/src/clock_calculus.ml - LustreC

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lustrec/src/clock_calculus.ml @ 6cbbe1c1

       (********************************************************************)
       (*                                                                  *)
       (*  The LustreC compiler toolset   /  The LustreC Development Team  *)
       (*  Copyright 2012 -    --   ONERA - CNRS - INPT - LIFL             *)
       (*                                                                  *)
       (*  LustreC is free software, distributed WITHOUT ANY WARRANTY      *)
       (*  under the terms of the GNU Lesser General Public License        *)
       (*  version 2.1.                                                    *)
       (*                                                                  *)
       (*  This file was originally from the Prelude compiler              *)
       (*                                                                  *)
       (********************************************************************)
       (** Main clock-calculus module. Based on type inference algorithms with
         destructive unification. Uses a bit of subtyping for periodic clocks. *)
       (* Though it shares similarities with the typing module, no code
           is shared.  Simple environments, very limited identifier scoping, no
           identifier redefinition allowed. *)
       open Utils
       open Lustre_types
       open Corelang
       open Clocks
       let loc_of_cond (_s, e) id =
         let pos_start =
           { e with Lexing.pos_cnum = e.Lexing.pos_cnum - (String.length id) }
         in
         pos_start, e
       (** [occurs cvar ck] returns true if the clock variable [cvar] occurs in
           clock [ck]. False otherwise. *)
       let rec occurs cvar ck =
         let ck = repr ck in
         match ck.cdesc with
         | Carrow (ck1, ck2) ->
             (occurs cvar ck1) || (occurs cvar ck2)
         | Ctuple ckl ->
             List.exists (occurs cvar) ckl
         | Con (ck',_,_) -> occurs cvar ck'
         | Cvar  -> ck=cvar
         | Cunivar   -> false
         | Clink ck' -> occurs cvar ck'
         | Ccarrying (_,ck') -> occurs cvar ck'
       (* Clocks generalization *)
       let rec generalize_carrier cr =
         match cr.carrier_desc with
         | Carry_const _
         | Carry_name ->
           if cr.carrier_scoped then
             raise (Scope_carrier cr);
           cr.carrier_desc <- Carry_var
         | Carry_var -> ()
         | Carry_link cr' -> generalize_carrier cr'
       (** Promote monomorphic clock variables to polymorphic clock variables. *)
       (* Generalize by side-effects *)
       let rec generalize ck =
         match ck.cdesc with
         | Carrow (ck1,ck2) ->
           generalize ck1; generalize ck2
         | Ctuple clist ->
           List.iter generalize clist
         | Con (ck',cr,_) -> generalize ck'; generalize_carrier cr
         | Cvar ->
           if ck.cscoped then
             raise (Scope_clock ck);
           ck.cdesc <- Cunivar
         | Cunivar -> ()
         | Clink ck' ->
           generalize ck'
         | Ccarrying (cr,ck') ->
           generalize_carrier cr; generalize ck'
       let try_generalize ck_node loc =
         try
           generalize ck_node
         with
         | Scope_carrier cr ->
           raise (Error (loc, Carrier_extrusion (ck_node, cr)))
         | Scope_clock ck ->
           raise (Error (loc, Clock_extrusion (ck_node, ck)))
       (* Clocks instanciation *)
       let instantiate_carrier cr inst_cr_vars =
         let cr = carrier_repr cr in
         match cr.carrier_desc with
         | Carry_const _
         | Carry_name -> cr
         | Carry_link _ ->
             failwith "Internal error"
         | Carry_var ->
             try
               List.assoc cr.carrier_id !inst_cr_vars
             with Not_found ->
               let cr_var = new_carrier Carry_name true in
               inst_cr_vars := (cr.carrier_id,cr_var)::!inst_cr_vars;
               cr_var
       (** Downgrade polymorphic clock variables to monomorphic clock variables *)
       (* inst_ck_vars ensures that a polymorphic variable is instanciated with
