open Ast exception LocError of loc * string exception Error of string let er_ident i = raise (Error ("Unknown identifier " ^ i)) let er_ident_loc i loc = raise (LocError (loc, "Unknown identifier " ^ i)) let er_not_a_variable i = raise (Error ("Expected '"^i^"' to be a variable")) let er_not_a_function i = raise (Error ("Expected '"^i^"' to be a function")) let er_tident_use () = raise (Error ("Er_tident_use")) let er_double_ref () = raise (Error ("Er_double_ref")) let er_ref_use ()= raise (Error ("Er_ref_use")) let er_not_implemented () = raise (Error ("Not implemented")) type typ = | T_Int | Typenull | T_Void | TClass of tident | TPoint of typ type type_ref = typ * bool (* type d'une variable, avec ref? *) type texpression = { te_loc: loc; te_desc: texpr_desc; type_expr : typ*bool*bool; (* Type, référence?, valeur gauche? *) } and texpr_desc = | TEInt of int | TENull | TEThis | TEIdent of ident | TEAssign of texpression * texpression | TECallFun of ident * texpression list (* changé : te -> ident *) (* | TECallMethod of texpression * ident * texpression list *) (* changé : te -> ident *) | TEUnary of unop * texpression | TEBinary of texpression * binop * texpression | TEMember of texpression * ident | TENew of tident * texpression list type tstr_expression = | TSEExpr of texpression | TSEStr of string module Smap = Map.Make(String) type tstatement = { ts_loc: loc; ts_desc: ts_desc; } and ts_desc = | TSEmpty | TSExpr of texpression | TSIf of texpression * tstatement * tstatement | TSWhile of texpression * tstatement | TSFor of texpression list * texpression option * texpression list * tstatement | TSBlock of tblock | TSReturn of texpression option | TSDeclare of type_ref * ident | TSDeclareAssignExpr of type_ref * ident * texpression | TSDeclareAssignConstructor of var_type * ident * tident * texpression list (* a faire *) (* Type of variable, variable name, constructor class name, constructor arguments *) | TSWriteCout of tstr_expression list and tblock = tstatement list and tproto = { tp_loc : loc; tp_name : ident; tp_class : tident option; (* p_class = none : standalone function *) tp_ret_type : type_ref option; (* p_class = some and p_ret_type = none : constructor *) tp_args : (type_ref * ident) list; } type mem = (* type d'une expression *) | Var of type_ref | Fun of tproto * tblock | Env of stmt (* statement type *) and stmt = mem Smap.t (* string -> env *) type tcls_mem = | TCVar of var_type * ident | TCMethod of tproto | TCVirtualMethod of tproto type tcls = { tc_name : tident; tc_supers : tident list option; tc_members : tcls_mem list; } type tdeclaration = | TDGlobal of (type_ref * ident) | TDFunction of (tproto * tblock) | TDClass of tcls | TDNothing type tprogram = tdeclaration list (* Quelques fonctions utiles : *) let find_v i env = match Smap.find i env with | Var tr -> tr | _ -> er_not_a_variable i let find_f i env = match Smap.find i env with | Fun (p,t) -> (p,t) | _ -> er_not_a_function i let same_type t1 t2 = (* types mem *) let tr1 = (match t1 with | Var (typ,_) -> typ | _ -> er_not_a_variable "") in let tr2 = (match t2 with | Var (typ,_) -> typ | _ -> er_not_a_variable "") in tr1 = tr2 let rec bf = function (* true si bien formé *) | T_Int -> true | TClass _ -> true | TPoint t -> bf t | _ -> false let num = function | T_Int -> true | Typenull -> true | TPoint _ -> true | _ -> false (* !! modifier si on peut pas être un type num peut pas aller avec une ref *) let build_type_or_ref vt = (* vt -> typ,bool = tr, true si ref *) let rec