280 lines
8.7 KiB
OCaml
280 lines
8.7 KiB
OCaml
(**************************************************************************)
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(* *)
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(* MiniLustre *)
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(* *)
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(* Author : Marc Pouzet *)
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(* Organization : Demons, LRI, University of Paris-Sud, Orsay *)
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(* *)
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(**************************************************************************)
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(* clock checking *)
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open Misc
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open Ident
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open Minils
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open Signature
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open Types
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open Location
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type error = | Etypeclash of ct * ct
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exception TypingError of error
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exception Unify
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let error kind = raise (TypingError kind)
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let message e kind =
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((match kind with | Etypeclash (actual_ct, expected_ct) -> ());
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(*TODO remettre en route quand Printer fonctionne
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Printf.eprintf "%aClock Clash: this expression has clock %a, \n\
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but is expected to have clock %a.\n"
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Printer.print_exp e
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Printer.print_clock actual_ct
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Printer.print_clock expected_ct*)
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raise Error)
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let index = ref 0
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let gen_index () = (incr index; !index)
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let new_var () = Cvar { contents = Cindex (gen_index ()); }
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let rec repr ck =
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match ck with
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| Cbase | Con _ | Cvar { contents = Cindex _ } -> ck
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| Cvar (({ contents = Clink ck } as link)) ->
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let ck = repr ck in (link.contents <- Clink ck; ck)
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let rec occur_check index ck =
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let ck = repr ck
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in
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match ck with
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| Cbase -> ()
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| Cvar { contents = Cindex n } when index <> n -> ()
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| Con (ck, _, _) -> occur_check index ck
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| _ -> raise Unify
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let rec ck_value ck =
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match ck with
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| Cbase | Con _ | Cvar { contents = Cindex _ } -> ck
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| Cvar { contents = Clink ck } -> ck_value ck
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let rec unify t1 t2 =
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if t1 == t2
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then ()
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else
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(match (t1, t2) with
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| (Ck ck1, Ck ck2) -> unify_ck ck1 ck2
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| (Cprod ct_list1, Cprod ct_list2) ->
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(try List.iter2 unify ct_list1 ct_list2 with | _ -> raise Unify)
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| _ -> raise Unify)
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and unify_ck ck1 ck2 =
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let ck1 = repr ck1 in
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let ck2 = repr ck2
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in
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if ck1 == ck2
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then ()
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else
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(match (ck1, ck2) with
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| (Cbase, Cbase) -> ()
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| (Cvar { contents = Cindex n1 }, Cvar { contents = Cindex n2 }) when
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n1 = n2 -> ()
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| (Cvar (({ contents = Cindex n1 } as v)), _) ->
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(occur_check n1 ck2; v.contents <- Clink ck2)
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| (_, Cvar (({ contents = Cindex n2 } as v))) ->
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(occur_check n2 ck1; v.contents <- Clink ck1)
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| (Con (ck1, c1, n1), Con (ck2, c2, n2)) when (c1 = c2) & (n1 = n2) ->
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unify_ck ck1 ck2
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| _ -> raise Unify)
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let rec eq ck1 ck2 =
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match ((repr ck1), (repr ck2)) with
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| (Cbase, Cbase) -> true
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| (Cvar { contents = Cindex n1 }, Cvar { contents = Cindex n2 }) -> true
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| (Con (ck1, _, n1), Con (ck2, _, n2)) when n1 = n2 -> eq ck1 ck2
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| _ -> false
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let rec unify t1 t2 =
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match (t1, t2) with
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| (Ck ck1, Ck ck2) -> unify_ck ck1 ck2
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| (Cprod t1_list, Cprod t2_list) -> unify_list t1_list t2_list
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| _ -> raise Unify
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and unify_list t1_list t2_list =
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try List.iter2 unify t1_list t2_list with | _ -> raise Unify
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let rec skeleton ck = function
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| Tprod ty_list -> Cprod (List.map (skeleton ck) ty_list)
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| Tarray _ | Tid _ -> Ck ck
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let ckofct = function | Ck ck -> repr ck | Cprod ct_list -> Cbase
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let prod =
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function | [] -> assert false | [ ty ] -> ty | ty_list -> Tprod ty_list
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let typ_of_name h x = Env.find x h
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let rec typing h e =
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let ct =
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match e.e_desc with
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| Econst _ | Econstvar _ -> Ck (new_var ())
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| Evar x -> Ck (typ_of_name h x)
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| Efby (c, e) -> typing h e
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| Etuple e_list -> Cprod (List.map (typing h) e_list)
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| Ecall(_, e_list, r) ->
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let ck_r = match r with
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| None -> new_var()
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| Some(reset) -> typ_of_name h reset
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in (List.iter (expect h (Ck ck_r)) e_list; skeleton ck_r e.e_ty)
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| Ecall(_, e_list, Some(reset)) ->
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let ck_r = typ_of_name h reset
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in (List.iter (expect h (Ck ck_r)) e_list; skeleton ck_r e.e_ty)
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| Ewhen (e, c, n) ->
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let ck_n = typ_of_name h n
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in (expect h (skeleton ck_n e.e_ty) e;
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skeleton (Con (ck_n, c, n)) e.e_ty)
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| Eifthenelse (e1, e2, e3) ->
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let ck = new_var () in
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let ct = skeleton ck e.e_ty
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in (expect h (Ck ck) e1; expect h ct e2; expect h ct e3; ct)
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| Emerge (n, c_e_list) ->