          the same monomorphic variable if it occurs several times in the same
          type. inst_cr_vars is the same for carriers. *)
       let rec instantiate inst_ck_vars inst_cr_vars ck =
         match ck.cdesc with
         | Carrow (ck1,ck2) ->
             {ck with cdesc =
              Carrow ((instantiate inst_ck_vars inst_cr_vars ck1),
                      (instantiate inst_ck_vars inst_cr_vars ck2))}
         | Ctuple cklist ->
             {ck with cdesc = Ctuple
                (List.map (instantiate inst_ck_vars inst_cr_vars) cklist)}
         | Con (ck',c,l) ->
             let c' = instantiate_carrier c inst_cr_vars in
             {ck with cdesc = Con ((instantiate inst_ck_vars inst_cr_vars ck'),c',l)}
         | Cvar  -> ck
         | Clink ck' ->
             {ck with cdesc = Clink (instantiate inst_ck_vars inst_cr_vars ck')}
         | Ccarrying (cr,ck') ->
             let cr' = instantiate_carrier cr inst_cr_vars in
               {ck with cdesc =
                Ccarrying (cr',instantiate inst_ck_vars inst_cr_vars ck')}
         | Cunivar ->
             try
               List.assoc ck.cid !inst_ck_vars
             with Not_found ->
               let var = new_ck Cvar true in
       	inst_ck_vars := (ck.cid, var)::!inst_ck_vars;
       	var
       let rec update_scope_carrier scoped cr =
         if (not scoped) then
           begin
             cr.carrier_scoped <- scoped;
             match cr.carrier_desc with
       	| Carry_const _ | Carry_name | Carry_var -> ()
             | Carry_link cr' -> update_scope_carrier scoped cr'
           end
       let rec update_scope scoped ck =
         if (not scoped) then
           begin
             ck.cscoped <- scoped;
             match ck.cdesc with
             | Carrow (ck1,ck2) ->
                 update_scope scoped ck1; update_scope scoped ck2
             | Ctuple clist ->
                 List.iter (update_scope scoped) clist
             | Con (ck', _, _) -> update_scope scoped ck'(*; update_scope_carrier scoped cr*)
             | Cvar | Cunivar -> ()
             | Clink ck' ->
                 update_scope scoped ck'
             | Ccarrying (cr,ck') ->
                 update_scope_carrier scoped cr; update_scope scoped ck'
           end
       (* Unifies two clock carriers *)
       let unify_carrier cr1 cr2 =
         let cr1 = carrier_repr cr1 in
         let cr2 = carrier_repr cr2 in
         if cr1==cr2 then ()
         else
           match cr1.carrier_desc, cr2.carrier_desc with
           | Carry_const id1, Carry_const id2 ->
             if id1 <> id2 then raise (Mismatch (cr1, cr2))
           | Carry_const _, Carry_name ->
             begin
       	cr2.carrier_desc <- Carry_link cr1;
       	update_scope_carrier cr2.carrier_scoped cr1
             end
           | Carry_name, Carry_const _ ->
             begin
               cr1.carrier_desc <- Carry_link cr2;
               update_scope_carrier cr1.carrier_scoped cr2
             end
           | Carry_name, Carry_name ->
             if cr1.carrier_id < cr2.carrier_id then
               begin
                 cr2.carrier_desc <- Carry_link cr1;
                 update_scope_carrier cr2.carrier_scoped cr1
               end
             else
               begin
                 cr1.carrier_desc <- Carry_link cr2;
                 update_scope_carrier cr1.carrier_scoped cr2
               end
           | _,_ -> assert false
       (* Semi-unifies two clock carriers *)
       let semi_unify_carrier cr1 cr2 =
         let cr1 = carrier_repr cr1 in
         let cr2 = carrier_repr cr2 in
         if cr1==cr2 then ()
         else
           match cr1.carrier_desc, cr2.carrier_desc with
           | Carry_const id1, Carry_const id2 ->
             if id1 <> id2 then raise (Mismatch (cr1, cr2))
           | Carry_const _, Carry_name ->
             begin
       	cr2.carrier_desc <- Carry_link cr1;
       	update_scope_carrier cr2.carrier_scoped cr1
             end
           | Carry_name, Carry_const _ -> raise (Mismatch (cr1, cr2))
           | Carry_name, Carry_name ->
             if cr1.carrier_id < cr2.carrier_id then
               begin
                 cr2.carrier_desc <- Carry_link cr1;
