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(************************************************************************)
(*  v      *   The Coq Proof Assistant  /  The Coq Development Team     *)
(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *)
(*   \VV/  **************************************************************)
(*    //   *      This file is distributed under the terms of the       *)
(*         *       GNU Lesser General Public License Version 2.1        *)
(************************************************************************)

(* Created by Jean-Christophe Filliâtre as part of the rebuilding of
   Coq around a purely functional abstract type-checker, Dec 1999 *)

(* This file provides the entry points to the kernel type-checker. It
   defines the abstract type of well-formed environments and
   implements the rules that build well-formed environments.

   An environment is made of constants and inductive types (E), of
   section declarations (Delta), of local bound-by-index declarations
   (Gamma) and of universe constraints (C). Below E[Delta,Gamma] |-_C
   means that the tuple E, Delta, Gamma, C is a well-formed
   environment. Main rules are:

   empty_environment:

     ------
     [,] |-

   push_named_assum(a,T):
   
     E[Delta,Gamma] |-_G
     ------------------------
     E[Delta,Gamma,a:T] |-_G'

   push_named_def(a,t,T):
   
     E[Delta,Gamma] |-_G
     ---------------------------
     E[Delta,Gamma,a:=t:T] |-_G'

   add_constant(ConstantEntry(DefinitionEntry(c,t,T))):

     E[Delta,Gamma] |-_G
     ---------------------------
     E,c:=t:T[Delta,Gamma] |-_G'

   add_constant(ConstantEntry(ParameterEntry(c,T))):

     E[Delta,Gamma] |-_G
     ------------------------
     E,c:T[Delta,Gamma] |-_G'

   add_mind(Ind(Ind[Gamma_p](Gamma_I:=Gamma_C))):

     E[Delta,Gamma] |-_G
     ------------------------
     E,Ind[Gamma_p](Gamma_I:=Gamma_C)[Delta,Gamma] |-_G'

   etc.
*)

open Util
open Names
open Univ
open Term
open Reduction
open Sign
open Declarations
open Inductive
open Environ
open Entries
open Typeops
open Type_errors
open Indtypes
open Term_typing
open Modops
open Subtyping
open Mod_typing
open Mod_subst


type modvariant =
  | NONE
  | SIG of (* funsig params *) (mod_bound_id * module_type_body) list
  | STRUCT of (* functor params *) (mod_bound_id * module_type_body) list
  | LIBRARY of dir_path

type module_info =
    {modpath : module_path;
     label : label;
     variant : modvariant;
     resolver : delta_resolver;
     resolver_of_param : delta_resolver;}
      
let check_label l labset =
  if Labset.mem l labset then error_existing_label l

let set_engagement_opt oeng env =
  match oeng with
      Some eng -> set_engagement eng env
    | _ -> env

type library_info = dir_path * Digest.t

type safe_environment =
    { old : safe_environment;
      env : env;
      modinfo : module_info;
      labset : Labset.t;
      revstruct : structure_body;
      univ : Univ.constraints;
      engagement : engagement option;
      imports : library_info list;
      loads : (module_path * module_body) list;
      local_retroknowledge : Retroknowledge.action list}

(*
  { old = senv.old;
    env = ;
    modinfo = senv.modinfo;
    labset = ;
    revsign = ;
    imports = senv.imports ;
    loads = senv.loads }
*)


(* a small hack to avoid variants and an unused case in all functions *)
let rec empty_environment =
  { old = empty_environment;
    env = empty_env;
    modinfo = {
      modpath = initial_path;
      label = mk_label "_";
      variant = NONE;
      resolver = empty_delta_resolver;
      resolver_of_param = empty_delta_resolver};
    labset = Labset.empty;
    revstruct = [];
    univ = Univ.Constraint.empty;
    engagement = None;
    imports = [];
    loads = [];
    local_retroknowledge = [] }

let env_of_safe_env senv = senv.env
let env_of_senv = env_of_safe_env







let add_constraints cst senv =
  {senv with
    env = Environ.add_constraints cst senv.env;
    univ = Univ.Constraint.union cst senv.univ }


(*spiwack: functions for safe retroknowledge *)

(* terms which are closed under the environnement env, i.e
   terms which only depends on constant who are themselves closed *)
let closed env term =
  ContextObjectMap.is_empty (assumptions full_transparent_state env term)

