(***********************************************************************) (* *) (* OCaml *) (* *) (* Xavier Leroy, 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. *) (* *) (***********************************************************************) open Misc open Longident open Path open Asttypes open Parsetree open Types open Format type error = Cannot_apply of module_type | Not_included of Includemod.error list | Cannot_eliminate_dependency of module_type | Signature_expected | Structure_expected of module_type | With_no_component of Longident.t | With_mismatch of Longident.t * Includemod.error list | Repeated_name of string * string | Non_generalizable of type_expr | Non_generalizable_class of Ident.t * class_declaration | Non_generalizable_module of module_type | Implementation_is_required of string | Interface_not_compiled of string | Not_allowed_in_functor_body | With_need_typeconstr | Not_a_packed_module of type_expr | Incomplete_packed_module of type_expr | Scoping_pack of Longident.t * type_expr | Extension of string | Recursive_module_require_explicit_type | Apply_generative exception Error of Location.t * Env.t * error open Typedtree let fst3 (x,_,_) = x let rec path_concat head p = match p with Pident tail -> Pdot (Pident head, Ident.name tail, 0) | Pdot (pre, s, pos) -> Pdot (path_concat head pre, s, pos) | Papply _ -> assert false (* Extract a signature from a module type *) let extract_sig env loc mty = match Env.scrape_alias env mty with Mty_signature sg -> sg | _ -> raise(Error(loc, env, Signature_expected)) let extract_sig_open env loc mty = match Env.scrape_alias env mty with Mty_signature sg -> sg | _ -> raise(Error(loc, env, Structure_expected mty)) (* Compute the environment after opening a module *) let type_open_ ?toplevel ovf env loc lid = let path = Typetexp.find_module env lid.loc lid.txt in let md = Env.find_module path env in let sg = extract_sig_open env lid.loc md.md_type in path, Env.open_signature ~loc ?toplevel ovf path sg env let type_open ?toplevel env sod = let (path, newenv) = type_open_ ?toplevel sod.popen_override env sod.popen_loc sod.popen_lid in let od = { open_override = sod.popen_override; open_path = path; open_txt = sod.popen_lid; open_attributes = sod.popen_attributes; open_loc = sod.popen_loc; } in (path, newenv, od) (* Record a module type *) let rm node = Stypes.record (Stypes.Ti_mod node); node (* Forward declaration, to be filled in by type_module_type_of *) let type_module_type_of_fwd : (Env.t -> Parsetree.module_expr -> Typedtree.module_expr * Types.module_type) ref = ref (fun env m -> assert false) (* Merge one "with" constraint in a signature *) let rec add_rec_types env = function Sig_type(id, decl, Trec_next) :: rem -> add_rec_types (Env.add_type ~check:true id decl env) rem | _ -> env let check_type_decl env loc id row_id newdecl decl rs rem = let env = Env.add_type ~check:true id newdecl env in let env = match row_id with | None -> env | Some id -> Env.add_type ~check:true id newdecl env in let env = if rs = Trec_not then env else add_rec_types env rem in Includemod.type_declarations env id newdecl decl; Typedecl.check_coherence env loc id newdecl let rec make_params n = function [] -> [] | _ :: l -> ("a" ^ string_of_int n) :: make_params (n+1) l let make_next_first rs rem = if rs = Trec_first then match rem with Sig_type (id, decl, Trec_next) :: rem -> Sig_type (id, decl, Trec_first) :: rem | Sig_module (id, mty, Trec_next) :: rem -> Sig_module (id, mty, Trec_first) :: rem | _ -> rem else rem let sig_item desc typ env loc = { Typedtree.sig_desc = desc; sig_loc = loc; sig_env = env } let make p n i = let open Variance in set May_pos p (set May_neg n (set May_weak n (set Inj i null))) let merge_constraint initial_env loc sg constr = let lid = match constr with | Pwith_type (lid, _) | Pwith_module (lid, _) -> lid | Pwith_typesubst {ptype_name=s} | Pwith_modsubst (s, _) -> {loc = s.loc; txt=Lident s.txt} in let real_id = ref None in let rec merge env sg namelist row_id = match (sg, namelist, constr) with ([], _, _) -> raise(Error(loc, env, With_no_component lid.txt)) | (Sig_type(id, decl, rs) :: rem, [s], Pwith_type (_, ({ptype_kind = Ptype_abstract} as sdecl))) when Ident.name id = s && Typedecl.is_fixed_type sdecl -> let decl_row = { type_params = List.map (fun _ -> Btype.newgenvar()) sdecl.ptype_params; type_arity = List.length sdecl.ptype_params; type_kind = Type_abstract; type_private = Private; type_manifest = None; type_variance = List.map (fun (_, v) -> let (c, n) = match v with | Covariant -> true, false | Contravariant -> false, true | Invariant -> false, false in make (not n) (not c) false ) sdecl.ptype_params; type_loc = sdecl.ptype_loc; type_newtype_level = None; type_attributes = []; } and id_row = Ident.create (s^"#row") in let initial_env = Env.add_type ~check:true id_row decl_row initial_env in let tdecl = Typedecl.transl_with_constraint initial_env id (Some(Pident id_row)) decl sdecl in let newdecl = tdecl.typ_type in check_type_decl env sdecl.ptype_loc id row_id newdecl decl rs rem; let decl_row = {decl_row with type_params = newdecl.type_params} in let rs' = if rs = Trec_first then Trec_not else rs in (Pident id, lid, Twith_type tdecl), Sig_type(id_row, decl_row, rs') :: Sig_type(id, newdecl, rs) :: rem | (Sig_type(id, decl, rs) :: rem , [s], Pwith_type (_, sdecl)) when Ident.name id = s -> let tdecl = Typedecl.transl_with_constraint initial_env id None decl sdecl in let newdecl = tdecl.typ_type in check_type_decl env sdecl.ptype_loc id row_id newdecl decl rs rem; (Pident id, lid, Twith_type tdecl), Sig_type(id, newdecl, rs) :: rem | (Sig_type(id, decl, rs) :: rem, [s], (Pwith_type _ | Pwith_typesubst _)) when Ident.name id = s ^ "#row" -> merge env rem namelist (Some id) | (Sig_type(id, decl, rs) :: rem, [s], Pwith_typesubst sdecl) when Ident.name id = s -> (* Check as for a normal with constraint, but discard definition *) let tdecl = Typedecl.transl_with_constraint initial_env id None decl sdecl in let newdecl = tdecl.typ_type in check_type_decl env sdecl.ptype_loc id row_id newdecl decl rs rem; real_id := Some id; (Pident id, lid, Twith_typesubst tdecl), make_next_first rs rem | (Sig_module(id, md, rs) :: rem, [s], Pwith_module (_, lid)) when Ident.name id = s -> let path = Typetexp.find_module initial_env loc lid.txt in let md' = Env.find_module path env in let md'' = {md' with md_type = Mtype.remove_aliases env md'.md_type} in let newmd = Mtype.strengthen_decl env md'' path in ignore(Includemod.modtypes env newmd.md_type md.md_type); (Pident id, lid, Twith_module (path, lid)), Sig_module(id, newmd, rs) :: rem | (Sig_module(id, md, rs) :: rem, [s], Pwith_modsubst (_, lid)) when Ident.name id = s -> let path = Typetexp.find_module initial_env loc lid.txt in let md' = Env.find_module path env in let