ocaml/typing/typeclass.ml

1069 lines
35 KiB
OCaml

(***********************************************************************)
(* *)
(* Objective Caml *)
(* *)
(* Jerome Vouillon, projet Cristal, INRIA Rocquencourt *)
(* *)
(* Copyright 1996 Institut National de Recherche en Informatique et *)
(* Automatique. Distributed only by permission. *)
(* *)
(***********************************************************************)
(* $Id$ *)
open Misc
open Parsetree
open Asttypes
open Typedtree
open Typecore
open Typetexp
type error =
Duplicate_method of string
| Duplicate_variable of string
| Duplicate_super_variable of string
| Repeated_parameter
| Virtual_class of string * string
| Closed_class of string
| Closed_ancestor of string * Path.t * string
| Non_closed of Ident.t * type_expr list * type_expr
| Mutable_var of string
| Undefined_var of string
| Variable_type_mismatch of string * type_expr * type_expr
| Method_type_mismatch of string * type_expr * type_expr
| Unconsistent_constraint
| Unbound_class of Longident.t
| Argument_type_mismatch of type_expr * type_expr
| Abbrev_type_clash of type_expr * type_expr * type_expr
| Bad_parameters of Ident.t * type_expr * type_expr
| Illdefined_class of string
| Argument_arity_mismatch of Path.t * int * int
| Parameter_arity_mismatch of Path.t * int * int
| Parameter_mismatch of type_expr * type_expr
exception Error of Location.t * error
let check_mutable loc lab mut mut' =
match mut, mut' with
(Immutable, Mutable) ->
raise(Error(loc, Mutable_var lab.Label.lab_name))
| _ ->
()
let rec add_methods env self concr concr_lst t =
match (Ctype.repr t).desc with
Tfield (lab, _, t') ->
Ctype.filter_method env lab self;
if List.exists (Label. (=) lab) concr_lst then
(Ctype.filter_method env lab concr; ());
add_methods env self concr concr_lst t'
| _ ->
()
let make_stub env cl =
Ctype.begin_def ();
(* Create self (class type) *)
let self = Ctype.newobj (Ctype.newvar ()) in
let concr = Ctype.newobj (Ctype.newvar ()) in
(* Find concrete methods and marks methods *)
let concr_meths =
List.fold_left
(function meths ->
function
Pcf_inher (nm, _, _, _, loc) ->
let (_, anc) =
try
Env.lookup_class nm env
with Not_found ->
raise(Error(loc, Unbound_class nm))
in
begin match (Ctype.expand_root env anc.cty_self).desc with
Tobject (ty, _) ->
add_methods env self concr anc.cty_concr ty;
Sort.merge (<) meths anc.cty_concr
| _ -> fatal_error "Typeclass.make_stub"
end
| Pcf_val _ ->
meths
| Pcf_virt (lab, _, _) ->
Ctype.filter_method env lab self;
meths
| Pcf_meth (lab, _, _) ->
Ctype.filter_method env lab self;
Ctype.filter_method env lab concr;
Sort.merge (<) meths [lab])
[] cl.pcl_field
in
Ctype.close_object concr;
Ctype.end_def ();
Ctype.generalize self;
Ctype.generalize concr;
(* Temporary object type *)
let temp_obj_params = List.map (fun _ -> Ctype.newvar ()) cl.pcl_param in
let temp_obj = Ctype.instance self in
let obj_temp_abbrev =
{ type_params = temp_obj_params;
type_arity = List.length temp_obj_params;
type_kind = Type_abstract;
type_manifest = Some temp_obj }
in let (obj_id, temp_env) = Env.enter_type cl.pcl_name obj_temp_abbrev env
in let abbrev =
Ctype.newty (Tconstr (Path.Pident obj_id, temp_obj_params, ref []))
in
(* Temporary class type *)
let (temp_cl_params, temp_cl) =
if cl.pcl_closed = Closed then
(temp_obj_params,
Ctype.newty (Tconstr(Path.Pident obj_id, temp_obj_params, ref [])))
else begin
let params = List.map (fun _ -> Ctype.newvar ()) cl.pcl_param in
let ty = Ctype.instance self in
Ctype.set_object_name ty params obj_id;
(params, ty)
end
in
let cl_temp_abbrev =
{ type_params = temp_cl_params;
type_arity = List.length temp_cl_params;
type_kind = Type_abstract;
type_manifest = Some temp_cl }
in let (cl_id, temp_env) =
Env.enter_type ("#" ^ cl.pcl_name) cl_temp_abbrev temp_env
in let cl_abbrev =