(* the set of safe terms in an environement any recursive set of
   terms who are known not to prove inconsistent statement. It should
   include at least all the closed terms. But it could contain other ones
   like the axiom of excluded middle for instance *)
let safe =
  closed



(* universal lifting, used for the "get" operations mostly *)
let retroknowledge f senv =
  Environ.retroknowledge f (env_of_senv senv)

let register senv field value by_clause =
  (* todo : value closed, by_clause safe, by_clause of the proper type*)
  (* spiwack : updates the safe_env with the information that the register
     action has to be performed (again) when the environement is imported *)
  {senv with env = Environ.register senv.env field value;
             local_retroknowledge =
      Retroknowledge.RKRegister (field,value)::senv.local_retroknowledge
  }

(* spiwack : currently unused *)
let unregister senv field  =
  (*spiwack: todo: do things properly or delete *)
  {senv with env = Environ.unregister senv.env field}
(* /spiwack *)










(* Insertion of section variables. They are now typed before being
   added to the environment. *)

(* Same as push_named, but check that the variable is not already
   there. Should *not* be done in Environ because tactics add temporary
   hypothesis many many times, and the check performed here would
   cost too much. *)
let safe_push_named (id,_,_ as d) env =
  let _ =
    try
      let _ = lookup_named id env in
      error ("Identifier "^string_of_id id^" already defined.")
    with Not_found -> () in
  Environ.push_named d env

let push_named_def (id,b,topt) senv =
  let (c,typ,cst) = translate_local_def senv.env (b,topt) in
  let senv' = add_constraints cst senv in
  let env'' = safe_push_named (id,Some c,typ) senv'.env in
  (cst, {senv' with env=env''})

let push_named_assum (id,t) senv =
  let (t,cst) = translate_local_assum senv.env t in
  let senv' = add_constraints cst senv in
  let env'' = safe_push_named (id,None,t) senv'.env in
  (cst, {senv' with env=env''})


(* Insertion of constants and parameters in environment. *)

type global_declaration =
  | ConstantEntry of constant_entry
  | GlobalRecipe of Cooking.recipe

let hcons_constant_type = function
  | NonPolymorphicType t ->
      NonPolymorphicType (hcons1_constr t)
  | PolymorphicArity (ctx,s) ->
      PolymorphicArity (map_rel_context hcons1_constr ctx,s)

let hcons_constant_body cb =
  let body = match cb.const_body with
      None -> None
    | Some l_constr -> let constr = Declarations.force l_constr in
	Some (Declarations.from_val (hcons1_constr constr))
  in
    { cb with
	const_body = body;
	const_type = hcons_constant_type cb.const_type }

let add_constant dir l decl senv =
  check_label l senv.labset;
  let kn = make_con senv.modinfo.modpath dir l in
  let cb =
    match decl with
      | ConstantEntry ce -> translate_constant senv.env kn ce
      | GlobalRecipe r ->
	  let cb = translate_recipe senv.env kn r in
	    if dir = empty_dirpath then hcons_constant_body cb else cb
  in
  let senv' = add_constraints cb.const_constraints senv in
  let env'' = Environ.add_constant kn cb senv'.env in
  let resolver = 
    if cb.const_inline then
      add_inline_delta_resolver kn senv'.modinfo.resolver
    else
      senv'.modinfo.resolver
  in
    kn, { old = senv'.old;
	  env = env'';
	  modinfo = {senv'.modinfo with
		       resolver = resolver};
	  labset = Labset.add l senv'.labset;
	  revstruct = (l,SFBconst cb)::senv'.revstruct;
          univ = senv'.univ;
          engagement = senv'.engagement;
	  imports = senv'.imports;
	  loads = senv'.loads ;
	  local_retroknowledge = senv'.local_retroknowledge }


