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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2015 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
open Pp
open Errors
open Util
open Names
open Declarations
open Entries
open Libnames
open Libobject
open Mod_subst
open Vernacexpr
open Misctypes
(** {6 Inlining levels} *)
let default_inline () = Some (Flags.get_inline_level ())
let inl2intopt = function
| NoInline -> None
| InlineAt i -> Some i
| DefaultInline -> default_inline ()
(** {6 Substitutive objects}
- The list of bound identifiers is nonempty only if the objects
are owned by a functor
- Then comes either the object segment itself (for interactive
modules), or a compact way to store derived objects (path to
a earlier module + subtitution).
*)
type algebraic_objects =
| Objs of Lib.lib_objects
| Ref of module_path * substitution
type substitutive_objects = MBId.t list * algebraic_objects
(** ModSubstObjs : a cache of module substitutive objects
This table is common to modules and module types.
- For a Module M:=N, the objects of N will be reloaded
with M after substitution.
- For a Module M:SIG:=..., the module M gets its objects from SIG
Invariants:
- A alias (i.e. a module path inside a Ref constructor) should
never lead to another alias, but rather to a concrete Objs
constructor.
We will plug later a handler dealing with missing entries in the
cache. Such missing entries may come from inner parts of module
types, which aren't registered by the standard libobject machinery.
*)
module ModSubstObjs :
sig
val set : module_path -> substitutive_objects -> unit
val get : module_path -> substitutive_objects
val set_missing_handler : (module_path -> substitutive_objects) -> unit
end =
struct
let table =
Summary.ref (MPmap.empty : substitutive_objects MPmap.t)
~name:"MODULE-SUBSTOBJS"
let missing_handler = ref (fun mp -> assert false)
let set_missing_handler f = (missing_handler := f)
let set mp objs = (table := MPmap.add mp objs !table)
let get mp =
try MPmap.find mp !table with Not_found -> !missing_handler mp
end
(** Some utilities about substitutive objects :
substitution, expansion *)
let sobjs_no_functor (mbids,_) = List.is_empty mbids
let subst_aobjs sub = function
| Objs o -> Objs (Lib.subst_objects sub o)
| Ref (mp, sub0) -> Ref (mp, join sub0 sub)
let subst_sobjs sub (mbids,aobjs) = (mbids, subst_aobjs sub aobjs)
let expand_aobjs = function
| Objs o -> o
| Ref (mp, sub) ->
match ModSubstObjs.get mp with
| (_,Objs o) -> Lib.subst_objects sub o
| _ -> assert false (* Invariant : any alias points to concrete objs *)
let expand_sobjs (_,aobjs) = expand_aobjs aobjs
(** {6 ModObjs : a cache of module objects}
For each module, we also store a cache of
"prefix", "substituted objects", "keep objects".
This is used for instance to implement the "Import" command.
substituted objects :
roughly the objects above after the substitution - we need to
keep them to call open_object when the module is opened (imported)
keep objects :
The list of non-substitutive objects - as above, for each of
them we will call open_object when the module is opened
(Some) Invariants:
* If the module is a functor, it won't appear in this cache.
* Module objects in substitutive_objects part have empty substituted
objects.
* Modules which where created with Module M:=mexpr or with
Module M:SIG. ... End M. have the keep list empty.
*)
type module_objects = object_prefix * Lib.lib_objects * Lib.lib_objects
module ModObjs :
sig
val set : module_path -> module_objects -> unit
val get : module_path -> module_objects (* may raise Not_found *)
val all : unit -> module_objects MPmap.t
end =
struct
let table =
Summary.ref (MPmap.empty : module_objects MPmap.t)
~name:"MODULE-OBJS"
let set mp objs = (table := MPmap.add mp objs !table)
let get mp = MPmap.find mp !table
let all () = !table
end
(** {6 Name management}
Auxiliary functions to transform full_path and kernel_name given
by Lib into module_path and DirPath.t needed for modules
*)
let mp_of_kn kn =
let mp,sec,l = repr_kn kn in
assert (DirPath.is_empty sec);
MPdot (mp,l)
let dir_of_sp sp =
let dir,id = repr_path sp in
add_dirpath_suffix dir id
(** {6 Declaration of module substitutive objects} *)
(** These functions register the visibility of the module and iterates
through its components. They are called by plenty of module functions *)
let consistency_checks exists dir dirinfo =
if exists then
let globref =
try Nametab.locate_dir (qualid_of_dirpath dir)
with Not_found ->
anomaly (pr_dirpath dir ++ str " should already exist!")