Ctype.newty (Tconstr (Path.Pident cl_id, temp_cl_params, ref []))
in
(* Temporary type for new *)
let new_args = List.map (fun _ -> Ctype.newvar ()) cl.pcl_args in
let new_ty =
if cl.pcl_kind = Concrete then
Some (List.fold_right
(fun arg ty -> Ctype.newty (Tarrow(arg, ty)))
new_args abbrev)
else
None
in let cl_temp_sig =
{ cty_params = [];
cty_args = []; cty_vars = Vars.empty;
cty_self = self; cty_concr = concr_meths;
cty_new = new_ty }
in let (id, temp_env) = Env.enter_class cl.pcl_name cl_temp_sig temp_env in
((cl, id, cl_id, obj_id, self, concr, concr_meths, new_args, new_ty,
temp_cl, temp_cl_params, cl_abbrev, temp_obj, temp_obj_params, abbrev),
temp_env)
let rec type_meth env loc self ty =
match (Ctype.repr ty).desc with
Tfield (lab, ty, ty') ->
let ty0 = Ctype.filter_method env lab self in
begin try
Ctype.unify env ty0 ty
with Ctype.Unify ->
raise(Error(loc, Method_type_mismatch
(lab.Label.lab_name, ty, ty0)))
end;
type_meth env loc self ty'
| _ ->
()
let missing_method env ty ty' =
let rec missing_method_rec met=
match (Ctype.repr met).desc with
Tfield(lab, _, met') ->
begin try
Ctype.filter_method env lab ty;
missing_method_rec met'
with Ctype.Unify ->
lab
end
| _ ->
fatal_error "Typeclass.missing_method (1)"
in
match (Ctype.expand_root env ty').desc with
Tobject (met, _) ->
missing_method_rec met
| _ ->
fatal_error "Typeclass.missing_method (2)"
let rec closed_scheme t =
match (Ctype.repr t).desc with
Tfield (lab, _, t') ->
Ctype.newty (Tfield (lab, Ctype.newvar (), closed_scheme t'))
| Tnil ->
Ctype.newty Tnil
| _ ->
fatal_error "Typeclass.closed_scheme"
let vals_remove lab vals =
Vars.fold (fun l k v -> if Label. (=) lab l then v else Vars.add l k v)
vals Vars.empty
let insert_value env lab priv mut ty loc vals =
begin try
let (mut', ty') = Vars.find lab vals in
check_mutable loc lab mut mut';
try Ctype.unify env ty ty' with Ctype.Unify ->
raise(Error(loc, Variable_type_mismatch(lab.Label.lab_name, ty, ty')))
with Not_found -> () end;
if priv = Private then
vals_remove lab vals
else
Vars.add lab (mut, ty) vals
let change_value_status lab priv mut loc vals =
try
let (mut', ty') = Vars.find lab vals in
check_mutable loc lab mut mut';
if priv = Private then
(vals_remove lab vals, ty')
else
(Vars.add lab (mut, ty') vals, ty')
with Not_found ->
raise(Error(loc, Undefined_var lab.Label.lab_name))
let type_class_field env var_env self cl (met_env, fields, vars_sig) =
function
Pcf_inher (cl_name, params, args, super, loc) ->
(* Find class type *)
let (path, cl_type) =
try
Env.lookup_class cl_name env
with Not_found ->
raise(Error(loc, Unbound_class cl_name))
in
let (params', args', vars', self') = Ctype.instance_class cl_type in
(* Unify parameters *)
if List.length params <> List.length params' then
raise(Error(loc, Parameter_arity_mismatch
(path, List.length params', List.length params)));
List.iter2
(fun sty ty ->
let ty' = Typetexp.transl_simple_type var_env false sty in
try Ctype.unify var_env ty ty' with Ctype.Unify ->
raise(Error(sty.ptyp_loc, Parameter_mismatch(ty', ty))))
params params';
(* Type arguments *)
if List.length args <> List.length args' then
raise(Error(loc, Argument_arity_mismatch
(path, List.length args', List.length args)));
let args = List.map2 (type_expect var_env) args args' in
(* Variables *)
let (vars, vars_sig, met_env) =
Vars.fold
(fun lab (mut, ty) (l, v_sig, env) ->
let (id, env) =
Env.enter_value lab.Label.lab_name
{val_type = ty; val_kind = Val_ivar mut} env
in
((lab, id)::l,
insert_value var_env lab Public mut ty loc v_sig,
env))
vars' ([], vars_sig, met_env)
in
(* Self type *)
let ty' = Ctype.expand_root var_env self' in
begin match ty'.desc with
Tobject (fi, _) ->
if ty' != Ctype.expand_root var_env self then begin
if not (Ctype.opened_object self') then
begin try
Ctype.unify var_env self
(Ctype.newobj (closed_scheme fi))
