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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2016 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* The following definitions are used by the function
[assumptions] which gives as an output the set of all
axioms and sections variables on which a given term depends
in a context (expectingly the Global context) *)
(* Initial author: Arnaud Spiwack
Module-traversing code: Pierre Letouzey *)
open Pp
open CErrors
open Util
open Names
open Term
open Declarations
open Mod_subst
open Globnames
open Printer
open Context.Named.Declaration
module NamedDecl = Context.Named.Declaration
(** For a constant c in a module sealed by an interface (M:T and
not M<:T), [Global.lookup_constant] may return a [constant_body]
without body. We fix this by looking in the implementation
of the module *)
let modcache = ref (MPmap.empty : structure_body MPmap.t)
let rec search_mod_label lab = function
| [] -> raise Not_found
| (l, SFBmodule mb) :: _ when Label.equal l lab -> mb
| _ :: fields -> search_mod_label lab fields
let rec search_cst_label lab = function
| [] -> raise Not_found
| (l, SFBconst cb) :: _ when Label.equal l lab -> cb
| _ :: fields -> search_cst_label lab fields
(* TODO: using [empty_delta_resolver] below is probably slightly incorrect. But:
a) I don't see currently what should be used instead
b) this shouldn't be critical for Print Assumption. At worse some
constants will have a canonical name which is non-canonical,
leading to failures in [Global.lookup_constant], but our own
[lookup_constant] should work.
*)
let rec fields_of_functor f subs mp0 args = function
|NoFunctor a -> f subs mp0 args a
|MoreFunctor (mbid,_,e) ->
match args with
| [] -> assert false (* we should only encounter applied functors *)
| mpa :: args ->
let subs = join (map_mbid mbid mpa empty_delta_resolver (*TODO*)) subs in
fields_of_functor f subs mp0 args e
let rec lookup_module_in_impl mp =
try Global.lookup_module mp
with Not_found ->
(* The module we search might not be exported by its englobing module(s).
We access the upper layer, and then do a manual search *)
match mp with
| MPfile _ -> raise Not_found (* can happen if mp is an open module *)
| MPbound _ -> assert false
| MPdot (mp',lab') ->
let fields = memoize_fields_of_mp mp' in
search_mod_label lab' fields
and memoize_fields_of_mp mp =
try MPmap.find mp !modcache
with Not_found ->
let l = fields_of_mp mp in
modcache := MPmap.add mp l !modcache;
l
and fields_of_mp mp =
let mb = lookup_module_in_impl mp in
let fields,inner_mp,subs = fields_of_mb empty_subst mb [] in
let subs =
if mp_eq inner_mp mp then subs
else add_mp inner_mp mp mb.mod_delta subs
in
Modops.subst_structure subs fields
and fields_of_mb subs mb args = match mb.mod_expr with
|Algebraic expr -> fields_of_expression subs mb.mod_mp args expr
|Struct sign -> fields_of_signature subs mb.mod_mp args sign
|Abstract|FullStruct -> fields_of_signature subs mb.mod_mp args mb.mod_type
(** The Abstract case above corresponds to [Declare Module] *)
and fields_of_signature x =
fields_of_functor
(fun subs mp0 args struc ->
assert (List.is_empty args);
(struc, mp0, subs)) x
and fields_of_expr subs mp0 args = function
|MEident mp ->
let mb = lookup_module_in_impl (subst_mp subs mp) in
fields_of_mb subs mb args
|MEapply (me1,mp2) -> fields_of_expr subs mp0 (mp2::args) me1
|MEwith _ -> assert false (* no 'with' in [mod_expr] *)
and fields_of_expression x = fields_of_functor fields_of_expr x
let lookup_constant_in_impl cst fallback =
try
let mp,dp,lab = repr_kn (canonical_con cst) in
let fields = memoize_fields_of_mp mp in
(* A module found this way is necessarily closed, in particular
our constant cannot be in an opened section : *)
search_cst_label lab fields
with Not_found ->
(* Either:
- The module part of the constant isn't registered yet :
we're still in it, so the [constant_body] found earlier
(if any) was a true axiom.