in
assert (eq_global_dir_reference globref dirinfo)
else
if Nametab.exists_dir dir then
anomaly (pr_dirpath dir ++ str " already exists")
let compute_visibility exists i =
if exists then Nametab.Exactly i else Nametab.Until i
(** Iterate some function [iter_objects] on all components of a module *)
let do_module exists iter_objects i dir mp sobjs kobjs =
let prefix = (dir,(mp,DirPath.empty)) in
let dirinfo = DirModule prefix in
consistency_checks exists dir dirinfo;
Nametab.push_dir (compute_visibility exists i) dir dirinfo;
ModSubstObjs.set mp sobjs;
(* If we're not a functor, let's iter on the internal components *)
if sobjs_no_functor sobjs then begin
let objs = expand_sobjs sobjs in
ModObjs.set mp (prefix,objs,kobjs);
iter_objects (i+1) prefix objs;
iter_objects (i+1) prefix kobjs
end
let do_module' exists iter_objects i ((sp,kn),sobjs) =
do_module exists iter_objects i (dir_of_sp sp) (mp_of_kn kn) sobjs []
(** Nota: Interactive modules and module types cannot be recached!
This used to be checked here via a flag along the substobjs. *)
let cache_module = do_module' false Lib.load_objects 1
let load_module = do_module' false Lib.load_objects
let open_module = do_module' true Lib.open_objects
let subst_module (subst,sobjs) = subst_sobjs subst sobjs
let classify_module sobjs = Substitute sobjs
let (in_module : substitutive_objects -> obj),
(out_module : obj -> substitutive_objects) =
declare_object_full {(default_object "MODULE") with
cache_function = cache_module;
load_function = load_module;
open_function = open_module;
subst_function = subst_module;
classify_function = classify_module }
(** {6 Declaration of module keep objects} *)
let cache_keep _ = anomaly (Pp.str "This module should not be cached!")
let load_keep i ((sp,kn),kobjs) =
(* Invariant : seg isn't empty *)
let dir = dir_of_sp sp and mp = mp_of_kn kn in
let prefix = (dir,(mp,DirPath.empty)) in
let prefix',sobjs,kobjs0 =
try ModObjs.get mp
with Not_found -> assert false (* a substobjs should already be loaded *)
in
assert (eq_op prefix' prefix);
assert (List.is_empty kobjs0);
ModObjs.set mp (prefix,sobjs,kobjs);
Lib.load_objects i prefix kobjs
let open_keep i ((sp,kn),kobjs) =
let dir = dir_of_sp sp and mp = mp_of_kn kn in
let prefix = (dir,(mp,DirPath.empty)) in
Lib.open_objects i prefix kobjs
let in_modkeep : Lib.lib_objects -> obj =
declare_object {(default_object "MODULE KEEP") with
cache_function = cache_keep;
load_function = load_keep;
open_function = open_keep }
(** {6 Declaration of module type substitutive objects} *)
(** Nota: Interactive modules and module types cannot be recached!