(* Insertion of inductive types. *)

let add_mind dir l mie senv =
  if mie.mind_entry_inds = [] then
    anomaly "empty inductive types declaration";
            (* this test is repeated by translate_mind *)
  let id = (List.nth mie.mind_entry_inds 0).mind_entry_typename in
  if l <> label_of_id id then
    anomaly ("the label of inductive packet and its first inductive"^
	     " type do not match");
  check_label l senv.labset;
    (* TODO: when we will allow reorderings we will have to verify
       all labels *)
  let kn = make_mind senv.modinfo.modpath dir l in
  let mib = translate_mind senv.env kn mie in
  let senv' = add_constraints mib.mind_constraints senv in
  let env'' = Environ.add_mind kn mib senv'.env in
  kn, { old = senv'.old;
	env = env'';
	modinfo = senv'.modinfo;
	labset = Labset.add l senv'.labset;  (* TODO: the same as above *)
	revstruct = (l,SFBmind mib)::senv'.revstruct;
        univ = senv'.univ;
        engagement = senv'.engagement;
	imports = senv'.imports;
	loads = senv'.loads;
        local_retroknowledge = senv'.local_retroknowledge }

(* Insertion of module types *)

let add_modtype l mte inl senv =
  check_label l senv.labset;
  let mp = MPdot(senv.modinfo.modpath, l) in
  let mtb = translate_module_type senv.env mp inl mte  in
  let senv' = add_constraints mtb.typ_constraints senv in
   let env'' = Environ.add_modtype mp mtb senv'.env in
    mp, { old = senv'.old;
	  env = env'';
	  modinfo = senv'.modinfo;
	  labset = Labset.add l senv'.labset;
	  revstruct = (l,SFBmodtype mtb)::senv'.revstruct;
          univ = senv'.univ;
          engagement = senv'.engagement;
	  imports = senv'.imports;
	  loads = senv'.loads;
          local_retroknowledge = senv'.local_retroknowledge }


(* full_add_module adds module with universes and constraints *)
let full_add_module mb senv =
  let senv = add_constraints mb.mod_constraints senv in
  let env = Modops.add_module mb senv.env in
    {senv with env = env}

(* Insertion of modules *)

let add_module l me inl senv =
  check_label l senv.labset;
  let mp = MPdot(senv.modinfo.modpath, l) in
  let mb = translate_module senv.env mp inl me in
  let senv' = full_add_module mb senv  in
  let modinfo = match mb.mod_type with
      SEBstruct _ -> 
	{ senv'.modinfo with
	    resolver = 
	    add_delta_resolver mb.mod_delta senv'.modinfo.resolver}
    | _ -> senv'.modinfo
  in
    mp,mb.mod_delta,
  { old = senv'.old;
    env = senv'.env;
    modinfo = modinfo;
    labset = Labset.add l senv'.labset;
    revstruct = (l,SFBmodule mb)::senv'.revstruct;
    univ = senv'.univ;
    engagement = senv'.engagement;
    imports = senv'.imports;
    loads = senv'.loads;
    local_retroknowledge = senv'.local_retroknowledge }
    
(* Interactive modules *)

let start_module l senv =
  check_label l senv.labset;
 let mp = MPdot(senv.modinfo.modpath, l) in
 let modinfo = { modpath = mp;
		 label = l;
		 variant = STRUCT [];
		 resolver = empty_delta_resolver;
		 resolver_of_param = empty_delta_resolver}
 in
   mp, { old = senv;
	 env = senv.env;
	 modinfo = modinfo;
	 labset = Labset.empty;
	 revstruct = [];
         univ = Univ.Constraint.empty;
         engagement = None;
	 imports = senv.imports;
	 loads = [];
	 (* spiwack : not sure, but I hope it's correct *)
         local_retroknowledge = [] }