newmd = Mtype.strengthen_decl env md' path in ignore(Includemod.modtypes env newmd.md_type md.md_type); real_id := Some id; (Pident id, lid, Twith_modsubst (path, lid)), make_next_first rs rem | (Sig_module(id, md, rs) :: rem, s :: namelist, _) when Ident.name id = s -> let ((path, path_loc, tcstr), newsg) = merge env (extract_sig env loc md.md_type) namelist None in (path_concat id path, lid, tcstr), Sig_module(id, {md with md_type=Mty_signature newsg}, rs) :: rem | (item :: rem, _, _) -> let (cstr, items) = merge (Env.add_item item env) rem namelist row_id in cstr, item :: items in try let names = Longident.flatten lid.txt in let (tcstr, sg) = merge initial_env sg names None in let sg = match names, constr with [s], Pwith_typesubst sdecl -> let id = match !real_id with None -> assert false | Some id -> id in let lid = try match sdecl.ptype_manifest with | Some {ptyp_desc = Ptyp_constr (lid, stl)} when List.length stl = List.length sdecl.ptype_params -> List.iter2 (fun x (y, _) -> match x, y with {ptyp_desc=Ptyp_var sx}, {ptyp_desc=Ptyp_var sy} when sx = sy -> () | _, _ -> raise Exit) stl sdecl.ptype_params; lid | _ -> raise Exit with Exit -> raise(Error(sdecl.ptype_loc, initial_env, With_need_typeconstr)) in let (path, _) = try Env.lookup_type lid.txt initial_env with Not_found -> assert false in let sub = Subst.add_type id path Subst.identity in Subst.signature sub sg | [s], Pwith_modsubst (_, lid) -> let id = match !real_id with None -> assert false | Some id -> id in let path = Typetexp.find_module initial_env loc lid.txt in let sub = Subst.add_module id path Subst.identity in Subst.signature sub sg | _ -> sg in (tcstr, sg) with Includemod.Error explanation -> raise(Error(loc, initial_env, With_mismatch(lid.txt, explanation))) (* Add recursion flags on declarations arising from a mutually recursive block. *) let map_rec fn decls rem = match decls with | [] -> rem | d1 :: dl -> fn Trec_first d1 :: map_end (fn Trec_next) dl rem let map_rec' = map_rec (* let rec map_rec' fn decls rem = match decls with | (id,_ as d1) :: dl when Btype.is_row_name (Ident.name id) -> fn Trec_not d1 :: map_rec' fn dl rem | _ -> map_rec fn decls rem *) let rec map_rec'' fn decls rem = match decls with | d1 :: dl when Btype.is_row_name (Ident.name d1.typ_id) -> fn Trec_not d1 :: map_rec'' fn dl rem | _ -> map_rec fn decls rem (* Add type extension flags to extension contructors *) let map_ext fn exts rem = match exts with | [] -> rem | d1 :: dl -> fn Text_first d1 :: map_end (fn Text_next) dl rem (* Auxiliary for translating recursively-defined module types. Return a module type that approximates the shape of the given module type AST. Retain only module, type, and module type components of signatures. For types, retain only their arity, making them abstract otherwise. *) let rec approx_modtype env smty = match smty.pmty_desc with Pmty_ident lid -> let (path, info) = Typetexp.find_modtype env smty.pmty_loc lid.txt in Mty_ident path | Pmty_alias lid -> let path = Typetexp.find_module env smty.pmty_loc lid.txt in Mty_alias path | Pmty_signature ssg -> Mty_signature(approx_sig env ssg) | Pmty_functor(param, sarg, sres) -> let arg = may_map (approx_modtype env) sarg in let (id, newenv) = Env.enter_module ~arg:true param.txt (Btype.default_mty arg) env in let res = approx_modtype newenv sres in Mty_functor(id, arg, res) | Pmty_with(sbody, constraints) -> approx_modtype env sbody | Pmty_typeof smod -> let (_, mty) = !type_module_type_of_fwd env smod in mty | Pmty_extension (s, _arg) -> raise (Error (s.loc, env, Extension s.txt)) and approx_module_declaration env pmd = { Types.md_type = approx_modtype env pmd.pmd_type; md_attributes = pmd.pmd_attributes; md_loc = pmd.pmd_loc; } and approx_sig env ssg = match ssg with [] -> [] | item :: srem -> match item.psig_desc with | Psig_type sdecls -> let decls = Typedecl.approx_type_decl env sdecls in let rem = approx_sig env srem in map_rec' (fun rs (id, info) -> Sig_type(id, info, rs)) decls rem | Psig_module pmd -> let md = approx_module_declaration env pmd in let (id, newenv) = Env.enter_module_declaration pmd.pmd_name.txt md env in Sig_module(id, md, Trec_not) :: approx_sig newenv srem | Psig_recmodule sdecls -> let decls = List.map (fun pmd -> (Ident.create pmd.pmd_name.txt, approx_module_declaration env pmd) ) sdecls in let newenv = List.fold_left (fun env (id, md) -> Env.add_module_declaration id md env) env decls in map_rec (fun rs (id, md) -> Sig_module(id, md, rs)) decls (approx_sig newenv srem) | Psig_modtype d -> let info = approx_modtype_info env d in let (id, newenv) = Env.enter_modtype d.pmtd_name.txt info env in Sig_modtype(id, info) :: approx_sig newenv srem | Psig_open sod -> let (path, mty, _od) = type_open env sod in approx_sig mty srem | Psig_include sincl -> let smty = sincl.pincl_mod in let mty = approx_modtype env smty in let sg = Subst.signature Subst.identity (extract_sig env smty.pmty_loc mty) in let newenv = Env.add_signature sg env in sg @ approx_sig newenv srem | Psig_class sdecls | Psig_class_type sdecls -> let decls = Typeclass.approx_class_declarations env sdecls in let rem = approx_sig env srem in List.flatten (map_rec (fun rs (i1, _, d1, i2, d2, i3, d3, _) -> [Sig_class_type(i1, d1, rs); Sig_type(i2, d2, rs); Sig_type(i3, d3, rs)]) decls [rem]) | _ -> approx_sig env srem and approx_modtype_info env sinfo = { mtd_type = may_map (approx_modtype env) sinfo.pmtd_type; mtd_attributes = sinfo.pmtd_attributes; mtd_loc = sinfo.pmtd_loc; } (* Additional validity checks on type definitions arising from recursive modules *) let check_recmod_typedecls env sdecls decls = let recmod_ids = List.map fst3 decls in List.iter2 (fun pmd (id, _, mty) -> let mty = mty.mty_type in List.iter (fun path -> Typedecl.check_recmod_typedecl env pmd.pmd_type.pmty_loc recmod_ids path (Env.find_type path env)) (Mtype.type_paths env (Pident id) mty)) sdecls decls (* Auxiliaries for checking uniqueness of names in signatures and structures *) module StringSet = Set.Make(struct type t = string let compare (x:t) y = compare x y end) let check cl loc set_ref name = if StringSet.mem name !set_ref then raise(Error(loc, Env.empty, Repeated_name(cl, name))) else set_ref := StringSet.add name !set_ref let check_name cl set_ref name = check cl name.loc set_ref name.txt let check_sig_item type_names module_names modtype_names loc = function Sig_type(id, _, _) -> check "type" loc type_names (Ident.name id) | Sig_module(id, _, _) -> check "module" loc module_names (Ident.name id) | Sig_modtype(id, _) -> check "module type" loc modtype_names (Ident.name id) | _ -> () let rec remove_duplicates val_ids ext_ids = function [] -> [] | Sig_value (id, _) :: rem when List.exists (Ident.equal id) val_ids -> remove_duplicates val_ids ext_ids rem | Sig_typext (id, _, _) :: rem when List.exists (Ident.equal id) ext_ids -> remove_duplicates val_ids ext_ids rem | f :: rem -> f :: remove_duplicates val_ids ext_ids rem let rec get_values = function [] -> [] | Sig_value (id, _) :: rem -> id :: get_values rem | f :: rem -> get_values rem let rec get_extension_constructors = function [] -> [] | Sig_typext (id, _, _) :: rem -> id :: get_extension_constructors rem | f :: rem -> get_extension_constructors rem (* Check and translate a module type expression *) let transl_modtype_longident loc env lid = let (path, info) = Typetexp.find_modtype env loc lid in path let transl_module_alias loc env lid = Typetexp.find_module env loc lid let mkmty desc typ env loc attrs = let mty = { mty_desc = desc; mty_type = typ; mty_loc = loc; mty_env = env; mty_attributes = attrs; } in Cmt_format.add_saved_type (Cmt_format.Partial_module_type mty); mty let mksig desc env loc = let sg = { sig_desc = desc; sig_loc = loc; sig_env = env } in Cmt_format.add_saved_type (Cmt_format.Partial_signature_item sg); sg (* let signature sg = List.map (fun item -> item.sig_type) sg *) let rec transl_modtype env smty = let loc = smty.pmty_loc in match smty.pmty_desc with Pmty_ident lid -> let path = transl_modtype_longident loc env lid.txt in mkmty (Tmty_ident (path, lid)) (Mty_ident path) env loc smty.pmty_attributes | Pmty_alias lid -> let path = transl_module_alias loc env lid.txt in mkmty (Tmty_alias (path, lid)) (Mty_alias path) env loc smty.pmty_attributes | Pmty_signature ssg -> let sg = transl_signature env ssg in mkmty (Tmty_signature sg) (Mty_signature sg.sig_type) env loc smty.pmty_attributes | Pmty_functor(param, sarg, sres) -> let arg = Misc.may_map (transl_modtype env) sarg in let ty_arg = Misc.may_map (fun m -> m.mty_type) arg in let (id, newenv) = Env.enter_module ~arg:true param.txt (Btype.default_mty ty_arg) env in let res = transl_modtype newenv sres in mkmty (Tmty_functor (id, param, arg, res)) (Mty_functor(id, ty_arg, res.mty_type)) env loc smty.pmty_attributes | Pmty_with(sbody, constraints) -> let body = transl_modtype env sbody in let init_sg = extract_sig env sbody.pmty_loc body.mty_type in let (tcstrs, final_sg) = List.fold_left (fun (tcstrs,sg) sdecl -> let (tcstr, sg) = merge_constraint env smty.pmty_loc sg sdecl in (tcstr :: tcstrs, sg) ) ([],init_sg) constraints in mkmty (Tmty_with ( body, tcstrs)) (Mtype.freshen (Mty_signature final_sg)) env loc smty.pmty_attributes | Pmty_typeof smod -> let tmty, mty = !type_module_type_of_fwd env smod in mkmty (Tmty_typeof tmty) mty env loc smty.pmty_attributes | Pmty_extension (s, _arg) -> raise (Error (s.loc, env, Extension s.txt)) and transl_signature env sg = let type_names = ref StringSet.empty and module_names = ref StringSet.empty and modtype_names = ref StringSet.empty in let rec transl_sig env sg = Ctype.init_def(Ident.current_time()); match sg with [] -> [], [], env | item :: srem -> let loc = item.psig_loc in match item.psig_desc with | Psig_value sdesc -> let (tdesc, newenv) = Typedecl.transl_value_decl env item.psig_loc sdesc in let (trem,rem, final_env) = transl_sig newenv srem in mksig (Tsig_value tdesc) env loc :: trem, (if List.exists (Ident.equal tdesc.val_id) (get_values rem) then rem else Sig_value(tdesc.val_id, tdesc.val_val) :: rem), final_env | Psig_type sdecls -> List.iter (fun decl -> check_name "type" type_names decl.ptype_name) sdecls; let (decls, newenv) = Typedecl.transl_type_decl env sdecls in let (trem, rem, final_env) = transl_sig newenv srem in mksig (Tsig_type decls) env loc :: trem, map_rec'' (fun rs td -> Sig_type(td.typ_id, td.typ_type, rs)) decls rem, final_env | Psig_typext styext -> let (tyext, newenv) = Typedecl.transl_type_extension false env item.psig_loc styext in let (trem, rem, final_env) = transl_sig newenv srem in let constructors = List.filter (fun ext -> not (List.exists (Ident.equal ext.ext_id) (get_extension_constructors rem))) tyext.tyext_constructors in mksig (Tsig_typext tyext) env loc :: trem, map_ext (fun es ext -> Sig_typext(ext.ext_id, ext.ext_type, es)) constructors rem, final_env | Psig_exception sext -> let (ext, newenv) = Typedecl.transl_exception env sext in let (trem, rem, final_env) = transl_sig newenv srem in let shadowed = List.exists (Ident.equal ext.ext_id) (get_extension_constructors rem) in mksig (Tsig_exception ext) env loc :: trem, (if shadowed then rem else Sig_typext(ext.ext_id, ext.ext_type, Text_exception) :: rem), final_env | Psig_module pmd -> check_name "module" module_names pmd.pmd_name; let tmty = transl_modtype env pmd.pmd_type in let md = { md_type=tmty.mty_type; md_attributes=pmd.pmd_attributes; md_loc=pmd.pmd_loc; } in let (id, newenv) = Env.enter_module_declaration pmd.pmd_name.txt md env in let (trem, rem, final_env) = transl_sig newenv srem in mksig (Tsig_module {md_id=id; md_name=pmd.pmd_name; md_type=tmty; md_loc=pmd.pmd_loc; md_attributes=pmd.pmd_attributes}) env loc :: trem, Sig_module(id, md, Trec_not) :: rem, final_env | Psig_recmodule sdecls -> List.iter (fun pmd -> check_name "module" module_names pmd.pmd_name) sdecls; let (decls, newenv) = transl_recmodule_modtypes item.psig_loc env sdecls in let (trem, rem, final_env) = transl_sig newenv srem in mksig (Tsig_recmodule decls) env loc :: trem, map_rec (fun rs md -> let d = {Types.md_type = md.md_type.mty_type; md_attributes = md.md_attributes; md_loc = md.md_loc; } in Sig_module(md.md_id, d, rs)) decls rem, final_env | Psig_modtype pmtd -> let newenv, mtd, sg = transl_modtype_decl modtype_names env item.psig_loc pmtd in let (trem, rem, final_env) = transl_sig newenv srem in mksig (Tsig_modtype mtd) env loc :: trem, sg :: rem, final_env | Psig_open sod -> let (path, newenv, od) = type_open env sod in let (trem, rem, final_env) = transl_sig newenv srem in mksig (Tsig_open od) env loc :: trem, rem, final_env | Psig_include sincl -> let smty = sincl.pincl_mod in let tmty = transl_modtype env smty in let mty = tmty.mty_type in let sg = Subst.signature Subst.identity (extract_sig env smty.pmty_loc mty) in List.iter (check_sig_item type_names module_names modtype_names item.psig_loc) sg; let newenv = Env.add_signature sg env in let incl = { incl_mod = tmty; incl_type = sg; incl_attributes = sincl.pincl_attributes; incl_loc = sincl.pincl_loc; } in let (trem, rem, final_env) = transl_sig newenv srem in mksig (Tsig_include incl) env loc :: trem, remove_duplicates (get_values rem) (get_extension_constructors rem) sg @ rem, final_env | Psig_class cl -> List.iter (fun {pci_name = name} -> check_name "type" type_names name) cl; let (classes, newenv) = Typeclass.class_descriptions env cl in let (trem, rem, final_env) = transl_sig newenv srem in mksig (Tsig_class (List.map2 (fun pcl tcl -> let (_, _, _, _, _, _, _, _, _, _, _, tcl) = tcl in tcl) cl classes)) env loc :: trem, List.flatten (map_rec (fun rs (i, _, d, i', d', i'', d'', i''', d''', _, _, _) -> [Sig_class(i, d, rs); Sig_class_type(i', d', rs); Sig_type(i'', d'', rs); Sig_type(i''', d''', rs)]) classes [rem]), final_env | Psig_class_type cl -> List.iter (fun {pci_name = name} -> check_name "type" type_names name) cl; let (classes, newenv) = Typeclass.class_type_declarations env cl in let (trem,rem, final_env) = transl_sig newenv srem in mksig (Tsig_class_type (List.map2 (fun pcl tcl -> let (_, _, _, _, _, _, _, tcl) = tcl in tcl ) cl classes)) env loc :: trem, List.flatten (map_rec (fun rs (i, _, d, i', d', i'', d'', _) -> [Sig_class_type(i, d, rs); Sig_type(i', d', rs); Sig_type(i'', d'', rs)]) classes [rem]), final_env | Psig_attribute x -> Typetexp.warning_attribute [x]; let (trem,rem, final_env) = transl_sig env srem in mksig (Tsig_attribute x) env loc :: trem, rem, final_env | Psig_extension ((s, _), _) -> raise (Error (s.loc, env, Extension s.txt)) in let previous_saved_types = Cmt_format.get_saved_types () in Typetexp.warning_enter_scope (); let (trem, rem, final_env) = transl_sig (Env.in_signature env) sg in let sg = { sig_items = trem; sig_type = rem; sig_final_env = final_env } in Typetexp.warning_leave_scope (); Cmt_format.set_saved_types ((Cmt_format.Partial_signature sg) :: previous_saved_types); sg and transl_modtype_decl modtype_names env loc {pmtd_name; pmtd_type; pmtd_attributes; pmtd_loc} = check_name "module type" modtype_names pmtd_name; let tmty = Misc.may_map (transl_modtype env) pmtd_type in let decl = { Types.mtd_type=may_map (fun t -> t.mty_type) tmty; mtd_attributes=pmtd_attributes; mtd_loc=pmtd_loc; } in let (id, newenv) = Env.enter_modtype pmtd_name.txt decl env in let mtd = { mtd_id=id; mtd_name=pmtd_name; mtd_type=tmty; mtd_attributes=pmtd_attributes; mtd_loc=pmtd_loc; } in newenv, mtd, Sig_modtype(id, decl) and transl_recmodule_modtypes loc env sdecls = let make_env curr = List.fold_left (fun env (id, _, mty) -> Env.add_module ~arg:true id mty env) env curr in let make_env2 curr = List.fold_left (fun env (id, _, mty) -> Env.add_module ~arg:true id mty.mty_type env) env curr in let transition env_c curr = List.map2 (fun pmd (id, id_loc, mty) -> (id, id_loc, transl_modtype env_c pmd.pmd_type)) sdecls curr in let ids = List.map (fun x -> Ident.create x.pmd_name.txt) sdecls in let approx_env = (* cf #5965 We use a dummy module type in order to detect a reference to one of the module being defined during the call to approx_modtype. It will be detected in Env.lookup_module. *) List.fold_left (fun env id -> let dummy = Mty_ident (Path.Pident (Ident.create "#recmod#")) in Env.add_module ~arg:true id dummy env ) env ids in let init = List.map2 (fun id pmd -> (id, pmd.pmd_name, approx_modtype approx_env pmd.pmd_type)) ids sdecls in let env0 = make_env init in let dcl1 = transition env0 init in let env1 = make_env2 dcl1 in check_recmod_typedecls env1 sdecls dcl1; let dcl2 = transition env1 dcl1 in (* List.iter (fun (id, mty) -> Format.printf "%a: %a@." Printtyp.ident id Printtyp.modtype mty) dcl2; *) let env2 = make_env2 dcl2 in check_recmod_typedecls env2 sdecls dcl2; let dcl2 = List.map2 (fun pmd (id, id_loc, mty) -> {md_id=id; md_name=id_loc; md_type=mty; md_loc=pmd.pmd_loc; md_attributes=pmd.pmd_attributes}) sdecls dcl2 in (dcl2, env2) (* Try to convert a module expression to a module path. *) exception Not_a_path let rec path_of_module mexp = match mexp.mod_desc with Tmod_ident (p,_) -> p | Tmod_apply(funct, arg, coercion) when !Clflags.applicative_functors -> Papply(path_of_module funct, path_of_module arg) | Tmod_constraint (mexp, _, _, _) -> path_of_module mexp | _ -> raise Not_a_path (* Check that all core type schemes in a structure are closed *) let rec closed_modtype = function Mty_ident p -> true | Mty_alias p -> true | Mty_signature sg -> List.for_all closed_signature_item sg | Mty_functor(id, param, body) -> closed_modtype body and closed_signature_item = function Sig_value(id, desc) -> Ctype.closed_schema desc.val_type | Sig_module(id, md, _) -> closed_modtype md.md_type | _ -> true let check_nongen_scheme env str = match str.str_desc with Tstr_value(rec_flag, pat_exp_list) -> List.iter (fun {vb_expr=exp} -> if not (Ctype.closed_schema exp.exp_type) then raise(Error(exp.exp_loc, env, Non_generalizable exp.exp_type))) pat_exp_list | Tstr_module {mb_expr=md;_} -> if not (closed_modtype md.mod_type) then raise(Error(md.mod_loc, env, Non_generalizable_module md.mod_type)) | _ -> () let check_nongen_schemes env str = List.iter (check_nongen_scheme env) str (* Helpers for typing recursive modules *) let anchor_submodule name anchor = match anchor with None -> None | Some p -> Some(Pdot(p, name, nopos)) let anchor_recmodule id anchor = Some (Pident id) let enrich_type_decls anchor decls oldenv newenv = match anchor with None -> newenv | Some p -> List.fold_left (fun e info -> let id = info.typ_id in let info' = Mtype.enrich_typedecl oldenv (Pdot(p, Ident.name id, nopos)) info.typ_type in Env.add_type ~check:true id info' e) oldenv decls let enrich_module_type anchor name mty env = match anchor with None -> mty | Some p -> Mtype.enrich_modtype env (Pdot(p, name, nopos)) mty let check_recmodule_inclusion env bindings = (* PR#4450, PR#4470: consider module rec X : DECL = MOD where MOD has inferred type ACTUAL The "natural" typing condition E, X: ACTUAL |- ACTUAL <: DECL leads to circularities through manifest types. Instead, we "unroll away" the potential circularities a finite number of times. The (weaker) condition we implement is: E, X: DECL, X1: ACTUAL, X2: ACTUAL{X <- X1}/X1 ... Xn: ACTUAL{X <- X(n-1)}/X(n-1) |- ACTUAL{X <- Xn}/Xn <: DECL{X <- Xn} so that manifest types rooted at X(n+1) are expanded in terms of X(n), avoiding circularities. The strengthenings ensure that Xn.t = X(n-1).t = ... = X2.t = X1.t. N can be chosen arbitrarily; larger values of N result in more recursive definitions being accepted. A good choice appears to be the number of mutually recursive declarations. *) let subst_and_strengthen env s id mty = Mtype.strengthen env (Subst.modtype s mty) (Subst.module_path s (Pident id)) in let rec check_incl first_time n env s = if n > 0 then begin (* Generate fresh names Y_i for the rec. bound module idents X_i *) let bindings1 = List.map (fun (id, _, mty_decl, modl, mty_actual, _attrs, _loc) -> (id, Ident.rename id, mty_actual)) bindings in (* Enter the Y_i in the environment with their actual types substituted by the input substitution s *) let env' = List.fold_left (fun env (id, id', mty_actual) -> let mty_actual' = if first_time then mty_actual else subst_and_strengthen env s id mty_actual in Env.add_module ~arg:false id' mty_actual' env) env bindings1 in (* Build the output substitution Y_i <- X_i *) let s' = List.fold_left (fun s (id, id', mty_actual) -> Subst.add_module id (Pident