This used to be checked more properly here. *)
let do_modtype i sp mp sobjs =
if Nametab.exists_modtype sp then
anomaly (pr_path sp ++ str " already exists");
Nametab.push_modtype (Nametab.Until i) sp mp;
ModSubstObjs.set mp sobjs
let cache_modtype ((sp,kn),sobjs) = do_modtype 1 sp (mp_of_kn kn) sobjs
let load_modtype i ((sp,kn),sobjs) = do_modtype i sp (mp_of_kn kn) sobjs
let subst_modtype (subst,sobjs) = subst_sobjs subst sobjs
let classify_modtype sobjs = Substitute sobjs
let open_modtype i ((sp,kn),_) =
let mp = mp_of_kn kn in
let mp' =
try Nametab.locate_modtype (qualid_of_path sp)
with Not_found ->
anomaly (pr_path sp ++ str " should already exist!");
in
assert (ModPath.equal mp mp');
Nametab.push_modtype (Nametab.Exactly i) sp mp
let (in_modtype : substitutive_objects -> obj),
(out_modtype : obj -> substitutive_objects) =
declare_object_full {(default_object "MODULE TYPE") with
cache_function = cache_modtype;
open_function = open_modtype;
load_function = load_modtype;
subst_function = subst_modtype;
classify_function = classify_modtype }
(** {6 Declaration of substitutive objects for Include} *)
let do_include do_load do_open i ((sp,kn),aobjs) =
let dir = Libnames.dirpath sp in
let mp = KerName.modpath kn in
let prefix = (dir,(mp,DirPath.empty)) in
let o = expand_aobjs aobjs in
if do_load then Lib.load_objects i prefix o;
if do_open then Lib.open_objects i prefix o
let cache_include = do_include true true 1
let load_include = do_include true false
let open_include = do_include false true
let subst_include (subst,aobjs) = subst_aobjs subst aobjs
let classify_include aobjs = Substitute aobjs
let (in_include : algebraic_objects -> obj),
(out_include : obj -> algebraic_objects) =
declare_object_full {(default_object "INCLUDE") with
cache_function = cache_include;
load_function = load_include;
open_function = open_include;
subst_function = subst_include;
classify_function = classify_include }
(** {6 Handler for missing entries in ModSubstObjs} *)
(** Since the inner of Module Types are not added by default to
the ModSubstObjs table, we compensate this by explicit traversal
of Module Types inner objects when needed. Quite a hack... *)
let mp_id mp id = MPdot (mp, Label.of_id id)
let rec register_mod_objs mp (id,obj) = match object_tag obj with
| "MODULE" -> ModSubstObjs.set (mp_id mp id) (out_module obj)
| "MODULE TYPE" -> ModSubstObjs.set (mp_id mp id) (out_modtype obj)
| "INCLUDE" ->
List.iter (register_mod_objs mp) (expand_aobjs (out_include obj))
| _ -> ()
let handle_missing_substobjs mp = match mp with
| MPdot (mp',l) ->
let objs = expand_sobjs (ModSubstObjs.get mp') in
List.iter (register_mod_objs mp') objs;
ModSubstObjs.get mp
| _ ->
assert false (* Only inner parts of module types should be missing *)
let () = ModSubstObjs.set_missing_handler handle_missing_substobjs
(** {6 From module expression to substitutive objects} *)
(** Turn a chain of [MSEapply] into the head module_path and the
list of module_path parameters (deepest param coming first).
The left part of a [MSEapply] must be either [MSEident] or
another [MSEapply]. *)
let get_applications mexpr =
let rec get params = function
| MEident mp -> mp, params
| MEapply (fexpr, mp) -> get (mp::params) fexpr
| MEwith _ -> error "Non-atomic functor application."
in get [] mexpr
(** Create the substitution corresponding to some functor applications *)
let rec compute_subst env mbids sign mp_l inl =
match mbids,mp_l with
| _,[] -> mbids,empty_subst
| [],r -> error "Application of a functor with too few arguments."