let end_module l restype senv =
  let oldsenv = senv.old in
  let modinfo = senv.modinfo in
  let mp = senv.modinfo.modpath in
  let restype =
    Option.map
      (fun (res,inl) -> translate_module_type senv.env mp inl res) restype in
  let params,is_functor =
    match modinfo.variant with
      | NONE | LIBRARY _ | SIG _ -> error_no_module_to_end ()
      | STRUCT params -> params, (List.length params > 0)
  in
  if l <> modinfo.label then error_incompatible_labels l modinfo.label;
  if not (empty_context senv.env) then error_local_context None;
  let functorize_struct tb =
    List.fold_left
      (fun mtb (arg_id,arg_b) ->
	SEBfunctor(arg_id,arg_b,mtb))
      tb
      params
  in
   let auto_tb =
     SEBstruct (List.rev senv.revstruct)
  in
   let mexpr,mod_typ,mod_typ_alg,resolver,cst = 
    match restype with
      | None ->  let mexpr = functorize_struct auto_tb in
	 mexpr,mexpr,None,modinfo.resolver,Constraint.empty
      | Some mtb ->
	  let auto_mtb = {
	    typ_mp = senv.modinfo.modpath;
	    typ_expr = auto_tb;
	    typ_expr_alg = None;
	    typ_constraints = Constraint.empty;
	    typ_delta = empty_delta_resolver} in
	  let cst = check_subtypes senv.env auto_mtb
	    mtb in
	  let mod_typ = functorize_struct mtb.typ_expr in
	  let mexpr = functorize_struct auto_tb in
	  let typ_alg = 
	    Option.map functorize_struct mtb.typ_expr_alg in
	    mexpr,mod_typ,typ_alg,mtb.typ_delta,cst
  in
  let cst = Constraint.union cst senv.univ in
  let mb =
    { mod_mp = mp;
      mod_expr = Some mexpr;
      mod_type = mod_typ;
      mod_type_alg = mod_typ_alg;
      mod_constraints = cst;
      mod_delta = resolver;
      mod_retroknowledge = senv.local_retroknowledge }
  in
  let newenv = oldsenv.env in
  let newenv = set_engagement_opt senv.engagement newenv in
  let senv'= {senv with env=newenv} in
  let senv' =
    List.fold_left
      (fun env (_,mb) -> full_add_module mb env) 
      senv'
      (List.rev senv'.loads)
  in
  let newenv = Environ.add_constraints cst senv'.env in
  let newenv =
    Modops.add_module mb newenv in 
  let modinfo = match mb.mod_type with
      SEBstruct _ -> 
	{ oldsenv.modinfo with
	    resolver = 
	    add_delta_resolver resolver oldsenv.modinfo.resolver}
    | _ -> oldsenv.modinfo
  in
    mp,resolver,{ old = oldsenv.old;
		  env = newenv;
		  modinfo = modinfo;
		  labset = Labset.add l oldsenv.labset;
		  revstruct = (l,SFBmodule mb)::oldsenv.revstruct;
		  univ = Univ.Constraint.union senv'.univ oldsenv.univ;
		  (* engagement is propagated to the upper level *)
		  engagement = senv'.engagement;
		  imports = senv'.imports;
		  loads = senv'.loads@oldsenv.loads;
		  local_retroknowledge = 
	senv'.local_retroknowledge@oldsenv.local_retroknowledge }


(* Include for module and module type*)
 let add_include me is_module inl senv =
   let sign,cst,resolver =
     if is_module then
       let sign,resolver,cst =  
	 translate_struct_include_module_entry senv.env 
	   senv.modinfo.modpath inl me in
	 sign,cst,resolver
     else
       let mtb = 
	 translate_module_type senv.env 
	   senv.modinfo.modpath inl me in
       mtb.typ_expr,mtb.typ_constraints,mtb.typ_delta
   in
   let senv = add_constraints cst senv in
   let mp_sup = senv.modinfo.modpath in
     (* Include Self support  *)
   let rec compute_sign sign mb resolver senv = 
     match sign with
     | SEBfunctor(mbid,mtb,str) ->
	 let cst_sub = check_subtypes senv.env mb mtb in
	 let senv = add_constraints cst_sub senv in
	 let mpsup_delta = if not inl then mb.typ_delta else
	   complete_inline_delta_resolver senv.env mp_sup mbid mtb mb.typ_delta in
	 let subst = map_mbid mbid mp_sup mpsup_delta in
	 let resolver = subst_codom_delta_resolver subst resolver in
	   (compute_sign 
	     (subst_struct_expr subst str) mb resolver senv)
     | str -> resolver,str,senv
   in
   let resolver,sign,senv = compute_sign sign {typ_mp = mp_sup;
				      typ_expr = SEBstruct (List.rev senv.revstruct);
				      typ_expr_alg = None;
				      typ_constraints = Constraint.empty;
				      typ_delta = senv.modinfo.resolver} resolver senv in
   let str = match sign with
     | SEBstruct(str_l) -> str_l
     | _ -> error ("You cannot Include a high-order structure.")
   in
   let senv =
     {senv 
      with modinfo = 
	 {senv.modinfo
	  with resolver =
	     add_delta_resolver resolver senv.modinfo.resolver}}
   in
   let add senv (l,elem)  =
     check_label l senv.labset;
     match elem with
       | SFBconst cb ->
	   let kn = make_kn mp_sup empty_dirpath l in
	   let con = constant_of_kn_equiv kn
	     (canonical_con 
		(constant_of_delta resolver (constant_of_kn kn)))
	   in
	   let senv' = add_constraints cb.const_constraints senv in
	   let env'' = Environ.add_constant con cb senv'.env in
	     { old = senv'.old;
	       env = env'';
	       modinfo = senv'.modinfo;
	       labset = Labset.add l senv'.labset;
	       revstruct = (l,SFBconst cb)::senv'.revstruct;
               univ = senv'.univ;
               engagement = senv'.engagement;
	       imports = senv'.imports;
	       loads = senv'.loads ;
	       local_retroknowledge = senv'.local_retroknowledge }
       | SFBmind mib ->
	   let kn = make_kn mp_sup empty_dirpath l in
	   let mind = mind_of_kn_equiv kn
	     (canonical_mind 
		(mind_of_delta resolver (mind_of_kn kn)))
	   in
	   let senv' = add_constraints mib.mind_constraints senv in
	   let env'' = Environ.add_mind mind mib senv'.env in
	     { old = senv'.old;
	       env = env'';
	       modinfo = senv'.modinfo;
	       labset = Labset.add l senv'.labset;
	       revstruct = (l,SFBmind mib)::senv'.revstruct;
               univ = senv'.univ;
               engagement = senv'.engagement;
	       imports = senv'.imports;
	       loads = senv'.loads;
               local_retroknowledge = senv'.local_retroknowledge }