id') s) Subst.identity bindings1 in (* Recurse with env' and s' *) check_incl false (n-1) env' s' end else begin (* Base case: check inclusion of s(mty_actual) in s(mty_decl) and insert coercion if needed *) let check_inclusion (id, id_loc, mty_decl, modl, mty_actual, attrs, loc) = let mty_decl' = Subst.modtype s mty_decl.mty_type and mty_actual' = subst_and_strengthen env s id mty_actual in let coercion = try Includemod.modtypes env mty_actual' mty_decl' with Includemod.Error msg -> raise(Error(modl.mod_loc, env, Not_included msg)) in let modl' = { mod_desc = Tmod_constraint(modl, mty_decl.mty_type, Tmodtype_explicit mty_decl, coercion); mod_type = mty_decl.mty_type; mod_env = env; mod_loc = modl.mod_loc; mod_attributes = []; } in { mb_id = id; mb_name = id_loc; mb_expr = modl'; mb_attributes = attrs; mb_loc = loc; } in List.map check_inclusion bindings end in check_incl true (List.length bindings) env Subst.identity (* Helper for unpack *) let rec package_constraints env loc mty constrs = if constrs = [] then mty else let sg = extract_sig env loc mty in let sg' = List.map (function | Sig_type (id, ({type_params=[]} as td), rs) when List.mem_assoc [Ident.name id] constrs -> let ty = List.assoc [Ident.name id] constrs in Sig_type (id, {td with type_manifest = Some ty}, rs) | Sig_module (id, md, rs) -> let rec aux = function | (m :: ((_ :: _) as l), t) :: rest when m = Ident.name id -> (l, t) :: aux rest | _ :: rest -> aux rest | [] -> [] in let md = {md with md_type = package_constraints env loc md.md_type (aux constrs) } in Sig_module (id, md, rs) | item -> item ) sg in Mty_signature sg' let modtype_of_package env loc p nl tl = try match (Env.find_modtype p env).mtd_type with | Some mty when nl <> [] -> package_constraints env loc mty (List.combine (List.map Longident.flatten nl) tl) | _ -> if nl = [] then Mty_ident p else raise(Error(loc, env, Signature_expected)) with Not_found -> let error = Typetexp.Unbound_modtype (Ctype.lid_of_path p) in raise(Typetexp.Error(loc, env, error)) let package_subtype env p1 nl1 tl1 p2 nl2 tl2 = let mkmty p nl tl = let ntl = List.filter (fun (n,t) -> Ctype.free_variables t = []) (List.combine nl tl) in let (nl, tl) = List.split ntl in modtype_of_package env Location.none p nl tl in let mty1 = mkmty p1 nl1 tl1 and mty2 = mkmty p2 nl2 tl2 in try Includemod.modtypes env mty1 mty2 = Tcoerce_none with Includemod.Error msg -> false (* raise(Error(Location.none, env, Not_included msg)) *) let () = Ctype.package_subtype := package_subtype let wrap_constraint env arg mty explicit = let coercion = try Includemod.modtypes env arg.mod_type mty with Includemod.Error msg -> raise(Error(arg.mod_loc, env, Not_included msg)) in { mod_desc = Tmod_constraint(arg, mty, explicit, coercion); mod_type = mty; mod_env = env; mod_attributes = []; mod_loc = arg.mod_loc } (* Type a module value expression *) let rec type_module ?(alias=false) sttn funct_body anchor env smod = match smod.pmod_desc with Pmod_ident lid -> let path = Typetexp.find_module env smod.pmod_loc lid.txt in let md = { mod_desc = Tmod_ident (path, lid); mod_type = Mty_alias path; mod_env = env; mod_attributes = smod.pmod_attributes; mod_loc = smod.pmod_loc } in let md = if alias && not (Env.is_functor_arg path env) then (Env.add_required_global (Path.head path); md) else match (Env.find_module path env).md_type with Mty_alias p1 when not alias -> let p1 = Env.normalize_path (Some smod.pmod_loc) env p1 in let mty = Includemod.expand_module_alias env [] p1 in { md with mod_desc = Tmod_constraint (md, mty, Tmodtype_implicit, Tcoerce_alias (p1, Tcoerce_none)); mod_type = if sttn then Mtype.strengthen env mty p1 else mty } | mty -> let mty = if sttn then Mtype.strengthen env mty path else mty in { md with mod_type = mty } in rm md | Pmod_structure sstr -> let (str, sg, finalenv) = type_structure funct_body anchor env sstr smod.pmod_loc in rm { mod_desc = Tmod_structure str; mod_type = Mty_signature sg; mod_env = env; mod_attributes = smod.pmod_attributes; mod_loc = smod.pmod_loc } | Pmod_functor(name, smty, sbody) -> let mty = may_map (transl_modtype env) smty in let ty_arg = may_map (fun m -> m.mty_type) mty in let (id, newenv), funct_body = match ty_arg with None -> (Ident.create "*", env), false | Some mty -> Env.enter_module ~arg:true name.txt mty env, true in let body = type_module sttn funct_body None newenv sbody in rm { mod_desc = Tmod_functor(id, name, mty, body); mod_type = Mty_functor(id, ty_arg, body.mod_type); mod_env = env; mod_attributes = smod.pmod_attributes; mod_loc = smod.pmod_loc } | Pmod_apply(sfunct, sarg) -> let arg = type_module true funct_body None env sarg in let path = try Some (path_of_module arg) with Not_a_path -> None in let funct = type_module (sttn && path <> None) funct_body None env sfunct in begin match Env.scrape_alias env funct.mod_type with Mty_functor(param, mty_param, mty_res) as mty_functor -> let generative, mty_param = (mty_param = None, Btype.default_mty mty_param) in if generative then begin if sarg.pmod_desc <> Pmod_structure [] then raise (Error (sfunct.pmod_loc, env, Apply_generative)); if funct_body && Mtype.contains_type env funct.mod_type then raise (Error (smod.pmod_loc, env, Not_allowed_in_functor_body)); end; let coercion = try Includemod.modtypes env arg.mod_type mty_param with Includemod.Error msg -> raise(Error(sarg.pmod_loc, env, Not_included msg)) in let mty_appl = match path with Some path -> Subst.modtype (Subst.add_module param path Subst.identity) mty_res | None -> if generative then mty_res else try Mtype.nondep_supertype (Env.add_module ~arg:true param arg.mod_type env) param mty_res with Not_found -> raise(Error(smod.pmod_loc, env, Cannot_eliminate_dependency mty_functor)) in rm { mod_desc = Tmod_apply(funct, arg, coercion); mod_type = mty_appl; mod_env = env; mod_attributes = smod.pmod_attributes; mod_loc = smod.pmod_loc } | _ -> raise(Error(sfunct.pmod_loc, env, Cannot_apply funct.mod_type)) end | Pmod_constraint(sarg, smty) -> let arg = type_module ~alias true funct_body anchor env sarg in let mty = transl_modtype env smty in rm {(wrap_constraint env arg mty.mty_type (Tmodtype_explicit mty)) with mod_loc = smod.pmod_loc; mod_attributes = smod.pmod_attributes; } | Pmod_unpack sexp -> if !Clflags.principal then Ctype.begin_def (); let exp = Typecore.type_exp env sexp in if !Clflags.principal then begin Ctype.end_def (); Ctype.generalize_structure exp.exp_type end; let mty = match Ctype.expand_head env exp.exp_type with {desc = Tpackage (p, nl, tl)} -> if List.exists (fun t -> Ctype.free_variables t <> []) tl then raise (Error (smod.pmod_loc, env, Incomplete_packed_module exp.exp_type)); if !Clflags.principal && not (Typecore.generalizable (Btype.generic_level-1) exp.exp_type) then Location.prerr_warning smod.pmod_loc (Warnings.Not_principal "this module unpacking"); modtype_of_package env smod.pmod_loc p nl tl | {desc = Tvar _} -> raise (Typecore.Error (smod.pmod_loc, env, Typecore.Cannot_infer_signature)) | _ -> raise (Error(smod.pmod_loc, env, Not_a_packed_module exp.exp_type)) in if funct_body && Mtype.contains_type env mty then raise (Error (smod.pmod_loc, env, Not_allowed_in_functor_body)); rm { mod_desc = Tmod_unpack(exp, mty); mod_type = mty; mod_env = env; mod_attributes = smod.pmod_attributes; mod_loc = smod.pmod_loc } | Pmod_extension (s, _arg) -> raise (Error (s.loc, env, Extension s.txt)) and type_structure ?