| mbid::mbids,mp::mp_l ->
let farg_id, farg_b, fbody_b = Modops.destr_functor sign in
let mb = Environ.lookup_module mp env in
let mbid_left,subst = compute_subst env mbids fbody_b mp_l inl in
let resolver =
if Modops.is_functor mb.mod_type then empty_delta_resolver
else
Modops.inline_delta_resolver env inl mp farg_id farg_b mb.mod_delta
in
mbid_left,join (map_mbid mbid mp resolver) subst
(** Create the objects of a "with Module" structure. *)
let rec replace_module_object idl mp0 objs0 mp1 objs1 =
match idl, objs0 with
| _,[] -> []
| id::idl,(id',obj)::tail when Id.equal id id' ->
assert (object_has_tag obj "MODULE");
let mp_id = MPdot(mp0, Label.of_id id) in
let objs = match idl with
| [] -> Lib.subst_objects (map_mp mp1 mp_id empty_delta_resolver) objs1
| _ ->
let objs_id = expand_sobjs (out_module obj) in
replace_module_object idl mp_id objs_id mp1 objs1
in
(id, in_module ([], Objs objs))::tail
| idl,lobj::tail -> lobj::replace_module_object idl mp0 tail mp1 objs1
let type_of_mod mp env = function
|true -> (Environ.lookup_module mp env).mod_type
|false -> (Environ.lookup_modtype mp env).mod_type
let rec get_module_path = function
|MEident mp -> mp
|MEwith (me,_) -> get_module_path me
|MEapply (me,_) -> get_module_path me
(** Substitutive objects of a module expression (or module type) *)
let rec get_module_sobjs is_mod env inl = function
|MEident mp ->
begin match ModSubstObjs.get mp with
|(mbids,Objs _) when not (ModPath.is_bound mp) ->
(mbids,Ref (mp, empty_subst)) (* we create an alias *)
|sobjs -> sobjs
end
|MEwith (mty, WithDef _) -> get_module_sobjs is_mod env inl mty
|MEwith (mty, WithMod (idl,mp1)) ->
assert (not is_mod);
let sobjs0 = get_module_sobjs is_mod env inl mty in
assert (sobjs_no_functor sobjs0);
(* For now, we expanse everything, to be safe *)
let mp0 = get_module_path mty in
let objs0 = expand_sobjs sobjs0 in
let objs1 = expand_sobjs (ModSubstObjs.get mp1) in
([], Objs (replace_module_object idl mp0 objs0 mp1 objs1))
|MEapply _ as me ->
let mp1, mp_l = get_applications me in
let mbids, aobjs = get_module_sobjs is_mod env inl (MEident mp1) in
let typ = type_of_mod mp1 env is_mod in
let mbids_left,subst = compute_subst env mbids typ mp_l inl in
(mbids_left, subst_aobjs subst aobjs)
let get_functor_sobjs is_mod env inl (params,mexpr) =
let (mbids, aobjs) = get_module_sobjs is_mod env inl mexpr in
(List.map fst params @ mbids, aobjs)
(** {6 Handling of module parameters} *)
(** For printing modules, [process_module_binding] adds names of
bound module (and its components) to Nametab. It also loads
objects associated to it. *)
let process_module_binding mbid me =
let dir = DirPath.make [MBId.to_id mbid] in
let mp = MPbound mbid in
let sobjs = get_module_sobjs false (Global.env()) (default_inline ()) me in
let subst = map_mp (get_module_path me) mp empty_delta_resolver in
let sobjs = subst_sobjs subst sobjs in
do_module false Lib.load_objects 1 dir mp sobjs []
(** Process a declaration of functor parameter(s) (Id1 .. Idn : Typ)
i.e. possibly multiple names with the same module type.
Global environment is updated on the fly.
Objects in these parameters are also loaded.
Output is accumulated on top of [acc] (in reverse order). *)
let intern_arg interp_modast acc (idl,(typ,ann)) =
let inl = inl2intopt ann in
let lib_dir = Lib.library_dp() in
let env = Global.env() in
let mty,_ = interp_modast env ModType typ in
let sobjs = get_module_sobjs false env inl mty in
let mp0 = get_module_path mty in
List.fold_left
(fun acc (_,id) ->
let dir = DirPath.make [id] in
let mbid = MBId.make lib_dir id in
let mp = MPbound mbid in
let resolver = Global.add_module_parameter mbid mty inl in
let sobjs = subst_sobjs (map_mp mp0 mp resolver) sobjs in
do_module false Lib.load_objects 1 dir mp sobjs [];
(mbid,mty,inl)::acc)
acc idl
(** Process a list of declarations of functor parameters
(Id11 .. Id1n : Typ1)..(Idk1 .. Idkm : Typk)
Global environment is updated on the fly.
The calls to [interp_modast] should be interleaved with these
env updates, otherwise some "with Definition" could be rejected.
Returns a list of mbids and entries (in reversed order).
This used to be a [List.concat (List.map ...)], but this should
be more efficient and independent of [List.map] eval order.