       | SFBmodule mb ->
	   let senv' = full_add_module mb senv in
	     { old = senv'.old;
	       env = senv'.env;
	       modinfo = senv'.modinfo;
	       labset = Labset.add l senv'.labset;
	       revstruct = (l,SFBmodule mb)::senv'.revstruct;
	       univ = senv'.univ;
	       engagement = senv'.engagement;
	       imports = senv'.imports;
	       loads = senv'.loads;
	       local_retroknowledge = senv'.local_retroknowledge }
       | SFBmodtype mtb ->
	   let senv' = add_constraints mtb.typ_constraints senv in
	   let mp = MPdot(senv.modinfo.modpath, l) in
	   let env' = Environ.add_modtype mp mtb senv'.env in
	     { old = senv.old;
	       env = env';
	       modinfo = senv'.modinfo;
	       labset = Labset.add l senv.labset;
	       revstruct = (l,SFBmodtype mtb)::senv'.revstruct;
               univ = senv'.univ;
               engagement = senv'.engagement;
	       imports = senv'.imports;
	       loads = senv'.loads;
               local_retroknowledge = senv'.local_retroknowledge }
   in
     resolver,(List.fold_left add senv str)

(* Adding parameters to modules or module types *)

let add_module_parameter mbid mte inl senv =
  if  senv.revstruct <> [] or senv.loads <> [] then
    anomaly "Cannot add a module parameter to a non empty module";
  let mtb = translate_module_type senv.env (MPbound mbid) inl mte in
  let senv = 
    full_add_module (module_body_of_type (MPbound mbid) mtb) senv
  in
  let new_variant = match senv.modinfo.variant with
    | STRUCT params -> STRUCT ((mbid,mtb) :: params)
    | SIG params -> SIG ((mbid,mtb) :: params)
    | _ ->
	anomaly "Module parameters can only be added to modules or signatures"  
  in
    
  let resolver_of_param = match mtb.typ_expr with
      SEBstruct _ -> mtb.typ_delta
    | _ -> empty_delta_resolver
  in
    mtb.typ_delta, { old = senv.old;
		     env = senv.env;
		     modinfo = { senv.modinfo with 
				   variant = new_variant;
				   resolver_of_param = add_delta_resolver
			      resolver_of_param senv.modinfo.resolver_of_param};
		     labset = senv.labset;
		     revstruct = [];
		     univ = senv.univ;
		     engagement = senv.engagement;
		     imports = senv.imports;
		     loads = [];
		     local_retroknowledge = senv.local_retroknowledge }
      