with Ctype.Unify ->
let lab = missing_method var_env self' self in
raise(Error(loc, Closed_ancestor
(cl.pcl_name, path, lab.Label.lab_name)))
end;
ty'.desc <- Tlink self;
type_meth var_env loc self fi
end
| _ ->
fatal_error "Typeclass.transl_class"
end;
(* Super methods *)
let (met, met_env) =
match super with
None ->
([], met_env)
| Some name ->
let ty = Ctype.newobj (Ctype.newvar ()) in
let used_methods =
List.map
(fun lab ->
Ctype.unify met_env (Ctype.filter_method met_env lab ty)
(Ctype.filter_method met_env lab self);
(lab, Ident.create lab.Label.lab_name))
cl_type.cty_concr
in
Ctype.close_object ty;
let (id, met_env) =
Env.enter_value name
{val_type = ty; val_kind = Val_anc used_methods} met_env
in
(used_methods, met_env)
in
(met_env, Cf_inher (path, args, vars, met)::fields, vars_sig)
| Pcf_val (lab, priv, mut, sinit, loc) ->
begin match sinit with
Some sexp ->
let exp = type_exp var_env sexp in
let (id, met_env) =
Env.enter_value lab.Label.lab_name
{val_type = exp.exp_type; val_kind = Val_ivar mut} met_env
in
(met_env, Cf_val (lab, id, priv, Some exp)::fields,
insert_value var_env lab priv mut exp.exp_type loc vars_sig)
| None ->
let (vars_sig, ty) =
change_value_status lab priv mut loc vars_sig
in
let (id, met_env) =
Env.enter_value lab.Label.lab_name
{val_type = ty; val_kind = Val_ivar mut} met_env
in
(met_env, Cf_val (lab, id, priv, None)::fields, vars_sig)
end
| Pcf_virt (lab, ty, loc) ->
let ty = transl_simple_type met_env false ty in
let ty' = Ctype.filter_method met_env lab self in
begin try Ctype.unify met_env ty ty' with Ctype.Unify ->
raise(Error(loc, Method_type_mismatch (lab.Label.lab_name, ty, ty')))
end;
(met_env, fields, vars_sig)
| Pcf_meth (lab, expr, loc) ->
let (texp, ty) = type_method met_env self cl.pcl_self expr in
let ty' = Ctype.filter_method met_env lab self in
begin try Ctype.unify met_env ty ty' with Ctype.Unify ->
raise(Error(loc, Method_type_mismatch (lab.Label.lab_name, ty, ty')))
end;
(met_env, Cf_meth (lab, texp)::fields, vars_sig)
let transl_class temp_env env
(cl, id, cl_id, obj_id, self, concr, concr_meths, new_args, new_ty,
temp_cl, temp_cl_params, cl_abbrev, temp_obj, temp_obj_params, abbrev)
=
reset_type_variables ();
Ctype.begin_def ();
(* Self type *)
let self = Ctype.instance self in
(* Introduce parameters *)
let params =
try List.map enter_type_variable cl.pcl_param with Already_bound ->
raise(Error(cl.pcl_loc, Repeated_parameter)) in
(* Bind self type variable *)
begin try
match cl.pcl_self_ty with
Some v -> Ctype.unify temp_env self (enter_type_variable v)
| None -> ()
with Already_bound ->
raise(Error(cl.pcl_loc, Repeated_parameter))
end;
(* Add constraints *)
List.iter
(function (v, ty, loc) ->
try
Ctype.unify temp_env
(type_variable loc v) (transl_simple_type temp_env false ty)
with Ctype.Unify ->
raise(Error(loc, Unconsistent_constraint)))
cl.pcl_cstr;
(* Type arguments and fields *)
let (args, var_env) = type_pattern_list temp_env cl.pcl_args in
let arg_sig = List.map (fun exp -> exp.pat_type) args in
let (_, fields, vars_sig) =
List.fold_left (type_class_field env var_env self cl)
(temp_env, [], Vars.empty)
cl.pcl_field
in
(* Closeness of self (1) *)
if cl.pcl_closed = Closed then
Ctype.close_object self;
(* Generalize class *)
Ctype.end_def ();
List.iter Ctype.generalize params;
List.iter Ctype.generalize arg_sig;
Vars.iter (fun l (m, t) -> Ctype.generalize t) vars_sig;
Ctype.generalize self;
(* Temporary class abbreviation *)
let (cl_params, cl_ty) = Ctype.instance_parameterized_type params self in
begin try Ctype.unify temp_env temp_cl cl_ty with Ctype.Unify ->
Ctype.remove_object_name temp_cl;
raise(Error(cl.pcl_loc, Abbrev_type_clash (cl_abbrev, cl_ty, temp_cl)))
end;
begin try
List.iter2 (Ctype.unify temp_env) temp_cl_params cl_params
with Ctype.Unify ->