*)
let intern_args interp_modast params =
List.fold_left (intern_arg interp_modast) [] params
(** {6 Auxiliary functions concerning subtyping checks} *)
let check_sub mtb sub_mtb_l =
(* The constraints are checked and forgot immediately : *)
ignore (List.fold_right
(fun sub_mtb env ->
Environ.add_constraints
(Subtyping.check_subtypes env mtb sub_mtb) env)
sub_mtb_l (Global.env()))
(** This function checks if the type calculated for the module [mp] is
a subtype of all signatures in [sub_mtb_l]. Uses only the global
environment. *)
let check_subtypes mp sub_mtb_l =
let mb =
try Global.lookup_module mp with Not_found -> assert false
in
let mtb = Modops.module_type_of_module mb in
check_sub mtb sub_mtb_l
(** Same for module type [mp] *)
let check_subtypes_mt mp sub_mtb_l =
let mtb =
try Global.lookup_modtype mp with Not_found -> assert false
in
check_sub mtb sub_mtb_l
(** Create a params entry.
In [args], the youngest module param now comes first. *)
let mk_params_entry args =
List.rev_map (fun (mbid,arg_t,_) -> (mbid,arg_t)) args
(** Create a functor type struct.
In [args], the youngest module param now comes first. *)
let mk_funct_type env args seb0 =
List.fold_left
(fun seb (arg_id,arg_t,arg_inl) ->
let mp = MPbound arg_id in
let arg_t = Mod_typing.translate_modtype env mp arg_inl ([],arg_t) in
MoreFunctor(arg_id,arg_t,seb))
seb0 args
(** Prepare the module type list for check of subtypes *)
let build_subtypes interp_modast env mp args mtys =
List.map
(fun (m,ann) ->
let inl = inl2intopt ann in
let mte,_ = interp_modast env ModType m in
let mtb = Mod_typing.translate_modtype env mp inl ([],mte) in
{ mtb with mod_type = mk_funct_type env args mtb.mod_type })
mtys
(** {6 Current module information}
This information is stored by each [start_module] for use
in a later [end_module]. *)
type current_module_info = {
cur_typ : (module_struct_entry * int option) option; (** type via ":" *)
cur_typs : module_type_body list (** types via "<:" *)
}
let default_module_info = { cur_typ = None; cur_typs = [] }
let openmod_info = Summary.ref default_module_info ~name:"MODULE-INFO"
(** {6 Current module type information}
This information is stored by each [start_modtype] for use
in a later [end_modtype]. *)
let openmodtype_info =
Summary.ref ([] : module_type_body list) ~name:"MODTYPE-INFO"
(** {6 Modules : start, end, declare} *)
module RawModOps = struct
let start_module interp_modast export id args res fs =
let mp = Global.start_module id in
let arg_entries_r = intern_args interp_modast args in
let env = Global.env () in
let res_entry_o, subtyps = match res with
| Enforce (res,ann) ->
let inl = inl2intopt ann in
let mte,_ = interp_modast env ModType res in
(* We check immediately that mte is well-formed *)
let _ = Mod_typing.translate_mse env None inl mte in
Some (mte,inl), []
| Check resl ->
None, build_subtypes interp_modast env mp arg_entries_r resl
in
openmod_info := { cur_typ = res_entry_o; cur_typs = subtyps };
let prefix = Lib.start_module export id mp fs in
Nametab.push_dir (Nametab.Until 1) (fst prefix) (DirOpenModule prefix);
Lib.add_frozen_state (); mp
let end_module () =
let oldoname,oldprefix,fs,lib_stack = Lib.end_module () in
let substitute, keep, special = Lib.classify_segment lib_stack in
let m_info = !openmod_info in
(* For sealed modules, we use the substitutive objects of their signatures *)
let sobjs0, keep, special = match m_info.cur_typ with
| None -> ([], Objs substitute), keep, special
| Some (mty, inline) ->
get_module_sobjs false (Global.env()) inline mty, [], []
in
let id = basename (fst oldoname) in
let mp,mbids,resolver = Global.end_module fs id m_info.cur_typ in
let sobjs = let (ms,objs) = sobjs0 in (mbids@ms,objs) in
check_subtypes mp m_info.cur_typs;