- The label has not been found in the structure. This is an error *)
match fallback with
| Some cb -> cb
| None -> anomaly (str "Print Assumption: unknown constant " ++ pr_con cst)
let lookup_constant cst =
try
let cb = Global.lookup_constant cst in
if Declareops.constant_has_body cb then cb
else lookup_constant_in_impl cst (Some cb)
with Not_found -> lookup_constant_in_impl cst None
(** Graph traversal of an object, collecting on the way the dependencies of
traversed objects *)
let label_of = function
| ConstRef kn -> pi3 (repr_con kn)
| IndRef (kn,_)
| ConstructRef ((kn,_),_) -> pi3 (repr_mind kn)
| VarRef id -> Label.of_id id
let rec traverse current ctx accu t = match kind_of_term t with
| Var id ->
let body () = id |> Global.lookup_named |> NamedDecl.get_value in
traverse_object accu body (VarRef id)
| Const (kn, _) ->
let body () = Global.body_of_constant_body (lookup_constant kn) in
traverse_object accu body (ConstRef kn)
| Ind ((mind, _) as ind, _) ->
traverse_inductive accu mind (IndRef ind)
| Construct (((mind, _), _) as cst, _) ->
traverse_inductive accu mind (ConstructRef cst)
| Meta _ | Evar _ -> assert false
| Case (_,oty,c,[||]) ->
(* non dependent match on an inductive with no constructors *)
begin match Constr.(kind oty, kind c) with
| Lambda(_,_,oty), Const (kn, _)
when Vars.noccurn 1 oty &&
not (Declareops.constant_has_body (lookup_constant kn)) ->
let body () = Global.body_of_constant_body (lookup_constant kn) in
traverse_object
~inhabits:(current,ctx,Vars.subst1 mkProp oty) accu body (ConstRef kn)
| _ ->
Termops.fold_constr_with_full_binders
Context.Rel.add (traverse current) ctx accu t
end
| _ -> Termops.fold_constr_with_full_binders
Context.Rel.add (traverse current) ctx accu t
and traverse_object ?inhabits (curr, data, ax2ty) body obj =
let data, ax2ty =
let already_in = Refmap_env.mem obj data in
match body () with
| None ->
let data =
if not already_in then Refmap_env.add obj Refset_env.empty data else data in
let ax2ty =
if Option.is_empty inhabits then ax2ty else
let ty = Option.get inhabits in
try let l = Refmap_env.find obj ax2ty in Refmap_env.add obj (ty::l) ax2ty
with Not_found -> Refmap_env.add obj [ty] ax2ty in
data, ax2ty
| Some body ->
if already_in then data, ax2ty else
let contents,data,ax2ty =
traverse (label_of obj) Context.Rel.empty
(Refset_env.empty,data,ax2ty) body in
Refmap_env.add obj contents data, ax2ty
in
(Refset_env.add obj curr, data, ax2ty)
(** Collects the references occurring in the declaration of mutual inductive
definitions. All the constructors and names of a mutual inductive
definition share exactly the same dependencies. Also, there is no explicit
dependency between mutually defined inductives and constructors. *)
and traverse_inductive (curr, data, ax2ty) mind obj =
let firstind_ref = (IndRef (mind, 0)) in
let label = label_of obj in
let data, ax2ty =
(* Invariant : I_0 \in data iff I_i \in data iff c_ij \in data
where I_0, I_1, ... are in the same mutual definition and c_ij
are all their constructors. *)
if Refmap_env.mem firstind_ref data then data, ax2ty else
let mib = Global.lookup_mind mind in
(* Collects references of parameters *)
let param_ctx = mib.mind_params_ctxt in
let nparam = List.length param_ctx in
let accu =
traverse_context label Context.Rel.empty
(Refset_env.empty, data, ax2ty) param_ctx
in
(* Build the context of all arities *)
let arities_ctx =
let global_env = Global.env () in
Array.fold_left (fun accu oib ->
let pspecif = Univ.in_punivs (mib, oib) in
let ind_type = Inductive.type_of_inductive global_env pspecif in
let ind_name = Name oib.mind_typename in