                 update_scope_carrier cr2.carrier_scoped cr1
               end
             else
               begin
                 cr1.carrier_desc <- Carry_link cr2;
                 update_scope_carrier cr1.carrier_scoped cr2
               end
           | _,_ -> assert false
       let try_unify_carrier ck1 ck2 loc =
         try
           unify_carrier ck1 ck2
         with
         | Unify (ck1',ck2') ->
           raise (Error (loc, Clock_clash (ck1',ck2')))
         | Mismatch (cr1,cr2) ->
           raise (Error (loc, Carrier_mismatch (cr1,cr2)))
       (** [unify ck1 ck2] unifies clocks [ck1] and [ck2]. Raises [Unify
           (ck1,ck2)] if the clocks are not unifiable.*)
       let rec unify ck1 ck2 =
         let ck1 = repr ck1 in
         let ck2 = repr ck2 in
         if ck1==ck2 then
           ()
         else
           match ck1.cdesc,ck2.cdesc with
           | Cvar, Cvar ->
             if ck1.cid < ck2.cid then
               begin
                 ck2.cdesc <- Clink (simplify ck1);
                 update_scope ck2.cscoped ck1
               end
             else
               begin
                 ck1.cdesc <- Clink (simplify ck2);
                 update_scope ck1.cscoped ck2
               end
           | (Cvar, _) when (not (occurs ck1 ck2)) ->
             update_scope ck1.cscoped ck2;
             ck1.cdesc <- Clink (simplify ck2)
           | (_, Cvar) when (not (occurs ck2 ck1)) ->
             update_scope ck2.cscoped ck1;
             ck2.cdesc <- Clink (simplify ck1)
           | Ccarrying (cr1,ck1'),Ccarrying (cr2,ck2') ->
             unify_carrier cr1 cr2;
             unify ck1' ck2'
           | Ccarrying (_,_),_ | _,Ccarrying (_,_) ->
             raise (Unify (ck1,ck2))
           | Carrow (c1,c2), Carrow (c1',c2') ->
             unify c1 c1'; unify c2 c2'
           | Ctuple ckl1, Ctuple ckl2 ->
             if (List.length ckl1) <> (List.length ckl2) then
               raise (Unify (ck1,ck2));
             List.iter2 unify ckl1 ckl2
           | Con (ck',c1,l1), Con (ck'',c2,l2) when l1=l2 ->
             unify_carrier c1 c2;
             unify ck' ck''
           | Cunivar, _ | _, Cunivar -> ()
           | _,_ -> raise (Unify (ck1,ck2))
       (** [unify ck1 ck2] semi-unifies clocks [ck1] and [ck2]. Raises [Unify
           (ck1,ck2)] if the clocks are not semi-unifiable.*)
       let rec semi_unify ck1 ck2 =
         let ck1 = repr ck1 in
         let ck2 = repr ck2 in
         if ck1==ck2 then
           ()
         else
             match ck1.cdesc,ck2.cdesc with
             | Cvar, Cvar ->
                 if ck1.cid < ck2.cid then
                   begin
                     ck2.cdesc <- Clink (simplify ck1);
                     update_scope ck2.cscoped ck1
                   end
                 else
                   begin
                     ck1.cdesc <- Clink (simplify ck2);
                     update_scope ck1.cscoped ck2
                   end
             | (Cvar, _) -> raise (Unify (ck1,ck2))
             | (_, Cvar) when (not (occurs ck2 ck1)) ->
                 update_scope ck2.cscoped ck1;
                 ck2.cdesc <- Clink (simplify ck1)
             | Ccarrying (cr1,ck1'),Ccarrying (cr2,ck2') ->
                 semi_unify_carrier cr1 cr2;
                 semi_unify ck1' ck2'
             | Ccarrying (_,_),_ | _,Ccarrying (_,_) ->
                 raise (Unify (ck1,ck2))
             | Carrow (c1,c2), Carrow (c1',c2') ->
       	begin
                 semi_unify c1 c1';
       	  semi_unify c2 c2'
       	end
             | Ctuple ckl1, Ctuple ckl2 ->
                 if (List.length ckl1) <> (List.length ckl2) then
                   raise (Unify (ck1,ck2));
                 List.iter2 semi_unify ckl1 ckl2
             | Con (ck',c1,l1), Con (ck'',c2,l2) when l1=l2 ->
                 semi_unify_carrier c1 c2;
                 semi_unify ck' ck''
             | Cunivar, _ | _, Cunivar -> ()
             | _,_ -> raise (Unify (ck1,ck2))
       (* Returns the value corresponding to a pclock (integer) factor
          expression. Expects a constant expression (checked by typing). *)
       let int_factor_of_expr e =
         match e.expr_desc with
         | Expr_const
             (Const_int i) -> i