(* We substitute objects if the module is sealed by a signature *)
let sobjs =
match m_info.cur_typ with
| None -> sobjs
| Some (mty, _) ->
subst_sobjs (map_mp (get_module_path mty) mp resolver) sobjs
in
let node = in_module sobjs in
(* We add the keep objects, if any, and if this isn't a functor *)
let objects = match keep, mbids with
| [], _ | _, _ :: _ -> special@[node]
| _ -> special@[node;in_modkeep keep]
in
let newoname = Lib.add_leaves id objects in
(* Name consistency check : start_ vs. end_module, kernel vs. library *)
assert (eq_full_path (fst newoname) (fst oldoname));
assert (ModPath.equal (mp_of_kn (snd newoname)) mp);
Lib.add_frozen_state () (* to prevent recaching *);
mp
let declare_module interp_modast id args res mexpr_o fs =
(* We simulate the beginning of an interactive module,
then we adds the module parameters to the global env. *)
let mp = Global.start_module id in
let arg_entries_r = intern_args interp_modast args in
let params = mk_params_entry arg_entries_r in
let env = Global.env () in
let mty_entry_o, subs, inl_res = match res with
| Enforce (mty,ann) ->
Some (fst (interp_modast env ModType mty)), [], inl2intopt ann
| Check mtys ->
None, build_subtypes interp_modast env mp arg_entries_r mtys,
default_inline ()
in
let mexpr_entry_o, inl_expr = match mexpr_o with
| None -> None, default_inline ()
| Some (mexpr,ann) ->
Some (fst (interp_modast env Module mexpr)), inl2intopt ann
in
let entry = match mexpr_entry_o, mty_entry_o with
| None, None -> assert false (* No body, no type ... *)
| None, Some typ -> MType (params, typ)
| Some body, otyp -> MExpr (params, body, otyp)
in
let sobjs, mp0 = match entry with
| MType (_,mte) | MExpr (_,_,Some mte) ->
get_functor_sobjs false env inl_res (params,mte), get_module_path mte
| MExpr (_,me,None) ->
get_functor_sobjs true env inl_expr (params,me), get_module_path me
in
(* Undo the simulated interactive building of the module
and declare the module as a whole *)
Summary.unfreeze_summaries fs;
let inl = match inl_expr with
| None -> None
| _ -> inl_res
in
let mp_env,resolver = Global.add_module id entry inl in
(* Name consistency check : kernel vs. library *)
assert (ModPath.equal mp (mp_of_kn (Lib.make_kn id)));
assert (ModPath.equal mp mp_env);
check_subtypes mp subs;
let sobjs = subst_sobjs (map_mp mp0 mp resolver) sobjs in
ignore (Lib.add_leaf id (in_module sobjs));
mp
end
(** {6 Module types : start, end, declare} *)
module RawModTypeOps = struct
let start_modtype interp_modast id args mtys fs =
let mp = Global.start_modtype id in
let arg_entries_r = intern_args interp_modast args in
let env = Global.env () in
let sub_mty_l = build_subtypes interp_modast env mp arg_entries_r mtys in
openmodtype_info := sub_mty_l;
let prefix = Lib.start_modtype id mp fs in
Nametab.push_dir (Nametab.Until 1) (fst prefix) (DirOpenModtype prefix);
Lib.add_frozen_state (); mp
let end_modtype () =
let oldoname,prefix,fs,lib_stack = Lib.end_modtype () in
let id = basename (fst oldoname) in
let substitute, _, special = Lib.classify_segment lib_stack in
let sub_mty_l = !openmodtype_info in
let mp, mbids = Global.end_modtype fs id in
let modtypeobjs = (mbids, Objs substitute) in
check_subtypes_mt mp sub_mty_l;
let oname = Lib.add_leaves id (special@[in_modtype modtypeobjs])
in
(* Check name consistence : start_ vs. end_modtype, kernel vs. library *)
assert (eq_full_path (fst oname) (fst oldoname));
assert (ModPath.equal (mp_of_kn (snd oname)) mp);
Lib.add_frozen_state ()(* to prevent recaching *);
mp
let declare_modtype interp_modast id args mtys (mty,ann) fs =
let inl = inl2intopt ann in
(* We simulate the beginning of an interactive module,
then we adds the module parameters to the global env. *)
let mp = Global.start_modtype id in
let arg_entries_r = intern_args interp_modast args in