Context.Rel.add (Context.Rel.Declaration.LocalAssum (ind_name, ind_type)) accu)
Context.Rel.empty mib.mind_packets
in
(* For each inductive, collects references in their arity and in the type
of constructors*)
let (contents, data, ax2ty) = Array.fold_left (fun accu oib ->
let arity_wo_param =
List.rev (List.skipn nparam (List.rev oib.mind_arity_ctxt))
in
let accu =
traverse_context
label param_ctx accu arity_wo_param
in
Array.fold_left (fun accu cst_typ ->
let param_ctx, cst_typ_wo_param = Term.decompose_prod_n_assum nparam cst_typ in
let ctx = Context.(Rel.fold_outside Context.Rel.add ~init:arities_ctx param_ctx) in
traverse label ctx accu cst_typ_wo_param)
accu oib.mind_user_lc)
accu mib.mind_packets
in
(* Maps all these dependencies to inductives and constructors*)
let data = Array.fold_left_i (fun n data oib ->
let ind = (mind, n) in
let data = Refmap_env.add (IndRef ind) contents data in
Array.fold_left_i (fun k data _ ->
Refmap_env.add (ConstructRef (ind, k+1)) contents data
) data oib.mind_consnames) data mib.mind_packets
in
data, ax2ty
in
(Refset_env.add obj curr, data, ax2ty)
(** Collects references in a rel_context. *)
and traverse_context current ctx accu ctxt =
snd (Context.Rel.fold_outside (fun decl (ctx, accu) ->
match decl with
| Context.Rel.Declaration.LocalDef (_,c,t) ->
let accu = traverse current ctx (traverse current ctx accu t) c in
let ctx = Context.Rel.add decl ctx in
ctx, accu
| Context.Rel.Declaration.LocalAssum (_,t) ->
let accu = traverse current ctx accu t in
let ctx = Context.Rel.add decl ctx in
ctx, accu) ctxt ~init:(ctx, accu))
let traverse current t =
let () = modcache := MPmap.empty in
traverse current Context.Rel.empty (Refset_env.empty, Refmap_env.empty, Refmap_env.empty) t
(** Hopefully bullet-proof function to recover the type of a constant. It just
ignores all the universe stuff. There are many issues that can arise when
considering terms out of any valid environment, so use with caution. *)
let type_of_constant cb = match cb.Declarations.const_type with
| Declarations.RegularArity ty -> ty
| Declarations.TemplateArity (ctx, arity) ->
Term.mkArity (ctx, Sorts.sort_of_univ arity.Declarations.template_level)
let assumptions ?(add_opaque=false) ?(add_transparent=false) st gr t =
let (idts, knst) = st in
(** Only keep the transitive dependencies *)
let (_, graph, ax2ty) = traverse (label_of gr) t in
let fold obj _ accu = match obj with
| VarRef id ->
let decl = Global.lookup_named id in
if is_local_assum decl then
let t = Context.Named.Declaration.get_type decl in
ContextObjectMap.add (Variable id) t accu
else accu
| ConstRef kn ->
let cb = lookup_constant kn in
let accu =
if cb.const_typing_flags.check_guarded then accu
else
let l = try Refmap_env.find obj ax2ty with Not_found -> [] in
ContextObjectMap.add (Axiom (Guarded kn, l)) Constr.mkProp accu
in
if not (Declareops.constant_has_body cb) || not cb.const_typing_flags.check_universes then
let t = type_of_constant cb in
let l = try Refmap_env.find obj ax2ty with Not_found -> [] in
ContextObjectMap.add (Axiom (Constant kn,l)) t accu
else if add_opaque && (Declareops.is_opaque cb || not (Cpred.mem kn knst)) then
let t = type_of_constant cb in
ContextObjectMap.add (Opaque kn) t accu
else if add_transparent then
let t = type_of_constant cb in
ContextObjectMap.add (Transparent kn) t accu
else
accu
| IndRef (m,_) | ConstructRef ((m,_),_) ->
let mind = Global.lookup_mind m in
if mind.mind_typing_flags.check_guarded then
accu
else
let l = try Refmap_env.find obj ax2ty with Not_found -> [] in
ContextObjectMap.add (Axiom (Positive m, l)) Constr.mkProp accu
in
Refmap_env.fold fold graph ContextObjectMap.empty
|