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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        *)
(************************************************************************)

(*i*)
open Errors
open Util
open Pp
open Names
open Cic
open Declarations
(*i*)

let error_not_a_constant l =
  error ("\""^(Label.to_string l)^"\" is not a constant")

let error_not_a_functor () = error "Application of not a functor"

let error_incompatible_modtypes _ _ = error "Incompatible module types"

let error_not_match l _ =
  error ("Signature components for label "^Label.to_string l^" do not match")

let error_no_such_label l = error ("No such label "^Label.to_string l)

let error_no_such_label_sub l l1 =
  let l1 = string_of_mp l1 in
  error ("The field "^
         Label.to_string l^" is missing in "^l1^".")

let error_not_a_module_loc loc s =
  user_err_loc (loc,"",str ("\""^Label.to_string s^"\" is not a module"))

let error_not_a_module s = error_not_a_module_loc Loc.ghost s

let error_with_module () =
  error "Unsupported 'with' constraint in module implementation"

let is_functor = function
  | MoreFunctor _ -> true
  | NoFunctor _ -> false

let destr_functor = function
  | MoreFunctor (arg_id,arg_t,body_t) -> (arg_id,arg_t,body_t)
  | NoFunctor _ -> error_not_a_functor ()

let module_body_of_type mp mtb =
  { mtb with mod_mp = mp; mod_expr = Abstract }

let rec add_structure mp sign resolver env =
  let add_one env (l,elem) =
    let kn = KerName.make2 mp l in
    let con = Constant.make1 kn in
    let mind = mind_of_delta resolver (MutInd.make1 kn) in
      match elem with
	| SFBconst cb ->
	   (* let con =  constant_of_delta resolver con in*)
	      Environ.add_constant con cb env
	| SFBmind mib ->
	   (* let mind =  mind_of_delta resolver mind in*)
	    Environ.add_mind mind mib env
	| SFBmodule mb -> add_module mb env
	      (* adds components as well *)
	| SFBmodtype mtb -> Environ.add_modtype mtb.mod_mp mtb env
  in
  List.fold_left add_one env sign

and add_module mb env =
  let mp = mb.mod_mp in
  let env = Environ.shallow_add_module mp mb env in
  match mb.mod_type with
  | NoFunctor struc -> add_structure mp struc mb.mod_delta env
  | MoreFunctor _ -> env

let add_module_type mp mtb env = add_module (module_body_of_type mp mtb) env

let strengthen_const mp_from l cb resolver =
  match cb.const_body with
    | Def _ -> cb
    | _ ->
      let con = Constant.make2 mp_from l in
      (* let con =  constant_of_delta resolver con in*)
      let u = 
	if cb.const_polymorphic then Univ.UContext.instance cb.const_universes 
	else Univ.Instance.empty
      in
      { cb with const_body = Def (Declarations.from_val (Const (con,u))) }

let rec strengthen_mod mp_from mp_to mb =
  if Declarations.mp_in_delta mb.mod_mp mb.mod_delta then mb
  else strengthen_body true mp_from mp_to mb

and strengthen_body is_mod mp_from mp_to mb =
  match mb.mod_type with
  | MoreFunctor _ -> mb
  | NoFunctor sign ->
    let resolve_out,sign_out = strengthen_sig mp_from sign mp_to mb.mod_delta
    in
    { mb with
      mod_expr =
        (if is_mod then Algebraic (NoFunctor (MEident mp_to)) else Abstract);
      mod_type = NoFunctor sign_out;
      mod_delta = resolve_out }

and strengthen_sig mp_from sign mp_to resolver =
  match sign with
    | [] -> empty_delta_resolver,[]
    | (l,SFBconst cb) :: rest ->
	let item' = l,SFBconst (strengthen_const mp_from l cb resolver) in
	let resolve_out,rest' = strengthen_sig mp_from rest mp_to resolver in
	resolve_out,item'::rest'
    | (_,SFBmind _ as item):: rest ->
	let resolve_out,rest' = strengthen_sig mp_from rest mp_to resolver in
	  resolve_out,item::rest'
    | (l,SFBmodule mb) :: rest ->
	let mp_from' = MPdot (mp_from,l) in
	let mp_to' = MPdot(mp_to,l) in
	let mb_out = strengthen_mod mp_from' mp_to' mb in
	let item' = l,SFBmodule (mb_out) in
	let resolve_out,rest' = strengthen_sig mp_from rest mp_to resolver in
	resolve_out (*add_delta_resolver resolve_out mb.mod_delta*),
	item':: rest'
    | (l,SFBmodtype mty as item) :: rest ->
	let resolve_out,rest' = strengthen_sig mp_from rest mp_to resolver in
	resolve_out,item::rest'

let strengthen mtb mp =
  strengthen_body false mtb.mod_mp mp mtb

let subst_and_strengthen mb mp =
  strengthen_mod mb.mod_mp mp (subst_module (map_mp mb.mod_mp mp) mb)

let module_type_of_module mp mb =
  let mtb =
    { mb with
      mod_expr = Abstract;
      mod_type_alg = None;
      mod_retroknowledge = [] }
  in
  match mp with
  | Some mp -> strengthen {mtb with mod_mp = mp} mp
  | None -> mtb