let params = mk_params_entry arg_entries_r in
let env = Global.env () in
let entry = params, fst (interp_modast env ModType mty) in
let sub_mty_l = build_subtypes interp_modast env mp arg_entries_r mtys in
let sobjs = get_functor_sobjs false env inl entry in
let subst = map_mp (get_module_path (snd entry)) mp empty_delta_resolver in
let sobjs = subst_sobjs subst sobjs in
(* Undo the simulated interactive building of the module type
and declare the module type as a whole *)
Summary.unfreeze_summaries fs;
(* We enrich the global environment *)
let mp_env = Global.add_modtype id entry inl in
(* Name consistency check : kernel vs. library *)
assert (ModPath.equal mp_env mp);
(* Subtyping checks *)
check_subtypes_mt mp sub_mty_l;
ignore (Lib.add_leaf id (in_modtype sobjs));
mp
end
(** {6 Include} *)
module RawIncludeOps = struct
let rec include_subst env mp reso mbids sign inline = match mbids with
| [] -> empty_subst
| mbid::mbids ->
let farg_id, farg_b, fbody_b = Modops.destr_functor sign in
let subst = include_subst env mp reso mbids fbody_b inline in
let mp_delta =
Modops.inline_delta_resolver env inline mp farg_id farg_b reso
in
join (map_mbid mbid mp mp_delta) subst
let rec decompose_functor mpl typ =
match mpl, typ with
| [], _ -> typ
| _::mpl, MoreFunctor(_,_,str) -> decompose_functor mpl str
| _ -> error "Application of a functor with too much arguments."
exception NoIncludeSelf
let type_of_incl env is_mod = function
|MEident mp -> type_of_mod mp env is_mod
|MEapply _ as me ->
let mp0, mp_l = get_applications me in
decompose_functor mp_l (type_of_mod mp0 env is_mod)
|MEwith _ -> raise NoIncludeSelf
let declare_one_include interp_modast (me_ast,annot) =
let env = Global.env() in
let me,kind = interp_modast env ModAny me_ast in
let is_mod = (kind == Module) in
let cur_mp = Lib.current_mp () in
let inl = inl2intopt annot in
let mbids,aobjs = get_module_sobjs is_mod env inl me in
let subst_self =
try
if List.is_empty mbids then raise NoIncludeSelf;
let typ = type_of_incl env is_mod me in
let reso,_ = Safe_typing.delta_of_senv (Global.safe_env ()) in
include_subst env cur_mp reso mbids typ inl
with NoIncludeSelf -> empty_subst
in
let base_mp = get_module_path me in
let resolver = Global.add_include me is_mod inl in
let subst = join subst_self (map_mp base_mp cur_mp resolver) in
let aobjs = subst_aobjs subst aobjs in
ignore (Lib.add_leaf (Lib.current_mod_id ()) (in_include aobjs))
let declare_include interp me_asts =
List.iter (declare_one_include interp) me_asts
end
(** {6 Module operations handling summary freeze/unfreeze} *)
let protect_summaries f =
let fs = Summary.freeze_summaries ~marshallable:`No in
try f fs
with reraise ->
(* Something wrong: undo the whole process *)
let reraise = Errors.push reraise in
let () = Summary.unfreeze_summaries fs in
iraise reraise
let start_module interp export id args res =
protect_summaries (RawModOps.start_module interp export id args res)
let end_module = RawModOps.end_module
let declare_module interp id args mtys me_l =
let declare_me fs = match me_l with
| [] -> RawModOps.declare_module interp id args mtys None fs
| [me] -> RawModOps.declare_module interp id args mtys (Some me) fs
| me_l ->
ignore (RawModOps.start_module interp None id args mtys fs);
RawIncludeOps.declare_include interp me_l;
RawModOps.end_module ()
in
protect_summaries declare_me
let start_modtype interp id args mtys =
protect_summaries (RawModTypeOps.start_modtype interp id args mtys)
let end_modtype = RawModTypeOps.end_modtype
let declare_modtype interp id args mtys mty_l =
let declare_mt fs = match mty_l with
| [] -> assert false
| [mty] -> RawModTypeOps.declare_modtype interp id args mtys mty fs
| mty_l ->
ignore (RawModTypeOps.start_modtype interp id args mtys fs);