         | _ -> failwith "Internal error: int_factor_of_expr"
       (** [clock_uncarry ck] drops the possible carrier(s) name(s) from clock [ck] *)
       let rec clock_uncarry ck =
         let ck = repr ck in
         match ck.cdesc with
         | Ccarrying (_, ck') -> ck'
         | Con(ck', cr, l)    -> clock_on (clock_uncarry ck') cr l
         | Ctuple ckl         -> clock_of_clock_list (List.map clock_uncarry ckl)
         | _                  -> ck
       let try_unify ck1 ck2 loc =
         try
           unify ck1 ck2
         with
         | Unify (ck1',ck2') ->
           raise (Error (loc, Clock_clash (ck1',ck2')))
         | Mismatch (cr1,cr2) ->
           raise (Error (loc, Carrier_mismatch (cr1,cr2)))
       let try_semi_unify ck1 ck2 loc =
         try
           semi_unify ck1 ck2
         with
         | Unify (ck1',ck2') ->
           raise (Error (loc, Clock_clash (ck1',ck2')))
         | Mismatch (cr1,cr2) ->
           raise (Error (loc, Carrier_mismatch (cr1,cr2)))
       (* ck2 is a subtype of ck1 *)
       let rec sub_unify sub ck1 ck2 =
         match (repr ck1).cdesc, (repr ck2).cdesc with
         | Ctuple cl1         , Ctuple cl2         ->
           if List.length cl1 <> List.length cl2
           then raise (Unify (ck1, ck2))
           else List.iter2 (sub_unify sub) cl1 cl2
         | Ctuple [c1]        , _                  -> sub_unify sub c1 ck2
         | _                  , Ctuple [c2]        -> sub_unify sub ck1 c2
         | Con (c1, cr1, t1)  , Con (c2, cr2, t2) when t1=t2 ->
           begin
             unify_carrier cr1 cr2;
             sub_unify sub c1 c2
           end
         | Ccarrying (cr1, c1), Ccarrying (cr2, c2)->
           begin
             unify_carrier cr1 cr2;
             sub_unify sub c1 c2
           end
         | _, Ccarrying (_, c2)           when sub -> sub_unify sub ck1 c2
         | _                                       -> unify ck1 ck2
       let try_sub_unify sub ck1 ck2 loc =
         try
           sub_unify sub ck1 ck2
         with
         | Unify (ck1',ck2') ->
           raise (Error (loc, Clock_clash (ck1',ck2')))
         | Mismatch (cr1,cr2) ->
           raise (Error (loc, Carrier_mismatch (cr1,cr2)))
       (* Unifies all the clock variables in the clock type of a tuple
          expression, so that the clock type only uses at most one clock variable *)
       let unify_tuple_clock ref_ck_opt ck loc =
       (*(match ref_ck_opt with
       | None     -> Format.eprintf "unify_tuple_clock None %a@." Clocks.print_ck ck
         | Some ck' -> Format.eprintf "unify_tuple_clock (Some %a) %a@." Clocks.print_ck ck' Clocks.print_ck ck);*)
         let ck_var = ref ref_ck_opt in
         let rec aux ck =
           match (repr ck).cdesc with
           | Con _
           | Cvar ->
               begin
                 match !ck_var with
                 | None ->
                     ck_var:=Some ck
                 | Some v ->
                     (* may fail *)
                     try_unify ck v loc
               end
           | Ctuple cl ->
               List.iter aux cl
           | Carrow _ -> assert false (* should not occur *)
           | Ccarrying (_, ck1) ->
               aux ck1
           | _ -> ()
         in aux ck
       (* Unifies all the clock variables in the clock type of an imported
          node, so that the clock type only uses at most one base clock variable,
          that is, the activation clock of the node *)
       let unify_imported_clock ref_ck_opt ck loc =
         let ck_var = ref ref_ck_opt in
         let rec aux ck =
           match (repr ck).cdesc with
           | Cvar ->
             begin
               match !ck_var with
               | None ->
                 ck_var := Some ck
               | Some v ->
                 (* cannot fail *)
                 try_unify ck v loc
             end
           | Ctuple cl ->
             List.iter aux cl
           | Carrow (ck1,ck2) ->
             aux ck1; aux ck2
           | Ccarrying (_, ck1) ->
             aux ck1
           | Con (ck1, _, _) -> aux ck1
           | _ -> ()
         in
         aux ck
       (* Computes the root clock of a tuple or a node clock,
          which is not the same as the base clock.