raise(Error(cl.pcl_loc,
Bad_parameters (cl_id, cl_abbrev,
Ctype.newty (Tconstr (Path.Pident cl_id, cl_params,
ref [])))))
end;
(* Object abbreviation and arguments for new *)
let (obj_params, arg_sig', obj_ty) =
Ctype.instance_parameterized_type_2 params arg_sig self
in
begin try Ctype.unify temp_env abbrev obj_ty with Ctype.Unify ->
raise(Error(cl.pcl_loc, Abbrev_type_clash (abbrev, obj_ty, temp_obj)))
end;
begin try
List.iter2 (Ctype.unify temp_env) temp_obj_params obj_params
with Ctype.Unify ->
raise(Error(cl.pcl_loc,
Bad_parameters (obj_id, abbrev,
Ctype.newty (Tconstr (Path.Pident obj_id, obj_params,
ref [])))))
end;
Ctype.close_object temp_obj;
List.iter2
(fun ty (exp, ty') ->
begin try
Ctype.unify temp_env ty ty'
with Ctype.Unify ->
raise(Error(exp.pat_loc, Argument_type_mismatch(ty', ty)))
end)
new_args (List.combine args arg_sig');
(* Fill interface / implementation *)
let cl_imp =
{ cl_args = args;
cl_field = List.rev fields;
cl_loc = cl.pcl_loc }
in let cl_sig =
{ cty_params = params;
cty_args = arg_sig;
cty_vars = vars_sig;
cty_self = self;
cty_concr = concr_meths;
cty_new = new_ty }
in let new_env = Env.add_class id cl_sig env in
((cl, id, cl_id, obj_id, cl_sig, cl_imp,
concr, abbrev, new_args, temp_obj, temp_obj_params),
new_env)
let build_new_type temp_env env
(cl, id, cl_id, obj_id, cl_sig, cl_imp,
concr, abbrev, new_args, temp_obj, temp_obj_params)
=
(* Modify constrainsts to ensure the object abbreviation is well-formed *)
let (params, args, vars, self) = Ctype.instance_class cl_sig in
List.iter2 (Ctype.unify temp_env) params temp_obj_params;
(* Never fails *)
(* Closeness of self (2) *)
if (cl.pcl_closed <> Closed) & not (Ctype.opened_object self) then
raise(Error(cl.pcl_loc, Closed_class cl.pcl_name));
(* Check whether the class can be concrete *)
if cl.pcl_kind = Concrete then begin
let concr = Ctype.instance concr in
try
Ctype.unify temp_env concr temp_obj
with Ctype.Unify ->
let lab = missing_method temp_env concr temp_obj in
raise(Error(cl.pcl_loc,
Virtual_class (cl.pcl_name, lab.Label.lab_name)))
end;
(* self should not be an abbreviation (printtyp) *)
let exp_self = Ctype.expand_root temp_env self in
(* Final class type *)
let cl_sig =
{ cty_params = params;
cty_args = args;
cty_vars = vars;
cty_self = exp_self;
cty_concr = cl_sig.cty_concr;
cty_new = cl_sig.cty_new } (* new is still monomorphic *)
in let new_env = Env.add_class id cl_sig env in
((cl, id, cl_id, obj_id, cl_sig, cl_imp), new_env)
let generalize_class (_, _, _, _, cl_sig, _) =
List.iter Ctype.generalize cl_sig.cty_params;
List.iter Ctype.generalize cl_sig.cty_args;
Vars.iter (fun l (m, t) -> Ctype.generalize t) cl_sig.cty_vars;
Ctype.generalize cl_sig.cty_self;
match cl_sig.cty_new with Some ty -> Ctype.generalize ty | None -> ()
let make_abbrev env
(cl, id, cl_id, obj_id, cl_sig, cl_imp)
=
(* Class type abbreviation *)
Ctype.begin_def ();
let (params, self) =
Ctype.instance_parameterized_type cl_sig.cty_params cl_sig.cty_self
in let (cl_ty, cstr) = Ctype.prune self params
in let cl_ty_params = List.map fst cstr in
Ctype.end_def ();
Ctype.generalize cl_ty;
List.iter Ctype.generalize cl_ty_params;
let cl_abbrev =
{ type_params = cl_ty_params;
type_arity = List.length cl_ty_params;
type_kind = Type_abstract;
type_manifest = Some
(if cl.pcl_closed = Closed then
Ctype.newgenty (Tconstr(Path.Pident obj_id, cl_ty_params, ref []))
else begin
Ctype.set_object_name cl_ty cl_ty_params obj_id;
cl_ty
end) }
in let new_env = Env.add_type cl_id cl_abbrev env in
(* Object type abbreviation *)
Ctype.begin_def ();
let (obj_ty_params, obj_ty) =
Ctype.instance_parameterized_type cl_ty_params cl_ty
in
Ctype.close_object obj_ty;
Ctype.end_def ();
List.iter Ctype.generalize obj_ty_params;
if not (Ctype.closed_schema obj_ty) then
raise(Error(cl.pcl_loc,
Non_closed(obj_id, obj_ty_params, obj_ty)));