see = function | TPtr vt -> TPoint (see vt) | TVoid -> T_Void | TInt -> T_Int | TRef _ -> er_ref_use() | TIdent tid -> TClass tid in match vt with | TRef (TRef vt) -> er_double_ref() (* ... *) | TRef vt -> (see vt),true (* indique qu'il s'agit d'une ref *) | vt -> (see vt),false (* -------------------------------------------- *) (* On passe aux choses sérieuses *) let rec type_expr env e = (* expression -> texpression *) try let d,(ty,b1,b2) = compute_type env e in { te_loc = e.e_loc; te_desc = d; type_expr = (ty,b1,b2) } with | Error(k) -> raise (LocError(e.e_loc, k)) | LocError(_, _) as e -> raise e | _ -> raise (LocError (e.e_loc,"Other error")) and get_expr0 env e = (* expression -> texpression,(ty,b1,b2) *) let te = type_expr env e in (te,te.type_expr) and get_expr env e = (* expression -> texpression,(ty,b) *) let te = type_expr env e in let (ty,b,_) = te.type_expr in (te,(ty,b)) and compute_type env e = match e.e_desc with (* expression -> te_desc,(typ,ref?,left?) *) | EInt n -> TEInt n, (T_Int,false,false) (* false, : pas une ref, pas une val gauche*) | EBool b -> let n = (if b then 1 else 0) in TEInt n, (T_Int,false,false) | ENull -> TENull, (Typenull,false,false) | EIdent i -> (try let ty,b = find_v i env in (* pb avec (i,bool) *) assert (bf ty); (* règle champs p4 *) TEIdent i,(ty,b,true) with Not_found -> er_ident i ) | EAssign (e1,e2) -> let te1,(ty1,_,b3) = get_expr0 env e1 in let te2,(ty2,_,_) = get_expr0 env e2 in assert (b3 = true); assert (num ty1); (* type num et ref compatibles ?*) (TEAssign (te1,te2) ),(ty1,false,false) | EUnary (op,e) -> let te,(ty,b1,b2) = get_expr0 env e in (match op with | PreIncr | PostIncr | PreDecr | PostDecr -> assert (b2 = true); assert (ty = T_Int); TEUnary(op,te),(T_Int,b1,false) | Plus | Minus | Not -> assert (ty = T_Int); TEUnary(op,te),(T_Int,false,false) | Ref -> assert b2; TEUnary(op,te),(TPoint ty,false,false) (* verif *) | Deref -> let t = (match ty with | TPoint t -> t | _ -> failwith "On attend un type pointeur" ) in TEUnary(op,te), (t,true,false) ) | EBinary (e1,op,e2) -> let te1,(ty1,_,b1) = get_expr0 env e1 in let te2,(ty2,_,b2) = get_expr0 env e2 in (match op with | Equal | NotEqual -> assert (ty1 = ty2); assert (num ty1) | Lt | Le | Gt | Ge | Add | Sub | Mul | Div | Modulo | Land | Lor -> assert (ty1 = T_Int); assert (ty2 = T_Int) ); (* vérifs *) TEBinary(te1,op,te2),(T_Int,false,false) | ECall (e,e_list) -> let name = (match e.e_desc with | EIdent i -> i | _ -> failwith "Not a function") in let tproto,tblock = find_f name env in (* chope la fonction *) let args = List.map (fun ((ty,_),_) -> ty) tproto.tp_args in (* pas adressage pris en compte *) let l = List.map (get_expr env) e_list in let tab = Array.of_list args in List.iteri (fun j (te,(ty0,b)) -> assert (ty0 = tab.(j) ) ) l ; (* vérif ici pour adresse/valeur, ici on test seulement que ce sont les mêmes types, pas d'adressage de pris en compte *) let l_te = List.map fst l in (* que les te de e_list*) let ty = match tproto.tp_ret_type with | None -> T_Void | Some (ty,b) -> ty in TECallFun(name,l_te),(ty,false,false) | EMember _ -> TEInt 0, (T_Int,false,false) | ENew _ -> TEInt 0, (T_Int,false,false) | EThis -> TEInt 0, (T_Int,false,false) (* Statements *) let rec type_stm env s = let d, ty = compute_type_stm env s in { ts_loc = s.s_loc; ts_desc = d }, ty and compute_type_stm env s = match s.s_desc with (* statement -> ts_desc,stm_type *) | SEmpty -> TSEmpty,env | SExpr e -> let te,(ty,_) = get_expr env e in (* verif ty est bien typé *) (TSExpr