(toplevel = false) funct_body anchor env sstr scope = let type_names = ref StringSet.empty and module_names = ref StringSet.empty and modtype_names = ref StringSet.empty in let type_str_item env srem {pstr_loc = loc; pstr_desc = desc} = match desc with | Pstr_eval (sexpr, attrs) -> let expr = Typecore.type_expression env sexpr in Tstr_eval (expr, attrs), [], env | Pstr_value(rec_flag, sdefs) -> let scope = match rec_flag with | Recursive -> Some (Annot.Idef {scope with Location.loc_start = loc.Location.loc_start}) | Nonrecursive -> let start = match srem with | [] -> loc.Location.loc_end | {pstr_loc = loc2} :: _ -> loc2.Location.loc_start in Some (Annot.Idef {scope with Location.loc_start = start}) in let (defs, newenv) = Typecore.type_binding env rec_flag sdefs scope in (* Note: Env.find_value does not trigger the value_used event. Values will be marked as being used during the signature inclusion test. *) Tstr_value(rec_flag, defs), List.map (fun id -> Sig_value(id, Env.find_value (Pident id) newenv)) (let_bound_idents defs), newenv | Pstr_primitive sdesc -> let (desc, newenv) = Typedecl.transl_value_decl env loc sdesc in Tstr_primitive desc, [Sig_value(desc.val_id, desc.val_val)], newenv | Pstr_type sdecls -> List.iter (fun decl -> check_name "type" type_names decl.ptype_name) sdecls; let (decls, newenv) = Typedecl.transl_type_decl env sdecls in Tstr_type decls, map_rec'' (fun rs info -> Sig_type(info.typ_id, info.typ_type, rs)) decls [], enrich_type_decls anchor decls env newenv | Pstr_typext styext -> let (tyext, newenv) = Typedecl.transl_type_extension true env loc styext in (Tstr_typext tyext, map_ext (fun es ext -> Sig_typext(ext.ext_id, ext.ext_type, es)) tyext.tyext_constructors [], newenv) | Pstr_exception sext -> let (ext, newenv) = Typedecl.transl_exception env sext in Tstr_exception ext, [Sig_typext(ext.ext_id, ext.ext_type, Text_exception)], newenv | Pstr_module {pmb_name = name; pmb_expr = smodl; pmb_attributes = attrs; pmb_loc; } -> check_name "module" module_names name; let modl = type_module ~alias:true true funct_body (anchor_submodule name.txt anchor) env smodl in let md = { md_type = enrich_module_type anchor name.txt modl.mod_type env; md_attributes = attrs; md_loc = pmb_loc; } in let (id, newenv) = Env.enter_module_declaration name.txt md env in Tstr_module {mb_id=id; mb_name=name; mb_expr=modl; mb_attributes=attrs; mb_loc=pmb_loc; }, [Sig_module(id, {md_type = modl.mod_type; md_attributes = attrs; md_loc = pmb_loc; }, Trec_not)], newenv | Pstr_recmodule sbind -> let sbind = List.map (function | {pmb_name = name; pmb_expr = {pmod_desc=Pmod_constraint(expr, typ)}; pmb_attributes = attrs; pmb_loc = loc; } -> name, typ, expr, attrs, loc | mb -> raise (Error (mb.pmb_expr.pmod_loc, env, Recursive_module_require_explicit_type)) ) sbind in List.iter (fun (name, _, _, _, _) -> check_name "module" module_names name) sbind; let (decls, newenv) = transl_recmodule_modtypes loc env (List.map (fun (name, smty, smodl, attrs, loc) -> {pmd_name=name; pmd_type=smty; pmd_attributes=attrs; pmd_loc=loc}) sbind ) in let bindings1 = List.map2 (fun {md_id=id; md_type=mty} (name, _, smodl, attrs, loc) -> let modl = type_module true funct_body (anchor_recmodule id anchor) newenv smodl in let mty' = enrich_module_type anchor (Ident.name id) modl.mod_type newenv in (id, name, mty, modl, mty', attrs, loc)) decls sbind in let newenv = (* allow aliasing recursive modules from outside *) List.fold_left (fun env md -> Env.add_module md.md_id md.md_type.mty_type env) env decls in let bindings2 = check_recmodule_inclusion newenv bindings1 in Tstr_recmodule bindings2, map_rec (fun rs mb -> Sig_module(mb.mb_id, { md_type=mb.mb_expr.mod_type; md_attributes=mb.mb_attributes; md_loc=mb.mb_loc; }, rs)) bindings2 [], newenv | Pstr_modtype pmtd -> (* check that it is non-abstract *) let newenv, mtd, sg = transl_modtype_decl modtype_names env loc pmtd in Tstr_modtype mtd, [sg], newenv | Pstr_open sod -> let (path, newenv, od) = type_open ~toplevel env sod in Tstr_open od, [], newenv | Pstr_class cl -> List.iter (fun {pci_name = name} -> check_name "type" type_names name) cl; let (classes, new_env) = Typeclass.class_declarations env cl in Tstr_class (List.map (fun (i, _, d, _,_,_,_,_,_, s, m, c) -> let vf = if d.cty_new = None then Virtual else Concrete in (* (i, s, m, c, vf) *) (c, m, vf)) classes), (* TODO: check with Jacques why this is here Tstr_class_type (List.map (fun (_,_, i, d, _,_,_,_,_,_,c) -> (i, c)) classes) :: Tstr_type (List.map (fun (_,_,_,_, i, d, _,_,_,_,_) -> (i, d)) classes) :: Tstr_type (List.map (fun (_,_,_,_,_,_, i, d, _,_,_) -> (i, d)) classes) :: *) List.flatten (map_rec (fun rs (i, _, d, i', d', i'', d'', i''', d''', _, _, _) -> [Sig_class(i, d, rs); Sig_class_type(i', d', rs); Sig_type(i'', d'', rs); Sig_type(i''', d''', rs)]) classes []), new_env | Pstr_class_type cl -> List.iter (fun {pci_name = name} -> check_name "type" type_names name) cl; let (classes, new_env) = Typeclass.class_type_declarations env cl in Tstr_class_type (List.map (fun (i, i_loc, d, _, _, _, _, c) -> (i, i_loc, c)) classes), (* TODO: check with Jacques why this is here Tstr_type (List.map (fun (_, _, i, d, _, _) -> (i, d)) classes) :: Tstr_type (List.map (fun (_, _, _, _, i, d) -> (i, d)) classes) :: *) List.flatten (map_rec (fun rs (i, _, d, i', d', i'', d'', _) -> [Sig_class_type(i, d, rs); Sig_type(i', d', rs); Sig_type(i'', d'', rs)]) classes []), new_env | Pstr_include sincl -> let smodl = sincl.pincl_mod in let modl = type_module true funct_body None env smodl in (* Rename all identifiers bound by this signature to avoid clashes *) let sg = Subst.signature Subst.identity (extract_sig_open env smodl.pmod_loc modl.mod_type) in let sg = match modl.mod_desc with Tmod_ident (p, _) when not (Env.is_functor_arg p env) -> Env.add_required_global (Path.head p); let pos = ref 0 in List.map (function | Sig_module (id, md, rs) -> let n = !pos in incr pos; Sig_module (id, {md with md_type = Mty_alias (Pdot(p,Ident.name id,n))}, rs) | Sig_value (_, {val_kind=Val_reg}) | Sig_typext _ | Sig_class _ as it -> incr pos; it | Sig_value _ | Sig_type _ | Sig_modtype _ | Sig_class_type _ as it -> it) sg | _ -> sg in List.iter (check_sig_item