          Root clock will be used as the call clock
          of a given node instance *)
       let compute_root_clock ck =
         let root = Clocks.root ck in
         let branch = ref None in
         let rec aux ck =
           match (repr ck).cdesc with
           | Ctuple cl ->
               List.iter aux cl
           | Carrow (ck1,ck2) ->
               aux ck1; aux ck2
           | _ ->
               begin
                 match !branch with
                 | None ->
                     branch := Some (Clocks.branch ck)
                 | Some br ->
                     (* cannot fail *)
                     branch := Some (Clocks.common_prefix br (Clocks.branch ck))
               end
         in
         begin
           aux ck;
           Clocks.clock_of_root_branch root (Utils.desome !branch)
         end
       (* Clocks a list of arguments of Lustre builtin operators:
          - type each expression, remove carriers of clocks as
            carriers may only denote variables, not arbitrary expr.
          - try to unify these clocks altogether
       *)
       let rec clock_standard_args env expr_list =
         let ck_list = List.map (fun e -> clock_uncarry (clock_expr env e)) expr_list in
         let ck_res = new_var true in
         List.iter2 (fun e ck -> try_unify ck ck_res e.expr_loc) expr_list ck_list;
         ck_res
       (* emulates a subtyping relation between clocks c and (cr : c),
          used during node application only *)
       and clock_subtyping_arg env ?(sub=true) real_arg formal_clock =
         let loc = real_arg.expr_loc in
         let real_clock = clock_expr env real_arg in
         try_sub_unify sub formal_clock real_clock loc
       (* computes clocks for node application *)
       and clock_appl env f args clock_reset loc =
        let args = expr_list_of_expr args in
         if Basic_library.is_homomorphic_fun f && List.exists is_tuple_expr args
         then
             let args = Utils.transpose_list (List.map expr_list_of_expr args) in
             Clocks.clock_of_clock_list (List.map (fun args -> clock_call env f args clock_reset loc) args)
         else
           clock_call env f args clock_reset loc
       and clock_call env f args clock_reset loc =
         (* Format.eprintf "Clocking call %s@." f; *)
         let cfun = clock_ident false env f loc in
         let cins, couts = split_arrow cfun in
         let cins = clock_list_of_clock cins in
         List.iter2 (clock_subtyping_arg env) args cins;
         unify_imported_clock (Some clock_reset) cfun loc;
         couts
       and clock_ident nocarrier env id loc =
         clock_expr ~nocarrier:nocarrier env (expr_of_ident id loc)
       and clock_carrier env c loc ce =
         let expr_c = expr_of_ident c loc in
         let ck = clock_expr ~nocarrier:false env expr_c in
         let cr = new_carrier Carry_name (*Carry_const c*) ck.cscoped in
         let ckb = new_var true in
         let ckcarry = new_ck (Ccarrying (cr, ckb)) ck.cscoped in
         try_unify ck ckcarry expr_c.expr_loc;
         unify_tuple_clock (Some ckb) ce expr_c.expr_loc;
         cr
       (** [clock_expr env expr] performs the clock calculus for expression [expr] in
           environment [env] *)
       and clock_expr ?(nocarrier=true) env expr =
         let resulting_ck =
           match expr.expr_desc with
             | Expr_const _ ->
             let ck = new_var true in
             expr.expr_clock <- ck;
             ck
         | Expr_ident v ->
             let ckv =
               try
                 Env.lookup_value env v
               with Not_found ->
       	  failwith ("Internal error, variable \""^v^"\" not found")
             in
             let ck = instantiate (ref []) (ref []) ckv in
             expr.expr_clock <- ck;
             ck
         | Expr_array elist ->
           let ck = clock_standard_args env elist in
           expr.expr_clock <- ck;
           ck
         | Expr_access (e1, _) ->
           (* dimension, being a static value, doesn't need to be clocked *)
           let ck = clock_standard_args env [e1] in
           expr.expr_clock <- ck;
           ck
         | Expr_power (e1, _) ->
           (* dimension, being a static value, doesn't need to be clocked *)
           let ck = clock_standard_args env [e1] in
           expr.expr_clock <- ck;