Ctype.generalize obj_ty;
let obj_abbrev =
{ type_params = obj_ty_params;
type_arity = List.length obj_ty_params;
type_kind = Type_abstract;
type_manifest = Some (Ctype.unroll_abbrev obj_id obj_ty_params obj_ty) }
in let new_env = Env.add_type obj_id obj_abbrev new_env in
((id, cl_sig, cl_id, cl_abbrev, obj_id, obj_abbrev, cl_imp), new_env)
let rec iter f env =
function
[] ->
([], env)
| cl :: cl_rem ->
let (cl', env') = f env cl in
let (cl_rem', env'') = iter f env' cl_rem in
(cl'::cl_rem', env'')
let transl_classes env cl =
Ctype.begin_def ();
let (info, temp_env) = iter make_stub env cl in
let (info, _) = iter (transl_class temp_env) env info in
let (info, new_env) = iter (build_new_type temp_env) env info in
Ctype.end_def ();
List.iter generalize_class info;
let (info, new_env) = iter make_abbrev new_env info in
(info, new_env)
(*----------------------------------------------------------------------*)
(* Represent object types as abstract types *)
let enter_class env cl =
let abstr_type =
{ type_params = [];
type_arity = List.length cl.pcty_param;
type_kind = Type_abstract;
type_manifest = None }
in
let (obj_id, ext_env) = Env.enter_type cl.pcty_name abstr_type env in
((cl, obj_id), ext_env)
let insert_value env lab priv mut ty loc val_sig val_redef =
let val_sig' =
if priv = Private then
vals_remove lab val_sig
else
Vars.add lab (mut, ty) val_sig
in
try
let (mut', ty') = Vars.find lab val_sig in
check_mutable loc lab mut mut';
(val_sig', (lab, ty', ty, loc)::val_redef)
with Not_found ->
(val_sig', val_redef)
let change_value_status lab priv mut loc val_sig =
try
let (mut', ty') = Vars.find lab val_sig in
check_mutable loc lab mut mut';
if priv = Private then
vals_remove lab val_sig
else
Vars.add lab (mut, ty') val_sig
with Not_found ->
raise(Error(loc, Undefined_var lab.Label.lab_name))
let insert_meth env self lab ty loc meth_redef =
let ty0 = Ctype.filter_method env lab self in
if not
(List.exists (function (lab', _, _, _) -> Label. (=) lab lab') meth_redef)
then
Ctype.unify env ty ty0;
(lab, ty0, ty, loc)::meth_redef
let rec type_meth env loc self methods ty =
match (Ctype.repr ty).desc with
Tfield (lab, ty, ty') ->
insert_meth env self lab ty loc (type_meth env loc self methods ty')
| _ ->
methods
let type_class_type_field env temp_env cl self
(val_sig, val_redef, meth_redef) =
function
Pctf_inher (name, params, loc) ->
let (path, cl_sig) =
try Env.lookup_class name env with Not_found ->
raise (Error (loc, Unbound_class name))
in
let (cstr, args, vals, super) = Ctype.prune_class_type cl_sig in
List.iter2
(fun t1 (t2, _) ->
Ctype.unify temp_env
(Typetexp.transl_simple_type temp_env false t1) t2)
params cstr;
let super = Ctype.expand_root temp_env super in
let (val_sig, val_redef) =
Vars.fold
(fun lab (mut, ty) (v_sig, v_redef) ->
insert_value temp_env lab Public mut ty loc v_sig v_redef)
vals
(val_sig, val_redef)
in
let meth_redef =
match super.desc with
Tobject (fi, _) ->
if not (Ctype.opened_object super) then
begin try
Ctype.unify temp_env self (Ctype.newobj (closed_scheme fi))
with Ctype.Unify ->
let lab = missing_method temp_env super self in
raise(Error(loc,
Closed_ancestor (cl.pcty_name, path,
lab.Label.lab_name)))
end;
super.desc <- Tlink self;
type_meth temp_env loc self meth_redef fi
| _ ->
fatal_error "Typeclass.type_class_type_field"
in
(val_sig, val_redef, meth_redef)
| Pctf_val (lab, priv, mut, sty, loc) ->
begin match sty with
Some sty ->
let ty = transl_simple_type temp_env false sty in
let (val_sig, val_redef) =
insert_value temp_env lab priv mut ty loc val_sig val_redef
in
(val_sig, val_redef, meth_redef)
| None ->
(change_value_status lab priv mut loc val_sig, val_redef, meth_redef)
end
| Pctf_virt (lab, sty, loc) ->
let ty = transl_simple_type temp_env false sty in
