(***********************************************************************) (* *) (* Objective Caml *) (* *) (* Jerome Vouillon, projet Cristal, INRIA Rocquencourt *) (* *) (* Copyright 1996 Institut National de Recherche en Informatique et *) (* en Automatique. All rights reserved. This file is distributed *) (* under the terms of the Q Public License version 1.0. *) (* *) (***********************************************************************) (* $Id$ *) open Misc open Asttypes open Types open Typedtree open Lambda open Translobj open Translcore (* XXX Rajouter des evenements... *) type error = Illegal_class_expr exception Error of Location.t * error let lfunction params body = match body with Lfunction (Curried, params', body') -> Lfunction (Curried, params @ params', body') | _ -> Lfunction (Curried, params, body) let lapply func args = match func with Lapply(func', args') -> Lapply(func', args' @ args) | _ -> Lapply(func, args) let lsequence l1 l2 = if l2 = lambda_unit then l1 else Lsequence(l1, l2) let transl_label l = Lconst (Const_base (Const_string l)) let rec transl_meth_list lst = Lconst (List.fold_right (fun lab rem -> Const_block (0, [Const_base (Const_string lab); rem])) lst (Const_pointer 0)) let set_inst_var obj id expr = let kind = if Typeopt.maybe_pointer expr then Paddrarray else Pintarray in Lprim(Parraysetu kind, [Lvar obj; Lvar id; transl_exp expr]) let copy_inst_var obj id expr templ offset = let kind = if Typeopt.maybe_pointer expr then Paddrarray else Pintarray in let id' = Ident.create (Ident.name id) in Llet(Strict, id', Lprim (Pidentity, [Lvar id]), Lprim(Parraysetu kind, [Lvar obj; Lvar id'; Lprim(Parrayrefu kind, [Lvar templ; Lprim(Paddint, [Lvar id'; Lvar offset])])])) let transl_val tbl create name id rem = Llet(StrictOpt, id, Lapply (oo_prim (if create then "new_variable" else "get_variable"), [Lvar tbl; transl_label name]), rem) let transl_vals tbl create vals rem = List.fold_right (fun (name, id) rem -> transl_val tbl create name id rem) vals rem let transl_super tbl meths inh_methods rem = List.fold_right (fun (nm, id) rem -> begin try Llet(StrictOpt, id, Lapply (oo_prim "get_method", [Lvar tbl; Lvar (Meths.find nm meths)]), rem) with Not_found -> rem end) inh_methods rem let create_object cl obj init = let obj' = Ident.create "self" in let (inh_init, obj_init) = init obj' in if obj_init = lambda_unit then (inh_init, Lapply (oo_prim "create_object_and_run_initializers", [Lvar obj; Lvar cl])) else begin (inh_init, Llet(Strict, obj', Lapply (oo_prim "create_object_opt", [Lvar obj; Lvar cl]), Lsequence(obj_init, Lapply (oo_prim "run_initializers_opt", [Lvar obj; Lvar obj'; Lvar cl])))) end let rec build_object_init cl_table obj params inh_init cl = match cl.cl_desc with Tclass_ident path -> let obj_init = Ident.create "obj_init" in (obj_init::inh_init, Lapply(Lvar obj_init, [Lvar obj])) | Tclass_structure str -> create_object cl_table obj (fun obj -> let (inh_init, obj_init) = List.fold_right (fun field (inh_init, obj_init) -> match field with Cf_inher (cl, _, _) -> let (inh_init, obj_init') = build_object_init cl_table obj [] inh_init cl in (inh_init, lsequence obj_init' obj_init) | Cf_val (_, id, exp) -> (inh_init, lsequence (set_inst_var obj id exp) obj_init) | Cf_meth _ | Cf_init _ -> (inh_init, obj_init) | Cf_let (rec_flag, defs, vals) -> (inh_init, Translcore.transl_let rec_flag defs (List.fold_right (fun (id, expr) rem -> lsequence (Lifused(id, set_inst_var obj id expr)) rem) vals obj_init))) str.cl_field (inh_init, lambda_unit) in (inh_init, List.fold_right (fun (id, expr) rem -> lsequence (Lifused (id, set_inst_var obj id expr)) rem) params obj_init)) | Tclass_fun (pat, vals, cl, partial) -> let (inh_init, obj_init) = build_object_init cl_table obj (vals @ params) inh_init cl in (inh_init, let build params rem = let param = name_pattern "param" [pat, ()] in Lfunction (Curried, param::params, Matching.for_function pat.pat_loc None (Lvar param) [pat, rem] partial) in begin match obj_init with Lfunction (Curried, params, rem) -> build params rem | rem -> build [] rem end) | Tclass_apply (cl, oexprs) -> let (inh_init, obj_init) = build_object_init cl_table obj params inh_init cl in (inh_init, transl_apply obj_init oexprs) | Tclass_let (rec_flag, defs, vals, cl) -> let (inh_init, obj_init) = build_object_init cl_table obj (vals @ params) inh_init cl in (inh_init, Translcore.transl_let rec_flag defs obj_init) | Tclass_constraint (cl, vals, pub_meths, concr_meths) -> build_object_init cl_table obj params inh_init