           ck
         | Expr_tuple elist ->
           let ck = new_ck (Ctuple (List.map (clock_expr env) elist)) true in
           expr.expr_clock <- ck;
           ck
         | Expr_ite (c, t, e) ->
           let ck_c = clock_standard_args env [c] in
           let ck = clock_standard_args env [t; e] in
           (* Here, the branches may exhibit a tuple clock, not the condition *)
           unify_tuple_clock (Some ck_c) ck expr.expr_loc;
           expr.expr_clock <- ck;
           ck
         | Expr_appl (id, args, r) ->
           (try
       (* for a modular compilation scheme, all inputs/outputs must share the same clock !
          this is also the reset clock !
       *)
           let cr =
             match r with
             | None        -> new_var true
             | Some c      -> clock_standard_args env [c] in
           let couts = clock_appl env id args (clock_uncarry cr) expr.expr_loc in
           expr.expr_clock <- couts;
           couts
           with exn -> (
             Format.eprintf "Current expr: %a@." Printers.pp_expr expr;
             raise exn
           ))
         | Expr_fby (e1,e2)
         | Expr_arrow (e1,e2) ->
           let ck = clock_standard_args env [e1; e2] in
           unify_tuple_clock None ck expr.expr_loc;
           expr.expr_clock <- ck;
           ck
         | Expr_pre e -> (* todo : deal with phases as in tail ? *)
             let ck = clock_standard_args env [e] in
             expr.expr_clock <- ck;
             ck
         | Expr_when (e,c,l) ->
             let ce = clock_standard_args env [e] in
             let c_loc = loc_of_cond expr.expr_loc c in
             let cr = clock_carrier env c c_loc ce in
             let ck = clock_on ce cr l in
             let cr' = new_carrier (Carry_const c) ck.cscoped in
             let ck' = clock_on ce cr' l in
             expr.expr_clock <- ck';
             ck
         | Expr_merge (c,hl) ->
             let cvar = new_var true in
             let crvar = new_carrier Carry_name true in
             List.iter (fun (t, h) -> let ckh = clock_uncarry (clock_expr env h) in unify_tuple_clock (Some (new_ck (Con (cvar,crvar,t)) true)) ckh h.expr_loc) hl;
             let cr = clock_carrier env c expr.expr_loc cvar in
             try_unify_carrier cr crvar expr.expr_loc;
             let cres = clock_current ((snd (List.hd hl)).expr_clock) in
             expr.expr_clock <- cres;
             cres
         in
         Log.report ~level:4 (fun fmt -> Format.fprintf fmt "Clock of expr %a: %a@ "
                                 Printers.pp_expr expr Clocks.print_ck resulting_ck);
         resulting_ck
       let clock_of_vlist vars =
         let ckl = List.map (fun v -> v.var_clock) vars in
         clock_of_clock_list ckl
       (** [clock_eq env eq] performs the clock-calculus for equation [eq] in
           environment [env] *)
       let clock_eq env eq =
         let expr_lhs = expr_of_expr_list eq.eq_loc
             (List.map (fun v -> expr_of_ident v eq.eq_loc) eq.eq_lhs) in
         let ck_rhs = clock_expr env eq.eq_rhs in
         clock_subtyping_arg env expr_lhs ck_rhs
       (* [clock_coreclock cck] returns the clock_expr corresponding to clock
           declaration [cck] *)
       let clock_coreclock env cck id loc scoped =
         match cck.ck_dec_desc with
         | Ckdec_any -> new_var scoped
         | Ckdec_bool cl ->
             let temp_env = Env.add_value env id (new_var true) in
             (* We just want the id to be present in the environment *)
             let dummy_id_expr = expr_of_ident id loc in
             let when_expr =
               List.fold_left
                 (fun expr (x,l) ->
                       {expr_tag = new_tag ();
                        expr_desc = Expr_when (expr,x,l);
                        expr_type = Types.new_var ();
                        expr_clock = new_var scoped;
                        expr_delay = Delay.new_var ();
                        expr_loc = loc;
       		 expr_annot = None})
                 dummy_id_expr cl
             in
             clock_expr temp_env when_expr
       (* Clocks a variable declaration *)
       let clock_var_decl scoped env vdecl =
         let ck = clock_coreclock env vdecl.var_dec_clock vdecl.var_id vdecl.var_loc scoped in
         let ck =
       (* WTF ????