(val_sig, val_redef, insert_meth temp_env self lab ty loc meth_redef)
| Pctf_meth (lab, sty, loc) ->
let ty = transl_simple_type temp_env false sty in
(val_sig, val_redef, insert_meth temp_env self lab ty loc meth_redef)
(* Build class and object types *)
let build_abbrevs temp_env env (cl, obj_id) =
reset_type_variables ();
Ctype.begin_def ();
(* Create self (class type) *)
let self = Ctype.newobj (Ctype.newvar ()) in
let concr = Ctype.newobj (Ctype.newvar ()) in
(* Find concrete methods and marks methods *)
let concr_meths =
List.fold_left
(function meths ->
function
Pctf_inher (nm, _, loc) ->
let (_, anc) =
try
Env.lookup_class nm env
with Not_found ->
raise(Error(loc, Unbound_class nm))
in
begin match (Ctype.expand_root env anc.cty_self).desc with
Tobject (ty, _) ->
add_methods env self concr anc.cty_concr ty;
Sort.merge (<) meths anc.cty_concr
| _ -> fatal_error "Typeclass.make_stub"
end
| Pctf_val _ ->
meths
| Pctf_virt (lab, _, _) ->
Ctype.filter_method env lab self;
meths
| Pctf_meth (lab, _, _) ->
Ctype.filter_method env lab self;
Ctype.filter_method env lab concr;
Sort.merge (<) meths [lab])
[] cl.pcty_field
in
Ctype.close_object concr;
(* Introduce parameters *)
let params =
try List.map enter_type_variable cl.pcty_param with Already_bound ->
raise(Error(cl.pcty_loc, Repeated_parameter))
in
(* Bind self type variable *)
begin try
match cl.pcty_self with
Some v -> Ctype.unify temp_env self (enter_type_variable v)
| None -> ()
with Already_bound ->
raise(Error(cl.pcty_loc, Repeated_parameter))
end;
(* Translate argument types *)
let args = List.map (transl_simple_type temp_env false) cl.pcty_args in
(* Translate fields *)
let (val_sig, val_redef, meth_redef) =
List.fold_left (type_class_type_field env temp_env cl self)
(Vars.empty, [], [])
cl.pcty_field
in
(* Closeness of self *)
if cl.pcty_closed = Closed then
Ctype.close_object self;
if (cl.pcty_closed <> Closed) & not (Ctype.opened_object self) then
raise(Error(cl.pcty_loc, Closed_class cl.pcty_name));
(* Generalize class *)
Ctype.end_def ();
List.iter Ctype.generalize params;
List.iter Ctype.generalize args;
Vars.iter (fun _ (_, ty) -> Ctype.generalize ty) val_sig;
Ctype.generalize self;
Ctype.generalize concr;
List.iter
(function (_, ty, ty', _) -> Ctype.generalize ty; Ctype.generalize ty')
val_redef;
List.iter
(function (_, ty, ty', _) -> Ctype.generalize ty; Ctype.generalize ty')
meth_redef;
(* Object type abbreviation *)
Ctype.begin_def ();
let (obj_params, obj_ty) = Ctype.instance_parameterized_type params self in
Ctype.close_object obj_ty;
Ctype.end_def ();
List.iter Ctype.generalize obj_params;
if not (Ctype.closed_schema obj_ty) then
raise(Error(cl.pcty_loc,
Non_closed(obj_id, obj_params, obj_ty)));
Ctype.generalize obj_ty;
let obj_abbrev =
{ type_params = obj_params;
type_arity = List.length obj_params;
type_kind = Type_abstract;
type_manifest = Some obj_ty }
in let ext_env = Env.add_type obj_id obj_abbrev env in
(* Class type abbreviation *)
let cl_abbrev =
{ type_params = List.map Ctype.repr params;
type_arity = List.length params;
type_kind = Type_abstract;
type_manifest = Some
(if cl.pcty_closed = Closed then
Ctype.newgenty (Tconstr(Path.Pident obj_id, params, ref []))
else begin
Ctype.set_object_name self params obj_id;
self
end) }
in
let (cl_id, ext_env) =
Env.enter_type ("#" ^ cl.pcty_name) cl_abbrev ext_env
in
(* Set class type name *)
(* Temporary class signature *)
let temp_cl_sig =
{ cty_params = params;
cty_args = args;
cty_vars = val_sig;
cty_self = self;
cty_concr = concr_meths;
cty_new = None }
in
((cl, cl_id, cl_abbrev, obj_id, obj_abbrev, obj_params, obj_ty, temp_cl_sig,
val_redef, meth_redef, concr),
ext_env)
let check_abbrev env
(cl, cl_id, cl_abbrev, obj_id, obj_abbrev, obj_params, obj_ty, temp_cl_sig,
val_redef, meth_redef, concr) =
begin try Ctype.correct_abbrev env obj_id obj_params obj_ty with