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let ck_c = typ_of_name h n
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in (typing_c_e_list h ck_c n c_e_list; skeleton ck_c e.e_ty)
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| Efield (e1, n) ->
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let ck = new_var () in
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let ct = skeleton ck e1.e_ty in (expect h (Ck ck) e1; ct)
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| Efield_update (_, e1, e2) ->
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let ck = new_var () in
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let ct = skeleton ck e.e_ty
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in (expect h (Ck ck) e1; expect h ct e2; ct)
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| Estruct l ->
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let ck = new_var () in
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(List.iter
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(fun (n, e) -> let ct = skeleton ck e.e_ty in expect h ct e) l;
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Ck ck)
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| Earray e_list ->
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let ck = new_var ()
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in (List.iter (expect h (Ck ck)) e_list; skeleton ck e.e_ty)
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| Earray_op(op) -> typing_array_op h e op
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in (e.e_ck <- ckofct ct; ct)
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and typing_array_op h e = function
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| Erepeat (_, e) -> typing h e
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| Eselect (_, e) -> typing h e
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| Eselect_dyn (e_list, _, e, defe) ->
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let ck = new_var () in
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let ct = skeleton ck e.e_ty
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in (expect h ct e; List.iter (expect h ct) e_list; ct)
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| Eupdate (_, e1, e2) ->
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let ck = new_var () in
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let ct = skeleton ck e.e_ty
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in (expect h (Ck ck) e1; expect h ct e2; ct)
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| Eselect_slice (_, _, e) -> typing h e
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| Econcat (e1, e2) ->
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let ck = new_var () in
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let ct = skeleton ck e.e_ty
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in (expect h (Ck ck) e1; expect h ct e2; ct)
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| Eiterator (_, _, _, e_list, r) ->
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let ck_r = match r with
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| None -> new_var()
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| Some(reset) -> typ_of_name h reset
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in (List.iter (expect h (Ck ck_r)) e_list; skeleton ck_r e.e_ty)
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and expect h expected_ty e =
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let actual_ty = typing h e
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in
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try unify actual_ty expected_ty
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with | Unify -> message e (Etypeclash (actual_ty, expected_ty))
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and typing_c_e_list h ck_c n c_e_list =
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let rec typrec =
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function
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| [] -> ()
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| (c, e) :: c_e_list ->
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(expect h (skeleton (Con (ck_c, c, n)) e.e_ty) e; typrec c_e_list)
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in typrec c_e_list
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let rec typing_pat h =
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function
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| Evarpat x -> Ck (typ_of_name h x)
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| Etuplepat pat_list -> Cprod (List.map (typing_pat h) pat_list)
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let typing_eqs h eq_list =
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List.iter
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(fun { eq_lhs = pat; eq_rhs = e } ->
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match e.e_desc with (*TODO FIXME*)
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| _ ->
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let ty_pat = typing_pat h pat
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in
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(try expect h ty_pat e
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with
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| Error ->
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(* TODO remettre en route quand Printer fonctionne
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(* DEBUG *)
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Printf.eprintf "Complete expression: %a\n"
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Printer.print_exp e;
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Printf.eprintf "Clock pattern: %a\n"
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Printer.print_clock ty_pat; *)
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raise Error))
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eq_list
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let build h dec =
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List.fold_left (fun h { v_name = n } -> Env.add n (new_var ()) h) h dec
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let sbuild h dec base =
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List.fold_left (fun h { v_name = n } -> Env.add n base h) h dec
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let typing_contract h contract base =
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match contract with
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| None -> h
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| Some
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{
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c_local = l_list;
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c_eq = eq_list;
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c_assume = e_a;
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c_enforce = e_g;
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c_controllables = c_list
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} ->
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let h = sbuild h c_list base in
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let h' = build h l_list
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in
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(* assumption *)
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(* property *)
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(typing_eqs h' eq_list;
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expect h' (Ck base) e_a;
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expect h' (Ck base) e_g;
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h)
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let typing_node (({
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n_name = f;
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n_input = i_list;
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n_output = o_list;
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n_contract = contract;
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n_local = l_list;
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n_equs = eq_list
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} as node))
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=
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let base = Cbase in
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let h = sbuild Env.empty i_list base in
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let h = sbuild h o_list base in
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let h = typing_contract h contract base in
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let h = build h l_list
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in
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(typing_eqs h eq_list;
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(*update clock info in variables descriptions *)
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let set_clock vd =
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{ (vd) with v_clock = ck_value (Env.find vd.v_name h); }
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in
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{
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(node)
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with
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n_input = List.map set_clock i_list;
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n_output = List.map set_clock o_list;
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n_local = List.map set_clock l_list;
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})
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let program (({ p_nodes = p_node_list } as p)) =
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{ (p) with p_nodes = List.map typing_node p_node_list; }
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