           if vdecl.var_dec_const
           then
             (try_generalize ck vdecl.var_loc; ck)
           else
        *)
             if Types.get_clock_base_type vdecl.var_type <> None
             then new_ck (Ccarrying (new_carrier Carry_name scoped, ck)) scoped
             else ck in
         (if vdecl.var_dec_const
          then match vdecl.var_dec_value with
          | None   -> ()
          | Some v ->
            begin
              let ck_static = clock_expr env v in
              try_unify ck ck_static v.expr_loc
            end);
         try_unify ck vdecl.var_clock vdecl.var_loc;
         Env.add_value env vdecl.var_id ck
       (* Clocks a variable declaration list *)
       let clock_var_decl_list env scoped l =
         List.fold_left (clock_var_decl scoped) env l
       (** [clock_node env nd] performs the clock-calculus for node [nd] in
           environment [env].
           Generalization of clocks wrt scopes follows this rule:
           - generalize inputs (unscoped).
           - generalize outputs. As they are scoped, only clocks coming from inputs
             are allowed to be generalized.
           - generalize locals. As outputs don't depend on them (checked the step before),
             they can be generalized.
        *)
       let clock_node env loc nd =
         (* let is_main = nd.node_id = !Options.main_node in *)
         let new_env = clock_var_decl_list env false nd.node_inputs in
         let new_env = clock_var_decl_list new_env true nd.node_outputs in
         let new_env = clock_var_decl_list new_env true nd.node_locals in
         let eqs, _ = get_node_eqs nd in (* TODO XXX: perform the clocking on auts.
       					For the moment, it is ignored *)
         List.iter (clock_eq new_env) eqs;
         let ck_ins = clock_of_vlist nd.node_inputs in
         let ck_outs = clock_of_vlist nd.node_outputs in
         let ck_node = new_ck (Carrow (ck_ins, ck_outs)) false in
         unify_imported_clock None ck_node loc;
         Log.report ~level:3 (fun fmt -> Format.fprintf fmt "Clock of %s: %a@ " nd.node_id print_ck ck_node);
         (* Local variables may contain first-order carrier variables that should be generalized.