Ctype.Nonlinear_abbrev ->
raise(Error(cl.pcty_loc, Illdefined_class cl.pcty_name))
end;
env
let check_field_redef env error (lab, ty, ty', loc) =
if not (Ctype.equal env [] ty [] ty') then
raise(Error(loc, error lab.Label.lab_name ty ty'))
let build_class_type env
(cl, cl_id, cl_abbrev, obj_id, obj_abbrev, obj_params, obj_ty, temp_cl_sig,
val_redef, meth_redef, concr) =
(* Check variable and method redefining *)
List.iter
(check_field_redef env (fun l t t' -> Variable_type_mismatch(l, t', t)))
val_redef;
List.iter
(check_field_redef env (fun l t t' -> Method_type_mismatch(l, t', t)))
meth_redef;
(* Class type skeleton *)
reset_type_variables ();
Ctype.begin_def ();
let (params, args, vals, self) = Ctype.instance_class temp_cl_sig in
(* Re-introduce parameters and bind self type variable *)
List.iter2
(fun v ty -> Ctype.unify env (enter_type_variable v) ty)
cl.pcty_param params;
begin match cl.pcty_self with
Some v -> Ctype.unify env (enter_type_variable v) self
| None -> ()
end;
(* Add constraints *)
List.iter
(function (v, ty, loc) ->
try
Ctype.unify env
(type_variable loc v) (transl_simple_type env false ty)
with Ctype.Unify ->
raise(Error(loc, Unconsistent_constraint)))
cl.pcty_cstr;
Ctype.end_def ();
List.iter Ctype.generalize params;
List.iter Ctype.generalize args;
Vars.iter (fun l (m, t) -> Ctype.generalize t) vals;
Ctype.generalize self;
(* Class type *)
let cl_sig =
{ cty_params = params;
cty_args = args;
cty_vars = vals;
cty_self = self;
cty_concr = temp_cl_sig.cty_concr;
cty_new = None }
in let (id, new_env) = Env.enter_class cl.pcty_name cl_sig env in
(* Build type of [new cl] *)
cl_sig.cty_new <-
if cl.pcty_kind = Concrete then begin
let concr = Ctype.instance concr in
let temp_obj = Ctype.instance obj_ty in
begin try
Ctype.unify env concr temp_obj
with Ctype.Unify ->
let lab = missing_method env concr temp_obj in
raise(Error(cl.pcty_loc,
Virtual_class (cl.pcty_name, lab.Label.lab_name)))
end;
Ctype.begin_def ();
let (params, args, _, self) = Ctype.instance_class cl_sig in
let abbrev =
Ctype.newty (Tconstr (Path.Pident obj_id, params, ref []))
in
Ctype.unify env self abbrev;
let ty_new =
List.fold_right (fun arg ty -> Ctype.newty (Tarrow(arg, ty)))
args abbrev
in
Ctype.end_def ();
Ctype.generalize ty_new;
Some ty_new
end else
None;
((id, cl_sig, cl_id, cl_abbrev, obj_id, obj_abbrev), new_env)
let rec transl_class_types env class_type_list =
(* Type classes are first abstract *)
let (info, temp_env) = iter enter_class env class_type_list in
let (info, new_env) = iter (build_abbrevs temp_env) env info in
List.iter (check_abbrev new_env) info;
let (info, final_env) = iter build_class_type new_env info in
(info, final_env)
(* Error report *)
open Format
let report_error = function
Duplicate_method s ->
print_string "Two methods are named"; print_space ();
print_string s
| Duplicate_variable s ->
print_string "Two instance variables are named"; print_space ();
print_string s
| Duplicate_super_variable s ->
print_string "Two ancestors are named"; print_space ();
print_string s
| Repeated_parameter ->
print_string "A type parameter occurs several times"
| Virtual_class (cl, met) ->
print_string "The class"; print_space ();
print_string cl; print_space ();
print_string "should be virtual: its methods"; print_space ();
print_string met; print_space ();
print_string "is undefined"
| Closed_class cl ->
print_string "The class"; print_space ();
print_string cl; print_space ();
print_string "is closed, but not marked closed"
| Closed_ancestor (cl, anc, met) ->
print_string "The class"; print_space ();
print_string cl; print_space ();
print_string "inherits from the closed class"; print_space ();
Printtyp.path anc; print_space ();
print_string "which has no method"; print_space ();
print_string met
| Non_closed (id, args, typ) ->