type_names module_names modtype_names loc) sg; let new_env = Env.add_signature sg env in let incl = { incl_mod = modl; incl_type = sg; incl_attributes = sincl.pincl_attributes; incl_loc = sincl.pincl_loc; } in Tstr_include incl, sg, new_env | Pstr_extension ((s, _), _) -> raise (Error (s.loc, env, Extension s.txt)) | Pstr_attribute x -> Typetexp.warning_attribute [x]; Tstr_attribute x, [], env in let rec type_struct env sstr = Ctype.init_def(Ident.current_time()); match sstr with | [] -> ([], [], env) | pstr :: srem -> let previous_saved_types = Cmt_format.get_saved_types () in let desc, sg, new_env = type_str_item env srem pstr in let str = { str_desc = desc; str_loc = pstr.pstr_loc; str_env = env } in Cmt_format.set_saved_types (Cmt_format.Partial_structure_item str :: previous_saved_types); let (str_rem, sig_rem, final_env) = type_struct new_env srem in (str :: str_rem, sg @ sig_rem, final_env) in if !Clflags.annotations then (* moved to genannot *) List.iter (function {pstr_loc = l} -> Stypes.record_phrase l) sstr; let previous_saved_types = Cmt_format.get_saved_types () in Typetexp.warning_enter_scope (); let (items, sg, final_env) = type_struct env sstr in let str = { str_items = items; str_type = sg; str_final_env = final_env } in Typetexp.warning_leave_scope (); Cmt_format.set_saved_types (Cmt_format.Partial_structure str :: previous_saved_types); str, sg, final_env let type_toplevel_phrase env s = Env.reset_required_globals (); type_structure ~toplevel:true false None env s Location.none (*let type_module_alias = type_module ~alias:true true false None*) let type_module = type_module true false None let type_structure = type_structure false None (* Normalize types in a signature *) let rec normalize_modtype env = function Mty_ident p -> () | Mty_alias p -> () | Mty_signature sg -> normalize_signature env sg | Mty_functor(id, param, body) -> normalize_modtype env body and normalize_signature env = List.iter (normalize_signature_item env) and normalize_signature_item env = function Sig_value(id, desc) -> Ctype.normalize_type env desc.val_type | Sig_module(id, md, _) -> normalize_modtype env md.md_type | _ -> () (* Simplify multiple specifications of a value or an extension in a signature. (Other signature components, e.g. types, modules, etc, are checked for name uniqueness.) If multiple specifications with the same name, keep only the last (rightmost) one. *) let rec simplify_modtype mty = match mty with Mty_ident path -> mty | Mty_alias path -> mty | Mty_functor(id, arg, res) -> Mty_functor(id, arg, simplify_modtype res) | Mty_signature sg -> Mty_signature(simplify_signature sg) and simplify_signature sg = let rec simplif val_names ext_names res = function [] -> res | (Sig_value(id, descr) as component) :: sg -> let name = Ident.name id in simplif (StringSet.add name val_names) ext_names (if StringSet.mem name val_names then res else component :: res) sg | (Sig_typext(id, ext, es) as component) :: sg -> let name = Ident.name id in simplif val_names (StringSet.add name ext_names) (if StringSet.mem name ext_names then res else component :: res) sg | Sig_module(id, md, rs) :: sg -> let md = {md with md_type = simplify_modtype md.md_type} in simplif val_names ext_names (Sig_module(id, md, rs) :: res) sg | component :: sg -> simplif val_names ext_names (component :: res) sg in simplif StringSet.empty StringSet.empty [] (List.rev sg) (* Extract the module type of a module expression *) let type_module_type_of env smod = let tmty = match smod.pmod_desc with | Pmod_ident lid -> (* turn off strengthening in this case *) let path = Typetexp.find_module env smod.pmod_loc lid.txt in let md = Env.find_module path env in rm { mod_desc = Tmod_ident (path, lid); mod_type = md.md_type; mod_env = env; mod_attributes = smod.pmod_attributes; mod_loc = smod.pmod_loc } | _ -> type_module env smod in let mty = tmty.mod_type in (* PR#6307: expand aliases at root and submodules *) let mty = Mtype.remove_aliases env mty in (* PR#5037: clean up inferred signature to remove duplicate specs *) let mty = simplify_modtype mty in (* PR#5036: must not contain non-generalized type variables *) if not (closed_modtype mty) then raise(Error(smod.pmod_loc, env, Non_generalizable_module mty)); tmty, mty (* For Typecore *) let rec get_manifest_types = function [] -> [] | Sig_type (id, {type_params=[]; type_manifest=Some ty}, _) :: rem -> (Ident.name id, ty) :: get_manifest_types rem | _ :: rem -> get_manifest_types rem let type_package env m p nl tl = (* Same as Pexp_letmodule *) (* remember original level *) let lv = Ctype.get_current_level () in Ctype.begin_def (); Ident.set_current_time lv; let context = Typetexp.narrow () in let modl = type_module env m in Ctype.init_def(Ident.current_time()); Typetexp.widen context; let (mp, env) = match modl.mod_desc with Tmod_ident (mp,_) -> (mp, env) | _ -> let (id, new_env) = Env.enter_module ~arg:true "%M" modl.mod_type env in (Pident id, new_env) in let rec mkpath mp = function | Lident name -> Pdot(mp, name, nopos) | Ldot (m, name) -> Pdot(mkpath mp m, name, nopos) | _ -> assert false in let tl' = List.map (fun name -> Btype.newgenty (Tconstr (mkpath mp name,[],ref Mnil))) nl in (* go back to original level *) Ctype.end_def (); if nl = [] then (wrap_constraint env modl (Mty_ident p) Tmodtype_implicit, []) else let mty = modtype_of_package env modl.mod_loc p nl tl' in List.iter2 (fun n ty -> try Ctype.unify env ty (Ctype.newvar ()) with Ctype.Unify _ -> raise (Error(m.pmod_loc, env, Scoping_pack (n,ty)))) nl tl'; (wrap_constraint env modl mty Tmodtype_implicit, tl') (* Fill in the forward declarations *) let () = Typecore.type_module := type_module; Typetexp.transl_modtype_longident := transl_modtype_longident; Typetexp.transl_modtype := transl_modtype; Typecore.type_open := type_open_ ?toplevel:None; Typecore.type_package := type_package; type_module_type_of_fwd := type_module_type_of (* Typecheck an implementation file *) let type_implementation sourcefile outputprefix modulename initial_env ast = Cmt_format.clear (); try Typecore.reset_delayed_checks (); Env.reset_required_globals (); let (str, sg, finalenv) = type_structure initial_env ast (Location.in_file sourcefile) in let simple_sg = simplify_signature sg in if !Clflags.print_types then begin Printtyp.wrap_printing_env initial_env (fun () -> fprintf std_formatter "%a@." Printtyp.signature simple_sg); (str, Tcoerce_none) (* result is ignored by Compile.implementation *) end else begin let sourceintf = Misc.chop_extension_if_any sourcefile ^ !Config.interface_suffix in if Sys.file_exists sourceintf then begin let intf_file = try find_in_path_uncap !Config.load_path (modulename ^ ".cmi") with Not_found -> raise(Error(Location.in_file sourcefile, Env.empty, Interface_not_compiled sourceintf)) in let dclsig = Env.read_signature modulename intf_file in let coercion = Includemod.compunit initial_env sourcefile sg intf_file dclsig in Typecore.force_delayed_checks (); (* It is important to run these checks after the inclusion test above, so that value declarations which are not used internally but exported are not reported as being unused. *) Cmt_format.save_cmt (outputprefix ^ ".cmt") modulename (Cmt_format.Implementation str) (Some sourcefile) initial_env None; (str, coercion) end else begin check_nongen_schemes finalenv str.str_items; normalize_signature finalenv simple_sg; let coercion = Includemod.compunit initial_env sourcefile sg "(inferred signature)" simple_sg in Typecore.force_delayed_checks (); (* See comment above. Here the target signature contains all the value being exported. We can still capture unused declarations like "let x = true;; let x = 1;;", because in this case, the inferred signature contains only the last declaration. *) if not !Clflags.dont_write_files then begin let sg = Env.save_signature simple_sg modulename (outputprefix ^ ".cmi") in Cmt_format.save_cmt (outputprefix ^ ".cmt") modulename (Cmt_format.Implementation str) (Some sourcefile) initial_env (Some sg); end; (str, coercion) end end with e -> Cmt_format.save_cmt (outputprefix ^ ".cmt") modulename (Cmt_format.Partial_implementation (Array.of_list (Cmt_format.get_saved_types ()))) (Some sourcefile) initial_env None; raise e let save_signature modname tsg outputprefix source_file initial_env cmi = Cmt_format.save_cmt (outputprefix ^ ".cmti") modname (Cmt_format.Interface tsg) (Some source_file) initial_env (Some cmi) (* "Packaging" of several compilation units into one unit having them as sub-modules. *) let rec package_signatures subst = function [] -> [] | (name, sg) :: rem -> let sg' = Subst.signature subst sg in let oldid = Ident.create_persistent name and newid = Ident.create name in Sig_module(newid, {md_type=Mty_signature sg'; md_attributes=[]; md_loc=Location.none; }, Trec_not) :: package_signatures (Subst.add_module oldid (Pident newid) subst) rem let package_units initial_env objfiles cmifile modulename = (* Read the signatures of the units *) let units = List.map (fun f -> let pref = chop_extensions f in let modname = String.capitalize(Filename.basename pref) in let sg = Env.read_signature modname (pref ^ ".cmi") in if Filename.check_suffix f ".cmi" && not(Mtype.no_code_needed_sig Env.initial_safe_string sg) then raise(Error(Location.none, Env.empty, Implementation_is_required f)); (modname, Env.read_signature modname (pref ^ ".cmi"))) objfiles in (* Compute signature of packaged unit *) Ident.reinit(); let sg = package_signatures Subst.identity units in (* See if explicit interface is provided *) let prefix = chop_extension_if_any cmifile in let mlifile = prefix ^ !Config.interface_suffix in if Sys.file_exists mlifile then begin if not (Sys.file_exists cmifile) then begin raise(Error(Location.in_file mlifile, Env.empty, Interface_not_compiled mlifile)) end; let dclsig = Env.read_signature modulename cmifile in Cmt_format.save_cmt (prefix ^ ".cmt") modulename (Cmt_format.Packed (sg, objfiles)) None initial_env None ; Includemod.compunit initial_env "(obtained by packing)" sg mlifile dclsig end else begin (* Determine imports *) let unit_names = List.map fst units in let imports = List.filter (fun (name, crc) -> not (List.mem name unit_names)) (Env.imported_units()) in (* Write packaged signature *) if not !Clflags.dont_write_files then begin let sg = Env.save_signature_with_imports sg modulename (prefix ^ ".cmi") imports in Cmt_format.save_cmt (prefix ^ ".cmt") modulename (Cmt_format.Packed (sg, objfiles)) None initial_env (Some sg) end; Tcoerce_none end (* Error report *) open Printtyp let report_error ppf = function Cannot_apply mty -> fprintf ppf "@[This module is not a functor; it has type@ %a@]" modtype mty | Not_included errs -> fprintf ppf "@[Signature mismatch:@ %a@]" Includemod.report_error errs | Cannot_eliminate_dependency mty -> fprintf ppf "@[This functor has type@ %a@ \ The parameter cannot be eliminated in the result type.@ \ Please bind the argument to a module identifier.@]" modtype mty | Signature_expected -> fprintf ppf "This module type is not a signature" | Structure_expected mty -> fprintf ppf "@[This module is not a structure; it has type@ %a" modtype mty | With_no_component lid -> fprintf ppf "@[The signature constrained by `with' has no component named %a@]" longident lid | With_mismatch(lid, explanation) -> fprintf ppf "@[\ @[In this `with' constraint, the new definition of %a@ \ does not match its original definition@ \ in the constrained signature:@]@ \ %a@]" longident lid Includemod.report_error explanation | Repeated_name(kind, name) -> fprintf ppf "@[Multiple definition of the %s name %s.@ \ Names must be unique in a given structure or signature.@]" kind name | Non_generalizable typ -> fprintf ppf "@[The type of this expression,@ %a,@ \ contains type variables that cannot be generalized@]" type_scheme typ | Non_generalizable_class (id, desc) -> fprintf ppf "@[The type of this class,@ %a,@ \ contains type variables that cannot be generalized@]" (class_declaration id) desc | Non_generalizable_module mty -> fprintf ppf "@[The type of this module,@ %a,@ \ contains type variables that cannot be generalized@]" modtype mty | Implementation_is_required intf_name -> fprintf ppf "@[The interface %a@ declares values, not just types.@ \ An implementation must be provided.@]" Location.print_filename intf_name | Interface_not_compiled intf_name -> fprintf ppf "@[Could not find the .cmi file for interface@ %a.@]" Location.print_filename intf_name | Not_allowed_in_functor_body -> fprintf ppf "@[This expression creates fresh types.@ %s@]" "It is not allowed inside applicative functors." | With_need_typeconstr -> fprintf ppf "Only type constructors with identical parameters can be substituted." | Not_a_packed_module ty -> fprintf ppf "This expression is not a packed module. It has type@ %a" type_expr ty | Incomplete_packed_module ty -> fprintf ppf "The type of this packed module contains variables:@ %a" type_expr ty | Scoping_pack (lid, ty) -> fprintf ppf "The type %a in this module cannot be exported.@ " longident lid; fprintf ppf "Its type contains local dependencies:@ %a" type_expr ty | Extension s -> fprintf ppf "Uninterpreted extension '%s'." s | Recursive_module_require_explicit_type -> fprintf ppf "Recursive modules require an explicit module type." | Apply_generative -> fprintf ppf "This is a generative functor. It can only be applied to ()" let report_error env ppf err = Printtyp.wrap_printing_env env (fun () -> report_error ppf err) let () = Location.register_error_of_exn (function | Error (loc, env, err) -> Some (Location.error_of_printer loc (report_error env) err) | _ -> None )