            That's not the case for types. *)
         try_generalize ck_node loc;
         (*
           List.iter (fun vdecl -> try_generalize vdecl.var_clock vdecl.var_loc) nd.node_inputs;
           List.iter (fun vdecl -> try_generalize vdecl.var_clock vdecl.var_loc) nd.node_outputs;*)
         (*List.iter (fun vdecl -> try_generalize vdecl.var_clock vdecl.var_loc) nd.node_locals;*)
         (* TODO : Xavier pourquoi ai je cette erreur ? *)
         (*  if (is_main && is_polymorphic ck_node) then
             raise (Error (loc,(Cannot_be_polymorphic ck_node)));
         *)
         Log.report ~level:3 (fun fmt -> Format.fprintf fmt "Generalized clock of %s: %a@ @ " nd.node_id print_ck ck_node);
         nd.node_clock <- ck_node;
         Env.add_value env nd.node_id ck_node
       let check_imported_pclocks loc ck_node =
         let pck = ref None in
         let rec aux ck =
           match ck.cdesc with
           | Carrow (ck1,ck2) -> aux ck1; aux ck2
           | Ctuple cl -> List.iter aux cl
           | Con (ck',_,_) -> aux ck'
           | Clink ck' -> aux ck'
           | Ccarrying (_,ck') -> aux ck'
           | Cvar | Cunivar  ->
               match !pck with
               | None -> ()
               | Some (_,_) ->
                   raise (Error (loc, (Invalid_imported_clock ck_node)))
         in
         aux ck_node
       let clock_imported_node env loc nd =
         let new_env = clock_var_decl_list env false nd.nodei_inputs in
         ignore(clock_var_decl_list new_env false nd.nodei_outputs);
         let ck_ins = clock_of_vlist nd.nodei_inputs in
         let ck_outs = clock_of_vlist nd.nodei_outputs in
         let ck_node = new_ck (Carrow (ck_ins,ck_outs)) false in
         unify_imported_clock None ck_node loc;
         check_imported_pclocks loc ck_node;
         try_generalize ck_node loc;
         nd.nodei_clock <- ck_node;
         Env.add_value env nd.nodei_id ck_node
       let new_env = clock_var_decl_list
       let clock_top_const env cdecl=
         let ck = new_var false in
         try_generalize ck cdecl.const_loc;
         Env.add_value env cdecl.const_id ck
       let clock_top_consts env clist =
         List.fold_left clock_top_const env clist
       let rec clock_top_decl env decl =
         match decl.top_decl_desc with
         | Node nd ->
           clock_node env decl.top_decl_loc nd
         | ImportedNode nd ->
           clock_imported_node env decl.top_decl_loc nd
         | Const c ->
           clock_top_const env c
         | TypeDef _ -> List.fold_left clock_top_decl env (consts_of_enum_type decl)
         | Include _ | Open _    -> env
       let clock_prog env decls =
         List.fold_left clock_top_decl env decls
       (* Once the Lustre program is fully clocked,
          we must get back to the original description of clocks,
          with constant parameters, instead of unifiable internal variables. *)
       (* The following functions aims at 'unevaluating' carriers occuring in clock expressions,
          i.e. replacing unifiable second_order variables with the original carrier names.
          Once restored in this formulation, clocks may be meaningfully printed.
       *)
       let uneval_vdecl_generics vdecl =
        (*Format.eprintf "Clock_calculus.uneval_vdecl_generics %a@." Printers.pp_node_var vdecl;*)
        if Types.get_clock_base_type vdecl.var_type <> None
        then
          match get_carrier_name vdecl.var_clock with
          | None    -> (Format.eprintf "internal error: %a@." print_ck vdecl.var_clock; assert false)
          | Some cr -> Clocks.uneval vdecl.var_id cr
       let uneval_node_generics vdecls =
         List.iter uneval_vdecl_generics vdecls
       let uneval_top_generics decl =
         match decl.top_decl_desc with
         | Node nd ->
             (* A node could contain first-order carrier variable in local vars. This is not the case for types. *)
             uneval_node_generics (nd.node_inputs @ nd.node_locals @ nd.node_outputs)
         | ImportedNode nd ->
             uneval_node_generics (nd.nodei_inputs @ nd.nodei_outputs)
         | Const _
         | Include _ | Open _
         | TypeDef _ -> ()
       let uneval_prog_generics prog =
        List.iter uneval_top_generics prog
       let check_env_compat header declared computed =
         uneval_prog_generics header;
         Env.iter declared (fun k decl_clock_k ->
             try
               let computed_c = instantiate (ref []) (ref []) (Env.lookup_value computed k) in
               try_semi_unify decl_clock_k computed_c Location.dummy_loc
             with Not_found -> (* If the lookup failed then either an actual
                                  required element should have been declared
                                  and is missing but typing should have catch
                                  it, or it was a contract and does not
                                  require this additional check.  *)
                 ()
+          )
       (* Local Variables: *)
       (* compile-command:"make -C .." *)
       (* End: *)

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