RawIncludeOps.declare_include interp mty_l;
RawModTypeOps.end_modtype ()
in
protect_summaries declare_mt
let declare_include interp me_asts =
protect_summaries (fun _ -> RawIncludeOps.declare_include interp me_asts)
(** {6 Libraries} *)
type library_name = DirPath.t
(** A library object is made of some substitutive objects
and some "keep" objects. *)
type library_objects = Lib.lib_objects * Lib.lib_objects
(** For the native compiler, we cache the library values *)
type library_values = Nativecode.symbol array
let library_values =
Summary.ref (Dirmap.empty : library_values Dirmap.t) ~name:"LIBVALUES"
let register_library dir cenv (objs:library_objects) digest univ =
assert (not (Lib.is_module_or_modtype ()));
let mp = MPfile dir in
let () =
try
(* Is this library already loaded ? *)
ignore(Global.lookup_module mp);
with Not_found ->
(* If not, let's do it now ... *)
let mp', values = Global.import cenv univ digest in
if not (ModPath.equal mp mp') then
anomaly (Pp.str "Unexpected disk module name");
library_values := Dirmap.add dir values !library_values
in
let sobjs,keepobjs = objs in
do_module false Lib.load_objects 1 dir mp ([],Objs sobjs) keepobjs
let get_library_symbols_tbl dir = Dirmap.find dir !library_values
let start_library dir =
let mp = Global.start_library dir in
openmod_info := default_module_info;
Lib.start_compilation dir mp;
Lib.add_frozen_state ()
let end_library ?except dir =
let oname = Lib.end_compilation_checks dir in
let mp,cenv,ast = Global.export ?except dir in
let prefix, lib_stack = Lib.end_compilation oname in
assert (ModPath.equal mp (MPfile dir));
let substitute, keep, _ = Lib.classify_segment lib_stack in
cenv,(substitute,keep),ast
(** {6 Implementation of Import and Export commands} *)
let really_import_module mp =
(* May raise Not_found for unknown module and for functors *)
let prefix,sobjs,keepobjs = ModObjs.get mp in
Lib.open_objects 1 prefix sobjs;
Lib.open_objects 1 prefix keepobjs
let cache_import (_,(_,mp)) = really_import_module mp
let open_import i obj =
if Int.equal i 1 then cache_import obj
let classify_import (export,_ as obj) =
if export then Substitute obj else Dispose
let subst_import (subst,(export,mp as obj)) =
let mp' = subst_mp subst mp in
if mp'==mp then obj else (export,mp')
let in_import : bool * module_path -> obj =
declare_object {(default_object "IMPORT MODULE") with
cache_function = cache_import;
open_function = open_import;
subst_function = subst_import;
classify_function = classify_import }
let import_module export mp =
Lib.add_anonymous_leaf (in_import (export,mp))
(** {6 Iterators} *)
let iter_all_segments f =
let rec apply_obj prefix (id,obj) = match object_tag obj with
| "INCLUDE" ->
let objs = expand_aobjs (out_include obj) in
List.iter (apply_obj prefix) objs
| _ -> f (make_oname prefix id) obj
in
let apply_mod_obj _ (prefix,substobjs,keepobjs) =
List.iter (apply_obj prefix) substobjs;
List.iter (apply_obj prefix) keepobjs
in
let apply_node = function
| sp, Lib.Leaf o -> f sp o
| _ -> ()
in
MPmap.iter apply_mod_obj (ModObjs.all ());
List.iter apply_node (Lib.contents ())
(** {6 Some types used to shorten declaremods.mli} *)
type 'modast module_interpretor =
Environ.env -> Misctypes.module_kind -> 'modast ->
Entries.module_struct_entry * Misctypes.module_kind
type 'modast module_params =
(Id.t Loc.located list * ('modast * inline)) list
(** {6 Debug} *)
let debug_print_modtab _ =
let pr_seg = function
| [] -> str "[]"
| l -> str ("[." ^ string_of_int (List.length l) ^ ".]")
in
let pr_modinfo mp (prefix,substobjs,keepobjs) s =
s ++ str (string_of_mp mp) ++ (spc ())
++ (pr_seg (Lib.segment_of_objects prefix (substobjs@keepobjs)))
in
let modules = MPmap.fold pr_modinfo (ModObjs.all ()) (mt ()) in
hov 0 modules
|