cl let rec build_object_init_0 cl_table params cl = match cl.cl_desc with Tclass_let (rec_flag, defs, vals, cl) -> let (inh_init, obj_init) = build_object_init_0 cl_table (vals @ params) cl in (inh_init, Translcore.transl_let rec_flag defs obj_init) | _ -> let obj = Ident.create "self" in let (inh_init, obj_init) = build_object_init cl_table obj params [] cl in let obj_init = lfunction [obj] obj_init in (inh_init, obj_init) let bind_method tbl public_methods lab id cl_init = if List.mem lab public_methods then Llet(Alias, id, Lvar (meth lab), cl_init) else Llet(StrictOpt, id, Lapply (oo_prim "get_method_label", [Lvar tbl; transl_label lab]), cl_init) let bind_methods tbl public_methods meths cl_init = Meths.fold (bind_method tbl public_methods) meths cl_init let rec build_class_init cla pub_meths cstr inh_init cl_init cl = match cl.cl_desc with Tclass_ident path -> begin match inh_init with obj_init::inh_init -> (inh_init, Llet (Strict, obj_init, Lapply(Lprim(Pfield 1, [transl_path path]), [Lvar cla]), cl_init)) | _ -> assert false end | Tclass_structure str -> let (inh_init, cl_init) = List.fold_right (fun field (inh_init, cl_init) -> match field with Cf_inher (cl, vals, meths) -> build_class_init cla pub_meths false inh_init (transl_vals cla false vals (transl_super cla str.cl_meths meths cl_init)) cl | Cf_val (name, id, exp) -> (inh_init, transl_val cla true name id cl_init) | Cf_meth (name, exp) -> let met_code = if !Clflags.native_code then begin (* Force correct naming of method for profiles *) let met = Ident.create ("method_" ^ name) in Llet(Strict, met, transl_exp exp, Lvar met) end else transl_exp exp in (inh_init, Lsequence(Lapply (oo_prim "set_method", [Lvar cla; Lvar (Meths.find name str.cl_meths); met_code]), cl_init)) | Cf_let (rec_flag, defs, vals) -> let vals = List.map (function (id, _) -> (Ident.name id, id)) vals in (inh_init, transl_vals cla true vals cl_init) | Cf_init exp -> (inh_init, Lsequence(Lapply (oo_prim "add_initializer", [Lvar cla; transl_exp exp]), cl_init))) str.cl_field (inh_init, cl_init) in (inh_init, bind_methods cla pub_meths str.cl_meths cl_init) | Tclass_fun (pat, vals, cl, _) -> let (inh_init, cl_init) = build_class_init cla pub_meths cstr inh_init cl_init cl in let vals = List.map (function (id, _) -> (Ident.name id, id)) vals in (inh_init, transl_vals cla true vals cl_init) | Tclass_apply (cl, exprs) -> build_class_init cla pub_meths cstr inh_init cl_init cl | Tclass_let (rec_flag, defs, vals, cl) -> let (inh_init, cl_init) = build_class_init cla pub_meths cstr inh_init cl_init cl in let vals = List.map (function (id, _) -> (Ident.name id, id)) vals in (inh_init, transl_vals cla true vals cl_init) | Tclass_constraint (cl, vals, meths, concr_meths) -> let core cl_init = build_class_init cla pub_meths true inh_init cl_init cl in if cstr then core cl_init else let virt_meths = List.fold_right (fun lab rem -> if Concr.mem lab concr_meths then rem else lab::rem) meths [] in let (inh_init, cl_init) = core (Lsequence (Lapply (oo_prim "widen", [Lvar cla]), cl_init)) in (inh_init, Lsequence(Lapply (oo_prim "narrow", [Lvar cla; transl_meth_list vals; transl_meth_list virt_meths; transl_meth_list (Concr.elements concr_meths)]), cl_init)) (* XXX Il devrait etre peu couteux d'ecrire des classes : class c x y = d e f *) (* XXX Exploiter le fait que les methodes sont definies dans l'ordre pour l'initialisation des classes (et les variables liees par un let ???) ? *) let transl_class ids cl_id arity pub_meths cl = let cla = Ident.create "class" in let (inh_init, obj_init) = build_object_init_0 cla [] cl in if not (Translcore.check_recursive_lambda ids obj_init) then raise(Error(cl.cl_loc, Illegal_class_expr)); let (inh_init, cl_init) = build_class_init cla pub_meths true (List.rev inh_init) obj_init cl in assert (inh_init = []); let table = Ident.create "table" in let class_init = Ident.create "class_init" in let obj_init = Ident.create "obj_init" in Llet(Strict, table, Lapply (oo_prim "create_table", [transl_meth_list pub_meths]), Llet(Strict, class_init, Lfunction(Curried, [cla], cl_init), Llet(Strict, obj_init, Lapply(Lvar class_init, [Lvar table]), Lsequence(Lapply (oo_prim "init_class", [Lvar table]), Lprim(Pmakeblock(0, Immutable), [Lvar obj_init; Lvar class_init; Lvar table]))))) let class_stub = Lprim(Pmakeblock(0, Mutable), [lambda_unit; lambda_unit; lambda_unit]) (* Error report *) open Format let report_error ppf = function | Illegal_class_expr -> fprintf ppf "This kind of class expression is not allowed"