(* Interactive module types *)

let start_modtype l senv =
  check_label l senv.labset;
 let mp = MPdot(senv.modinfo.modpath, l) in
 let modinfo = { modpath = mp;
		 label = l;
		 variant = SIG [];
		 resolver = empty_delta_resolver;
		 resolver_of_param = empty_delta_resolver}
 in
  mp, { old = senv;
	env = senv.env;
	modinfo = modinfo;
	labset = Labset.empty;
	revstruct = [];
        univ = Univ.Constraint.empty;
        engagement = None;
	imports = senv.imports;
	loads = [] ;
	(* spiwack: not 100% sure, but I think it should be like that *)
        local_retroknowledge = []}

let end_modtype l senv =
  let oldsenv = senv.old in
  let modinfo = senv.modinfo in
  let params =
    match modinfo.variant with
      | LIBRARY _ | NONE | STRUCT _ -> error_no_modtype_to_end ()
      | SIG params -> params
  in
  if l <> modinfo.label then error_incompatible_labels l modinfo.label;
  if not (empty_context senv.env) then error_local_context None;
  let auto_tb =
     SEBstruct (List.rev senv.revstruct)
  in
  let mtb_expr =
    List.fold_left
      (fun mtb (arg_id,arg_b) ->
	 SEBfunctor(arg_id,arg_b,mtb))
      auto_tb
      params
  in
  let mp = MPdot (oldsenv.modinfo.modpath, l) in
  let newenv = oldsenv.env in
  let newenv = Environ.add_constraints senv.univ  newenv in
  let newenv = set_engagement_opt senv.engagement newenv in
  let senv = {senv with env=newenv} in
  let senv =
    List.fold_left
      (fun env (mp,mb) -> full_add_module mb env)
      senv
      (List.rev senv.loads)
  in
  let mtb = {typ_mp = mp;
    typ_expr = mtb_expr;
    typ_expr_alg = None;
    typ_constraints = senv.univ;
    typ_delta = senv.modinfo.resolver} in
  let newenv =
    Environ.add_modtype mp mtb senv.env
  in
    mp, { old = oldsenv.old;
	  env = newenv;
	  modinfo = oldsenv.modinfo;
	  labset = Labset.add l oldsenv.labset;
	  revstruct = (l,SFBmodtype mtb)::oldsenv.revstruct;
          univ = Univ.Constraint.union senv.univ oldsenv.univ;
          engagement = senv.engagement;
	  imports = senv.imports;
	  loads = senv.loads@oldsenv.loads;
          (* spiwack : if there is a bug with retroknowledge in nested modules
             it's likely to come from here *)
          local_retroknowledge = 
        senv.local_retroknowledge@oldsenv.local_retroknowledge}

let current_modpath senv = senv.modinfo.modpath
let delta_of_senv senv = senv.modinfo.resolver,senv.modinfo.resolver_of_param

(* Check that the engagement expected by a library matches the initial one *)
let check_engagement env c =
  match Environ.engagement env, c with
    | Some ImpredicativeSet, Some ImpredicativeSet -> ()
    | _, None -> ()
    | _, Some ImpredicativeSet ->
        error "Needs option -impredicative-set."

let set_engagement c senv =
  {senv with
    env = Environ.set_engagement c senv.env;
    engagement = Some c }

(* Libraries = Compiled modules *)

type compiled_library =
    dir_path * module_body * library_info list * engagement option

(* We check that only initial state Require's were performed before
   [start_library] was called *)

let is_empty senv =
  senv.revstruct = [] &&
  senv.modinfo.modpath = initial_path &&
  senv.modinfo.variant = NONE

let start_library dir senv =
  if not (is_empty senv) then
    anomaly "Safe_typing.start_library: environment should be empty";
  let dir_path,l =
    match (repr_dirpath dir) with
	[] -> anomaly "Empty dirpath in Safe_typing.start_library"
      | hd::tl ->
	  make_dirpath tl, label_of_id hd
  in
  let mp = MPfile dir in
  let modinfo = {modpath = mp;
		 label = l;
		 variant = LIBRARY dir;
		 resolver = empty_delta_resolver;
		 resolver_of_param = empty_delta_resolver}
  in
  mp, { old = senv;
	env = senv.env;
	modinfo = modinfo;
	labset = Labset.empty;
	revstruct = [];
        univ = Univ.Constraint.empty;
        engagement = None;
	imports = senv.imports;
	loads = [];
        local_retroknowledge = [] }

