expr_merge (i, List.map (fun (t, h) -> (t, se h)) hl)
971
      | Expr_appl (i, e', i') -> Expr_appl (i, se e', i')
972
      | Expr_ident i -> 
973
	if List.exists (fun v -> v.var_id = i) vars_to_replace then (
974
	  let eq_i eq = eq.eq_lhs = [i] in
975
	  if List.exists eq_i defs then
976
	    let sub = List.find eq_i defs in
977
	    let sub' = se sub.eq_rhs in
978
	    sub'.expr_desc
979
	  else 
980
	    assert false
981
	)
982
	else
983
	  ed
984

    
985
  }
986
  
987
 let rec expr_to_eexpr  expr =
988
   { eexpr_tag = expr.expr_tag;
989
     eexpr_qfexpr = expr;
990
     eexpr_quantifiers = [];
991
     eexpr_type = expr.expr_type;
992
     eexpr_clock = expr.expr_clock;
993
     eexpr_loc = expr.expr_loc;
994
     eexpr_normalized = None
995
   }
996
 (* and expr_desc_to_eexpr_desc expr_desc = *)
997
 (*   let conv = expr_to_eexpr in *)
998
 (*   match expr_desc with *)
999
 (*   | Expr_const c -> EExpr_const (match c with *)
1000
 (*     | Const_int x -> EConst_int x  *)
1001
 (*     | Const_real x -> EConst_real x  *)
1002
 (*     | Const_float x -> EConst_float x  *)
1003
 (*     | Const_tag x -> EConst_tag x  *)
1004
 (*     | _ -> assert false *)
1005

    
1006
 (*   ) *)
1007
 (*   | Expr_ident i -> EExpr_ident i *)
1008
 (*   | Expr_tuple el -> EExpr_tuple (List.map conv el) *)
1009

    
1010
 (*   | Expr_arrow (e1, e2)-> EExpr_arrow (conv e1, conv e2)  *)
1011
 (*   | Expr_fby (e1, e2) -> EExpr_fby (conv e1, conv e2) *)
1012
 (*   | Expr_pre e' -> EExpr_pre (conv e') *)
1013
 (*   | Expr_appl (i, e', i') ->  *)
1014
 (*     EExpr_appl  *)
1015
 (*       (i, conv e', match i' with None -> None | Some(id, _) -> Some id) *)
1016

    
1017
 (*   | Expr_when _ *)
1018
 (*   | Expr_merge _ -> assert false *)
1019
 (*   | Expr_array _  *)
1020
 (*   | Expr_access _  *)
1021
 (*   | Expr_power _  -> assert false *)
1022
 (*   | Expr_ite (c, t, e) -> assert false  *)
1023
 (*   | _ -> assert false *)
1024
      
1025
     
1026
let rec get_expr_calls nodes e =
1027
  let get_calls = get_expr_calls nodes in
1028
  match e.expr_desc with
1029
  | Expr_const _ 
1030
   | Expr_ident _ -> Utils.ISet.empty
1031
   | Expr_tuple el
1032
   | Expr_array el -> List.fold_left (fun accu e -> Utils.ISet.union accu (get_calls e)) Utils.ISet.empty el
1033
   | Expr_pre e1 
1034
   | Expr_when (e1, _, _) 
1035
   | Expr_access (e1, _) 
1036
   | Expr_power (e1, _) -> get_calls e1
1037
   | Expr_ite (c, t, e) -> Utils.ISet.union (Utils.ISet.union (get_calls c) (get_calls t)) (get_calls e) 
1038
   | Expr_arrow (e1, e2) 
1039
   | Expr_fby (e1, e2) -> Utils.ISet.union (get_calls e1) (get_calls e2)
1040
   | Expr_merge (_, hl) -> List.fold_left (fun accu (_, h) -> Utils.ISet.union accu (get_calls h)) Utils.ISet.empty  hl
1041
   | Expr_appl (i, e', i') -> 
1042
     if Basic_library.is_expr_internal_fun e then 
1043
       (get_calls e') 
1044
     else
1045
       let calls =  Utils.ISet.add i (get_calls e') in
1046
       let test = (fun n -> match n.top_decl_desc with Node nd -> nd.node_id = i | _ -> false) in
1047
       if List.exists test nodes then
1048
	 match (List.find test nodes).top_decl_desc with
1049
	 | Node nd -> Utils.ISet.union (get_node_calls nodes nd) calls
1050
	 | _ -> assert false
1051
       else 
1052
	 calls
1053

    
1054
and get_eq_calls nodes eq =
1055
  get_expr_calls nodes eq.eq_rhs
1056
and get_aut_handler_calls nodes h =
1057
  List.fold_left (fun accu stmt -> match stmt with
1058
  | Eq eq -> Utils.ISet.union (get_eq_calls nodes eq) accu
1059
  | Aut aut' ->  Utils.ISet.union (get_aut_calls nodes aut') accu
1060
  ) Utils.ISet.empty h.hand_stmts 
1061
and get_aut_calls nodes aut =
1062
  List.fold_left (fun accu h -> Utils.ISet.union (get_aut_handler_calls nodes h) accu)
1063
    Utils.ISet.empty aut.aut_handlers
1064
and get_node_calls nodes node =
1065
  let eqs, auts = get_node_eqs node in
1066
  let aut_calls =
1067
    List.fold_left
1068
      (fun accu aut -> Utils.ISet.union (get_aut_calls nodes aut) accu)
1069
      Utils.ISet.empty auts
1070
  in
1071
  List.fold_left
1072
    (fun accu eq -> Utils.ISet.union (get_eq_calls nodes eq) accu)
1073
    aut_calls eqs
1074