te) , env | SBlock b -> build_block env b | SReturn None -> (TSReturn None) , env | SReturn (Some e0) -> let te,(ty,_) = get_expr env e0 in TSReturn (Some te), env | SIf (e,s1,s2) -> let te,(ty,_) = get_expr env e in let ts1,ty1 = type_stm env s1 in (* vérifs règle *) let ts2,ty2 = type_stm env s2 in assert (ty = T_Int); (TSIf (te,ts1,ts2)) , env | SFor (el1,eopt,el3,s) -> let tel1 = List.map (type_expr env) el1 in (* et fait les vérifs pr e1 et e3 ? *) let tel3 = List.map (type_expr env) el3 in let teopt = (match eopt with | None -> None | Some e -> let te,(ty,_) = get_expr env e in assert (ty = T_Int); Some te) in ignore( type_stm env s ); (* vérifie i *) let ts, _ = type_stm env s in (* fait le truc d'avant aussi *) TSFor (tel1,teopt,tel3,ts) , env (* traduire règles restantes du for*) | SWhile(e,s) -> let ts,tys = type_stm env s in let te,(ty,_) = get_expr env e in TSWhile(te,ts),env (* pq while n'est pas dans les règles données ? *) | SDeclare(vt,i) -> let ty,b = build_type_or_ref vt in assert (bf ty); assert (not (Smap.mem i env) ); let env0 = Smap.add i (Var (ty,b)) env in TSDeclare( (ty,b) ,i) , env0 | SDeclareAssignExpr(vt,i,e) -> let ty,b = build_type_or_ref vt in assert (bf ty); assert (not (Smap.mem i env)); let te,(tye,_) = get_expr env e in (* assert tye let args = List.map (fun e -> match e.se_desc with | SEExpr e0 -> let te,(ty,_) = get_expr env {e_loc = e.se_loc; e_desc = e0} in assert (ty = T_Int); TSEExpr te | SEStr s -> TSEStr(s) (* osef *) ) str_e_list in TSWriteCout(args) , env | SDeclareAssignConstructor(vt,i,ti,e_l) -> TSEmpty,env (* a faire *) and build_block env b = (* utilisé ds compute_type_stm et def_global_fun *) let two_stms (env,l) s = let ts,ty = type_stm env s in (ty,(ts::l)) in let ty_final,ts_list = List.fold_left two_stms (env,[]) b in (* verif si b bien typé (règle i1;i2) et construit le te-block*) TSBlock (List.rev ts_list),env and get_block env b = match fst (build_block env b) with | TSBlock tb -> tb | _ -> failwith "Pas possible" (* Autres *) let get_fun env p b = (* p : proto b : block -> name,Fun( ...)*) let name = p.p_name in let ty_args = List.map (* liste des arguments tr*ident *) (fun (vt,i) -> let tr = build_type_or_ref vt in (tr,i) ) p.p_args in (* vérif que les xi sont distincts, enlever '&' possible pour traiter les ref, en fait fait quand on appelle sur proto.p_args *) let n = List.length p.p_args in let ids = Array.of_list( List.map snd p.p_args ) in (* juste les ident*) for i = 0 to n-2 do for j = i+1 to n-1 do assert (String.compare ids.(i) ids.(j) = 0) (* compare 2 à 2 *) done; done; List.iter (fun ((ty,_),_) -> assert( bf ty ) ) ty_args; (* types st bf*) let contexte = List.fold_left (* tr = (ty,ref?) *) (fun envir (tr,i) -> Smap.add i (Var tr) envir) env ty_args in (* contexte ds l'instruction *) let tb = get_block contexte b in (* vérif instructions typées*) let tproto = { tp_loc = p.p_loc ; tp_name = name ; tp_class = None ; tp_ret_type = None ; tp_args = ty_args; } in name,tproto,tb let compute_decl env = function | DGlobal(t,i) -> let tr = build_type_or_ref t in (TDGlobal(tr,i)) , (Smap.add i (Var tr) env) (* on voudrait une liste de ident pr decl plsr en meme temps *) | DFunction (p,b) -> let name,tp,tb = get_fun env p b in (TDFunction (tp,tb) ) , (Smap.add name (Fun (tp,tb)) env) | DClass c -> er_not_implemented() (* TODO *) let prog p = let l = ( List.fold_left (fun list decl -> let (td,env) = List.hd list in (compute_decl env decl)::list ) [(TDNothing,Smap.empty)] p ) in List.map fst l