let pack_module senv =
  {mod_mp=senv.modinfo.modpath;
   mod_expr=None;
   mod_type= SEBstruct (List.rev senv.revstruct);
   mod_type_alg=None;
   mod_constraints=Constraint.empty;
   mod_delta=senv.modinfo.resolver;
   mod_retroknowledge=[];
  }

let export senv dir =
  let modinfo = senv.modinfo in
  begin
    match modinfo.variant with
      | LIBRARY dp ->
	  if dir <> dp then
	    anomaly "We are not exporting the right library!"
      | _ ->
	  anomaly "We are not exporting the library"
  end;
  (*if senv.modinfo.params <> [] || senv.modinfo.restype <> None then
    (* error_export_simple *) (); *)
    let str = SEBstruct (List.rev senv.revstruct) in
    let mp = senv.modinfo.modpath in
    let mb = 
    { mod_mp = mp;
      mod_expr = Some str;
      mod_type = str;
      mod_type_alg = None;
      mod_constraints = senv.univ;
      mod_delta = senv.modinfo.resolver;
      mod_retroknowledge = senv.local_retroknowledge}
  in
   mp, (dir,mb,senv.imports,engagement senv.env)


let check_imports senv needed =
  let imports = senv.imports in
  let check (id,stamp) =
    try
      let actual_stamp = List.assoc id imports in
      if stamp <> actual_stamp then
	error
	  ("Inconsistent assumptions over module "^(string_of_dirpath id)^".")
    with Not_found ->
      error ("Reference to unknown module "^(string_of_dirpath id)^".")
  in
  List.iter check needed



(* we have an inefficiency: Since loaded files are added to the
environment every time a module is closed, their components are
calculated many times. Thic could be avoided in several ways:

1 - for each file create a dummy environment containing only this
file's components, merge this environment with the global
environment, and store for the future (instead of just its type)

2 - create "persistent modules" environment table in Environ add put
loaded by side-effect once and for all (like it is done in OCaml).
Would this be correct with respect to undo's and stuff ?
*)

let import (dp,mb,depends,engmt) digest senv =
  check_imports senv depends;
  check_engagement senv.env engmt;
  let mp = MPfile dp in
  let env = senv.env in
  let env = Environ.add_constraints mb.mod_constraints env in
  let env = Modops.add_module mb env in
  mp, { senv with
	  env = env;
	  modinfo = 
      {senv.modinfo with 
	 resolver = 
	    add_delta_resolver mb.mod_delta senv.modinfo.resolver};
	  imports = (dp,digest)::senv.imports;
	  loads = (mp,mb)::senv.loads }


(* Remove the body of opaque constants in modules *)
 let rec lighten_module mb =
  { mb with
    mod_expr = None;
    mod_type = lighten_modexpr mb.mod_type;
  }

and lighten_struct struc =
  let lighten_body (l,body) = (l,match body with
    | SFBconst ({const_opaque=true} as x) -> SFBconst {x with const_body=None}
    | (SFBconst _ | SFBmind _ ) as x -> x
    | SFBmodule m -> SFBmodule (lighten_module m)
    | SFBmodtype m -> SFBmodtype
	({m with
	    typ_expr = lighten_modexpr m.typ_expr}))
  in
    List.map lighten_body struc

and lighten_modexpr = function
  | SEBfunctor (mbid,mty,mexpr) ->
      SEBfunctor (mbid,
		    ({mty with
			typ_expr = lighten_modexpr mty.typ_expr}),
		  lighten_modexpr mexpr)
  | SEBident mp as x -> x
  | SEBstruct (struc) ->
      SEBstruct  (lighten_struct struc)
  | SEBapply (mexpr,marg,u) ->
      SEBapply (lighten_modexpr mexpr,lighten_modexpr marg,u)
  | SEBwith (seb,wdcl) ->
      SEBwith (lighten_modexpr seb,wdcl)

let lighten_library (dp,mb,depends,s) = (dp,lighten_module mb,depends,s)


type judgment = unsafe_judgment

let j_val j = j.uj_val
let j_type j = j.uj_type

let safe_infer senv = infer (env_of_senv senv)

let typing senv = Typeops.typing (env_of_senv senv)