open_hovbox 0;
Printtyp.reset ();
Printtyp.mark_loops typ;
print_string "Some variables are not bound in"; print_space ();
Printtyp.type_expr (Ctype.newty (Tconstr(Path.Pident id, args, ref [])));
print_space (); print_string "="; print_space ();
Printtyp.type_expr typ;
close_box ()
| Mutable_var v ->
print_string "The variable"; print_space ();
print_string v; print_space ();
print_string "was mutable and is redefined as immutable"
| Undefined_var v ->
print_string "The variable"; print_space ();
print_string v; print_space ();
print_string "is undefined"
| Variable_type_mismatch (v, actual, expected) ->
open_hovbox 0;
Printtyp.reset ();
Printtyp.mark_loops actual; Printtyp.mark_loops expected;
print_string "The variable ";
print_string v; print_space ();
print_string "has type"; print_space ();
Printtyp.type_expr actual;
print_space ();
print_string "but is expected to have type"; print_space ();
Printtyp.type_expr expected;
close_box ()
| Method_type_mismatch (m, actual, expected) ->
open_hovbox 0;
Printtyp.reset ();
Printtyp.mark_loops actual; Printtyp.mark_loops expected;
print_string "The method ";
print_string m; print_space ();
print_string "has type"; print_space ();
Printtyp.type_expr actual;
print_space ();
print_string "but is expected to have type"; print_space ();
Printtyp.type_expr expected;
close_box ()
| Unconsistent_constraint ->
print_string "The class constraints are not consistent"
| Unbound_class cl ->
print_string "Unbound class"; print_space ();
Printtyp.longident cl
| Argument_type_mismatch (actual, expected) ->
open_hovbox 0;
Printtyp.reset ();
Printtyp.mark_loops actual; Printtyp.mark_loops expected;
print_string "This argument has type"; print_space ();
Printtyp.type_expr actual;
print_space ();
print_string "but is expected to have type"; print_space ();
Printtyp.type_expr expected;
close_box ()
| Abbrev_type_clash (abbrev, actual, expected) ->
open_hovbox 0;
Printtyp.reset ();
Printtyp.mark_loops abbrev; Printtyp.mark_loops actual;
Printtyp.mark_loops expected;
print_string "The abbreviation"; print_space ();
Printtyp.type_expr abbrev; print_space ();
print_string "expands to type"; print_space ();
Printtyp.type_expr actual; print_space ();
print_string "but is used with type"; print_space ();
Printtyp.type_expr expected;
close_box ()
| Bad_parameters (id, params, cstrs) ->
open_hovbox 0;
Printtyp.reset ();
Printtyp.mark_loops params; Printtyp.mark_loops cstrs;
print_string "The abbreviation"; print_space ();
Printtyp.ident id; print_space ();
print_string "is used with parameters"; print_space ();
Printtyp.type_expr params; print_space ();
print_string "wich are incompatible with constraints"; print_space ();
Printtyp.type_expr cstrs; print_space ();
close_box ()
| Illdefined_class s ->
print_string "The class "; print_string s;
print_string " is ill-defined"
| Parameter_mismatch(actual, expected) ->
Printtyp.reset ();
Printtyp.mark_loops actual; Printtyp.mark_loops expected;
open_hovbox 0;
print_string "The type parameter"; print_space ();
Printtyp.type_expr actual; print_space ();
print_string "does not meet its constraint: it should be";
print_space ();
Printtyp.type_expr expected
| Argument_arity_mismatch(p, expected, provided) ->
open_hovbox 0;
print_string "The class "; Printtyp.path p;
print_space(); print_string "expects "; print_int expected;
print_string " argument(s),"; print_space();
print_string "but is here applied to "; print_int provided;
print_string " argument(s)";
close_box()
| Parameter_arity_mismatch(p, expected, provided) ->
open_hovbox 0;
print_string "The class "; Printtyp.path p;
print_space(); print_string "expects "; print_int expected;
print_string " parameter(s),"; print_space();
print_string "but is here applied to "; print_int provided;
print_string " parameter(s)";
close_box()