type cic_id = string
+(*
type term_info =
{ sort: (cic_id, Ast.sort_kind) Hashtbl.t;
uri: (cic_id, NReference.reference) Hashtbl.t;
}
+*)
module IntMap = Map.Make(struct type t = int let compare = compare end);;
module StringMap = Map.Make(String);;
method interp_db = match interp_db with None -> assert false | Some x -> x
method set_interp_db v = {< interp_db = Some v >}
method set_interp_status
- : 'status. #g_status as 'status -> 'self
+ : 'status. (#g_status as 'status) -> 'self
= fun o -> {< interp_db = Some o#interp_db >}#set_coercion_status o
initializer
interp_db <- Some (initial_db self)
List.fold_right (fun idref t -> Ast.AttributedTerm (`IdRef idref, t))
let instantiate32 idrefs env symbol args =
- let rec instantiate_arg = function
+ let instantiate_arg = function
| Ast.IdentArg (n, name) ->
let t =
try List.assoc name env
dsc, args, appl_pattern
) (StringMap.find symbol status#interp_db.interpretations)
in
- if sorted then HExtlib.list_uniq (List.sort Pervasives.compare raw)
+ if sorted then HExtlib.list_uniq (List.sort Stdlib.compare raw)
else raw
with Not_found -> raise Interpretation_not_found
| NCic.Lambda (n,s,t) ->
idref (Ast.Binder (`Lambda,(Ast.Ident (n,None), Some (k ~context s)),
k ~context:((n,NCic.Decl s)::context) t))
- | NCic.LetIn (n,s,ty,NCic.Rel 1) ->
+ | NCic.LetIn (_n,s,ty,NCic.Rel 1) ->
idref (Ast.Cast (k ~context ty, k ~context s))
| NCic.LetIn (n,s,ty,t) ->
idref (Ast.LetIn ((Ast.Ident (n,None), Some (k ~context s)), k ~context
[arg] -> idref (k ~context arg)
| _ -> idref (Ast.Appl (List.map (k ~context) args))))
| NCic.Match (NReference.Ref (uri,_) as r,outty,te,patterns) ->
+ (try
let name = NUri.name_of_uri uri in
(* CSC
let uri_str = UriManager.string_of_uri uri in
in
let rec eat_branch n ctx ty pat =
match (ty, pat) with
- | NCic.Prod (name, s, t), _ when n > 0 ->
+ | NCic.Prod (_name, _s, t), _ when n > 0 ->
eat_branch (pred n) ctx t pat
| NCic.Prod (_, _, t), NCic.Lambda (name, s, t') ->
let cv, rhs = eat_branch 0 ((name,NCic.Decl s)::ctx) t t' in
| `Term -> Some case_indty
in
idref (Ast.Case (k ~context te, indty, Some (k ~context outty), patterns))
+ with
+ NCicEnvironment.ObjectNotFound msg ->
+ idref (Ast.Case(k ~context te,Some ("NOT_FOUND: " ^ Lazy.force msg,None),
+ Some (k ~context outty),
+ (List.map (fun t -> Ast.Pattern ("????", None, []), k ~context t)
+ patterns))))
;;
let rec nast_of_cic1 status ~idref ~output_type ~metasenv ~subst ~context term =
) context ([],[]))
;;
-let nmap_sequent0 status ~idref ~metasenv ~subst (i,(n,context,ty)) =
- let module K = Content in
+let nmap_sequent0 status ~idref ~metasenv ~subst (i,(_n,context,ty)) =
let nast_of_cic =
nast_of_cic1 status ~idref ~output_type:`Term ~metasenv ~subst in
let context' = nmap_context0 status ~idref ~metasenv ~subst context in
res
;;
-let build_def_item seed context metasenv id n t ty =
+let build_def_item seed _context _metasenv id n t ty =
let module K = Content in
(*
try
}
;;
-let nmap_obj0 status ~idref (uri,_,metasenv,subst,kind) =
+let nmap_cobj0 status ~idref (uri,_,metasenv,subst,kind) =
let module K = Content in
let nast_of_cic =
nast_of_cic1 status ~idref ~output_type:`Term ~metasenv ~subst in
K.inductive_constructors = build_constructors seed cl
}
in
-let build_fixpoint b seed =
+let build_fixpoint _b seed =
fun (_,n,_,ty,t) ->
let t = nast_of_cic ~context:[] t in
let ty = nast_of_cic ~context:[] ty in
foo status ~idref:(idref register_ref) obj, ids_to_refs
;;
-let nmap_obj status = with_idrefs nmap_obj0 status
+let nmap_cobj status = with_idrefs nmap_cobj0 status
let nmap_sequent status ~metasenv ~subst =
with_idrefs (nmap_sequent0 ~metasenv ~subst) status
let nmap_context status ~metasenv ~subst =
with_idrefs (nmap_context0 ~metasenv ~subst) status
+
+(* FG ***********************************************************************)
+
+let nmap_obj0 status ~idref (_, _, metasenv, subst, kind) =
+ let module N = NotationPt in
+ let nast_of_cic =
+ nast_of_cic1 status ~idref ~output_type:`Term ~metasenv ~subst
+ in
+ let rec mk_captures lno k c u = match lno, u with
+ | 0, _ -> k, c
+ | _, NCic.Prod (n, w, u) when lno > 0 ->
+ let cap = nast_of_cic ~context:c w, None in
+ let hyp = n, NCic.Decl w in
+ mk_captures (pred lno) (cap :: k) (hyp :: c) u
+ | _ -> assert false
+ in
+ let build_captures lno = function
+ | [] -> [], []
+ | (_, _, u, _) :: _ -> mk_captures lno [] [] u
+ in
+ let rec eat_prods prods lno t = match prods, lno, t with
+ | _, 0, _ -> t
+ | true, _, NCic.Prod (_, _, t) when lno > 0 -> eat_prods prods (pred lno) t
+ | false, _, NCic.Lambda (_, _, t) when lno > 0 -> eat_prods prods (pred lno) t
+ | _ -> assert false
+ in
+ let build_constractor lno context (_, n, bo) =
+ let bo = nast_of_cic ~context (eat_prods false lno bo) in
+ n, bo
+ in
+ let build_inductive is_ind lno context (_, n, ty, cl) =
+ let ty = nast_of_cic ~context (eat_prods true lno ty) in
+ n, is_ind, ty, List.map (build_constractor lno context) cl
+ in
+ match kind with
+ | NCic.Constant (_, n, xbo, ty, attrs) ->
+ let ty = nast_of_cic ~context:[] ty in
+ let xbo = match xbo with
+ | Some bo -> Some (nast_of_cic ~context:[] bo)
+ | None -> None
+ in
+ N.Theorem (n, ty, xbo, attrs)
+ | NCic.Inductive (is_ind, lno, itl, (src, `Regular)) ->
+ let captures, context = build_captures lno itl in
+ N.Inductive (captures, List.map (build_inductive is_ind lno context) itl, src)
+ | _ -> assert false (* NCic.Fixpoint (is_rec, ifl, _) -> *)
+
+let nmap_obj status = with_idrefs nmap_obj0 status