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+(************************************************************************)
+(*  v      *   The Coq Proof Assistant  /  The Coq Development Team     *)
+(* <O___,, *   INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2011     *)
+(*   \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 Util
+open Names
+open Sign
+open Univ
+open Term
+open Declarations
+open Mod_subst
+
+type context_object =
+  | Variable of identifier (* A section variable or a Let definition *)
+  | Axiom of constant      (* An axiom or a constant. *)
+  | Opaque of constant     (* An opaque constant. *)
+
+(* Defines a set of [assumption] *)
+module OrderedContextObject =
+struct
+  type t = context_object
+  let compare x y =
+      match x , y with
+      | Variable i1 , Variable i2 -> id_ord i1 i2
+      | Axiom k1 , Axiom k2 -> Pervasives.compare k1 k2
+	          (* spiwack: it would probably be cleaner
+		     to provide a [kn_ord] function *)
+      | Opaque k1 , Opaque k2 -> Pervasives.compare k1 k2
+      | Variable _ , Axiom _ -> -1
+      | Axiom _ , Variable _ -> 1
+      | Opaque _ , _ -> -1
+      | _, Opaque _ -> 1
+end
+
+module ContextObjectSet = Set.Make (OrderedContextObject)
+module ContextObjectMap = Map.Make (OrderedContextObject)
+
+(** 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 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 _ | MPbound _ ->
+	raise Not_found (* should have been found by [lookup_module] *)
+      | MPdot (mp',lab') ->
+	let fields = memoize_fields_of_mp mp' in
+	match List.assoc lab' fields with
+	  | SFBmodule mb -> mb
+	  | _ -> assert false (* same label for a non-module ?! *)
+
+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 inner_mp = mp then subs
+    else add_mp inner_mp mp mb.mod_delta subs
+  in
+  Modops.subst_signature subs fields
+
+and fields_of_mb subs mb args =
+  let seb = match mb.mod_expr with
+    | None -> mb.mod_type (* cf. Declare Module *)
+    | Some seb -> seb
+  in
+  fields_of_seb subs mb.mod_mp seb args
+
+(* TODO: using [empty_delta_resolver] below in [fields_of_seb]
+   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.
+*)
+
+and fields_of_seb subs mp0 seb args = match seb with
+  | SEBstruct l ->
+    assert (args = []);
+    l, mp0, subs
+  | SEBident mp ->
+    let mb = lookup_module_in_impl (subst_mp subs mp) in
+    fields_of_mb subs mb args
+  | SEBapply (seb1,seb2,_) ->
+    (match seb2 with
+      | SEBident mp2 -> fields_of_seb subs mp0 seb1 (mp2::args)
+      | _ -> assert false) (* only legal application is to module names *)
+  | SEBfunctor (mbid,mtb,seb) ->
+    (match args with
+      | [] -> assert false (* we should only encounter applied functors *)
+      | mpa :: args ->
+	let subs = add_mbid mbid mpa empty_delta_resolver subs in
+	fields_of_seb subs mp0 seb args)
+  | SEBwith _ -> assert false (* should not appear in a mod_expr
+				   or mod_type field *)
+
+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 : *)
+    match List.assoc lab fields with
+      | SFBconst cb -> cb
+      | _ -> assert false (* label not pointing to a constant ?! *)
+  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 ("Print Assumption: unknown constant "^string_of_con cst)
+
+let lookup_constant cst =
+  try
+    let cb = Global.lookup_constant cst in
+    if cb.const_body <> None then cb
+    else lookup_constant_in_impl cst (Some cb)
+  with Not_found -> lookup_constant_in_impl cst None
+
+let assumptions ?(add_opaque=false) st (* t *) =
+  modcache := MPmap.empty;
+  let (idts,knst) = st in
+  (* Infix definition for chaining function that accumulate
+     on a and a ContextObjectSet, ContextObjectMap.  *)
+  let ( ** ) f1 f2 s m = let (s',m') = f1 s m in f2 s' m' in
+  (* This function eases memoization, by checking if an object is already
+     stored before trying and applying a function.
+     If the object is there, the function is not fired (we are in a
+     particular case where memoized object don't need a treatment at all).
+     If the object isn't there, it is stored and the function is fired*)
+  let try_and_go o f s m =
+    if ContextObjectSet.mem o s then
+      (s,m)
+    else
+      f (ContextObjectSet.add o s) m
+  in
+  let identity2 s m = (s,m)
+  in
+  (* Goes recursively into the term to see if it depends on assumptions.
+    The 3 important cases are :
+     - Const _ where we need to first unfold the constant and return
+       the needed assumptions of its body in the environment,
+     - Rel _ which means the term is a variable which has been bound
+       earlier by a Lambda or a Prod (returns [] ),
+     - Var _ which means that the term refers to a section variable or
+       a "Let" definition, in the former it is an assumption of [t],
+       in the latter is must be unfolded like a Const.
+    The other cases are straightforward recursion.
+    Calls to the environment are memoized, thus avoiding to explore
+    the DAG of the environment as if it was a tree (can cause
+    exponential behavior and prevent the algorithm from terminating
+    in reasonable time). [s] is a set of [context_object], representing
+    the object already visited.*)
+  let rec do_constr t s acc =
+    let rec iter t =
+      match kind_of_term t with
+	| Var id -> do_memoize_id id
+	| Meta _ | Evar _ -> assert false
+	| Cast (e1,_,e2) | Prod (_,e1,e2) | Lambda (_,e1,e2) ->
+	  (iter e1)**(iter e2)
+	| LetIn (_,e1,e2,e3) -> (iter e1)**(iter e2)**(iter e3)
+	| App (e1, e_array) -> (iter e1)**(iter_array e_array)
+	| Case (_,e1,e2,e_array) -> (iter e1)**(iter e2)**(iter_array e_array)
+	| Fix (_,(_, e1_array, e2_array)) | CoFix (_,(_,e1_array, e2_array)) ->
+          (iter_array e1_array) ** (iter_array e2_array)
+	| Const kn -> do_memoize_kn kn
+	| _ -> identity2 (* closed atomic types + rel *)
+    and iter_array a = Array.fold_right (fun e f -> (iter e)**f) a identity2
+    in iter t s acc
+
+  and add_id id s acc =
+    (* a Var can be either a variable, or a "Let" definition.*)
+    match Global.lookup_named id with
+    | (_,None,t) ->
+        (s,ContextObjectMap.add (Variable id) t acc)
+    | (_,Some bdy,_) -> do_constr bdy s acc
+
+  and do_memoize_id id =
+    try_and_go (Variable id) (add_id id)
+
+  and add_kn kn s acc =
+    let cb = lookup_constant kn in
+    let do_type cst =
+      let ctype =
+	match cb.const_type with
+	| PolymorphicArity (ctx,a) -> mkArity (ctx, Type a.poly_level)
+	| NonPolymorphicType t -> t
+      in
+	(s,ContextObjectMap.add cst ctype acc)
+    in
+    let (s,acc) =
+      if add_opaque && cb.const_body <> None
+	&& (cb.const_opaque || not (Cpred.mem kn knst))
+      then
+	do_type (Opaque kn)
+      else (s,acc)
+    in
+      match cb.const_body with
+      | None -> do_type (Axiom kn)
+      | Some body -> do_constr (Declarations.force body) s acc
+
+  and do_memoize_kn kn =
+    try_and_go (Axiom kn) (add_kn kn)
+
+ in
+ fun t ->
+   snd (do_constr t
+	  (ContextObjectSet.empty)
+	  (ContextObjectMap.empty))