    
1075
let get_expr_vars e =
1076
  let rec get_expr_vars vars e =
1077
    get_expr_desc_vars vars e.expr_desc
1078
  and get_expr_desc_vars vars expr_desc =
1079
    (*Format.eprintf "get_expr_desc_vars expr=%a@." Printers.pp_expr (mkexpr Location.dummy_loc expr_desc);*)
1080
  match expr_desc with
1081
  | Expr_const _ -> vars
1082
  | Expr_ident x -> Utils.ISet.add x vars
1083
  | Expr_tuple el
1084
  | Expr_array el -> List.fold_left get_expr_vars vars el
1085
  | Expr_pre e1 -> get_expr_vars vars e1
1086
  | Expr_when (e1, c, _) -> get_expr_vars (Utils.ISet.add c vars) e1 
1087
  | Expr_access (e1, d) 
1088
  | Expr_power (e1, d)   -> List.fold_left get_expr_vars vars [e1; expr_of_dimension d]
1089
  | Expr_ite (c, t, e) -> List.fold_left get_expr_vars vars [c; t; e]
1090
  | Expr_arrow (e1, e2) 
1091
  | Expr_fby (e1, e2) -> List.fold_left get_expr_vars vars [e1; e2]
1092
  | Expr_merge (c, hl) -> List.fold_left (fun vars (_, h) -> get_expr_vars vars h) (Utils.ISet.add c vars) hl
1093
  | Expr_appl (_, arg, None)   -> get_expr_vars vars arg
1094
  | Expr_appl (_, arg, Some r) -> List.fold_left get_expr_vars vars [arg; r]
1095
  in
1096
  get_expr_vars Utils.ISet.empty e 
1097

    
1098
let rec expr_has_arrows e =
1099
  expr_desc_has_arrows e.expr_desc
1100
and expr_desc_has_arrows expr_desc =
1101
  match expr_desc with
1102
  | Expr_const _ 
1103
  | Expr_ident _ -> false
1104
  | Expr_tuple el
1105
  | Expr_array el -> List.exists expr_has_arrows el
1106
  | Expr_pre e1 
1107
  | Expr_when (e1, _, _) 
1108
  | Expr_access (e1, _) 
1109
  | Expr_power (e1, _) -> expr_has_arrows e1
1110
  | Expr_ite (c, t, e) -> List.exists expr_has_arrows [c; t; e]
1111
  | Expr_arrow (e1, e2) 
1112
  | Expr_fby (e1, e2) -> true
1113
  | Expr_merge (_, hl) -> List.exists (fun (_, h) -> expr_has_arrows h) hl
1114
  | Expr_appl (i, e', i') -> expr_has_arrows e'
1115

    
1116
and eq_has_arrows eq =
1117
  expr_has_arrows eq.eq_rhs
1118
and aut_has_arrows aut = List.exists (fun h -> List.exists (fun stmt -> match stmt with Eq eq -> eq_has_arrows eq | Aut aut' -> aut_has_arrows aut') h.hand_stmts ) aut.aut_handlers 
1119
and node_has_arrows node =
1120
  let eqs, auts = get_node_eqs node in
1121
  List.exists (fun eq -> eq_has_arrows eq) eqs || List.exists (fun aut -> aut_has_arrows aut) auts
1122

    
1123

    
1124

    
1125
let copy_var_decl vdecl =
1126
  mkvar_decl vdecl.var_loc ~orig:vdecl.var_orig (vdecl.var_id, vdecl.var_dec_type, vdecl.var_dec_clock, vdecl.var_dec_const, vdecl.var_dec_value, vdecl.var_parent_nodeid)
1127

    
1128
let copy_const cdecl =
1129
  { cdecl with const_type = Types.new_var () }
1130

    
1131
let copy_node nd =
1132
  { nd with
1133
    node_type     = Types.new_var ();
1134
    node_clock    = Clocks.new_var true;
1135
    node_inputs   = List.map copy_var_decl nd.node_inputs;
1136
    node_outputs  = List.map copy_var_decl nd.node_outputs;
1137
    node_locals   = List.map copy_var_decl nd.node_locals;
1138
    node_gencalls = [];
1139
    node_checks   = [];
1140
    node_stateless = None;
1141
  }
1142

    
1143
let copy_top top =
1144
  match top.top_decl_desc with
1145
  | Node nd -> { top with top_decl_desc = Node (copy_node nd)  }
1146
  | Const c -> { top with top_decl_desc = Const (copy_const c) }
1147
  | _       -> top
1148

    
1149
let copy_prog top_list =
1150
  List.map copy_top top_list
1151

    
1152

    
1153
let rec expr_contains_expr expr_tag expr  =
1154
  let search = expr_contains_expr expr_tag in
1155
  expr.expr_tag = expr_tag ||
1156
      (
1157
	match expr.expr_desc with
1158
	| Expr_const _ -> false
1159
	| Expr_array el -> List.exists search el
1160
	| Expr_access (e1, _) 
1161
	| Expr_power (e1, _) -> search e1
1162
	| Expr_tuple el -> List.exists search el
1163
	| Expr_ite (c, t, e) -> List.exists search [c;t;e]
1164
	| Expr_arrow (e1, e2)
1165
	| Expr_fby (e1, e2) -> List.exists search [e1; e2]
1166
	| Expr_pre e' 
1167
	| Expr_when (e', _, _) -> search e'
1168
	| Expr_merge (_, hl) -> List.exists (fun (_, h) -> search h) hl
1169
	| Expr_appl (_, e', None) -> search e' 
1170
	| Expr_appl (_, e', Some e'') -> List.exists search [e'; e''] 
1171
	| Expr_ident _ -> false
1172
      )
1173

    
1174

    
1175

    
1176

    
1177
(* Local Variables: *)
1178
(* compile-command:"make -C .." *)
1179
(* End: *)
(17-17/73)