-(*let nparamod metasenv subst context t table =
- prerr_endline "========================================";
- let module C = struct
- let metasenv = metasenv
- let subst = subst
- let context = context
- end
- in
- let module B = NCicBlob.NCicBlob(C) in
- let module Pp = Pp.Pp (B) in
- let module FU = FoUnif.Founif(B) in
- let module IDX = Index.Index(B) in
- let module Sup = Superposition.Superposition(B) in
- let module Utils = FoUtils.Utils(B) in*)
-(*
- let test_unification _ = function
- | Terms.Node [_; _; lhs; rhs] ->
- prerr_endline "Unification test :";
- prerr_endline (Pp.pp_foterm lhs);
- prerr_endline (Pp.pp_foterm rhs);
- FU.unification [] [] lhs rhs
- | _ -> assert false
- in
- let subst,vars = test_unification [] res in
- prerr_endline "Result :";
- prerr_endline (Pp.pp_foterm res);
- prerr_endline "Substitution :";
- prerr_endline (Pp.pp_substitution subst)
-*)
-(*
-
- let mk_clause maxvar t =
- let ty = B.embed t in
- let proof = B.embed (NCic.Rel ~-1) in
- Utils.mk_unit_clause maxvar ty proof
- in
- let clause, maxvar = mk_clause 0 t in
- prerr_endline "Input clause :";
- prerr_endline (Pp.pp_unit_clause clause);
- let bag = Utils.empty_bag in
- let active_clauses, maxvar =
- List.fold_left
- (fun (cl,maxvar) t ->
- let c, m = mk_clause maxvar t in
- c::cl, m)
- ([],maxvar) table
- in
- let table =
- List.fold_left IDX.index_unit_clause IDX.DT.empty active_clauses
- in
- prerr_endline "Active table:";
- List.iter (fun uc -> prerr_endline (Pp.pp_unit_clause uc)) active_clauses;
- let bag, maxvar, _, newclauses =
- Sup.infer_right bag maxvar clause (active_clauses, table)
- in
- prerr_endline "Output clauses :";
- List.iter (fun c -> prerr_endline (Pp.pp_unit_clause c)) newclauses;
- (* prerr_endline "Proofs: ";
- prerr_endline (Pp.pp_bag bag); *)
- prerr_endline "========================================";
-;;
-*)
-let debug s =
- prerr_endline s
+let debug s = ()
+(* prerr_endline s *)
;;
-let nparamod metasenv subst context t table =
+let nparamod rdb metasenv subst context t table =
+ let nb_iter = ref 100 in
prerr_endline "========================================";
let module C = struct
let metasenv = metasenv
else let cl = PassiveSet.min_elt passives in
Some (snd cl,PassiveSet.remove cl passives)
in
- let rec given_clause bag maxvar actives passives g_actives g_passives =
+ let rec given_clause bag maxvar actives
+ passives g_actives g_passives =
+ decr nb_iter; if !nb_iter = 0 then raise (Failure "Timeout !");
+
(* keep goals demodulated w.r.t. actives and check if solved *)
- (* we may move this at the end of infer_right and simplify with
- * just new_clauses *)
+ (* we may move this at the end of infer_right *)
let bag, g_actives =
List.fold_left
(fun (bag,acc) c ->
- let bag, c = Sup.backward_simplify maxvar (snd actives) bag c in
+ let bag, c = Sup.simplify_goal maxvar (snd actives) bag c in
bag, c::acc)
(bag,[]) g_actives
in
- (* backward step : superposition left, simplifications on goals *)
- debug "Backward infer step...";
+ (* superposition left, simplifications on goals *)
+ debug "infer_left step...";
let bag, maxvar, g_actives, g_passives =
match select g_passives with
| None -> bag, maxvar, g_actives, g_passives
| Some (g_current, g_passives) ->
debug ("Selected goal : " ^ Pp.pp_unit_clause g_current);
let bag, g_current =
- Sup.backward_simplify maxvar (snd actives) bag g_current
+ Sup.simplify_goal maxvar (snd actives) bag g_current
in
let bag, maxvar, new_goals =
Sup.infer_left bag maxvar g_current actives
* P' = P + new' *)
debug "Forward infer step...";
let bag, maxvar, actives, passives, g_passives =
- match select passives with
- | None -> bag, maxvar, actives, passives, g_passives
- | Some (current, passives) ->
- debug ("Selected fact : " ^ Pp.pp_unit_clause current);
- match Sup.forward_simplify (snd actives) bag current with
- | None -> debug ("Discarded fact");
- bag, maxvar, actives, passives, g_passives
- | Some (bag, current) ->
- debug ("Fact after simplification :" ^ Pp.pp_unit_clause current);
- let bag, maxvar, actives, new_clauses =
- Sup.infer_right bag maxvar current actives
- in
- let ctable = IDX.index_unit_clause IDX.DT.empty current in
- let bag, maxvar, new_goals =
- List.fold_left
- (fun (bag,m,acc) g ->
- let bag, m, ng = Sup.infer_left bag maxvar g
- ([current],ctable) in
- bag,m,ng@acc)
- (bag,maxvar,[]) g_actives
- in
- let new_clauses = List.fold_left add_passive_clause
- PassiveSet.empty new_clauses in
- let new_goals = List.fold_left add_passive_clause
- PassiveSet.empty new_goals in
- bag, maxvar, actives,
- PassiveSet.union new_clauses passives,
- PassiveSet.union new_goals g_passives
+ let rec aux_simplify passives =
+ match select passives with
+ | None -> assert false
+ | Some (current, passives) ->
+ debug ("Selected fact : " ^ Pp.pp_unit_clause current);
+ match Sup.keep_simplified current actives bag with
+ | None -> aux_simplify passives
+ | Some x -> x
+ in
+ let (current, bag, actives) = aux_simplify passives
+ in
+ debug ("Fact after simplification :"
+ ^ Pp.pp_unit_clause current);
+ let bag, maxvar, actives, new_clauses =
+ Sup.infer_right bag maxvar current actives
+ in
+ let ctable = IDX.index_unit_clause IDX.DT.empty current in
+ let bag, maxvar, new_goals =
+ List.fold_left
+ (fun (bag,m,acc) g ->
+ let bag, m, ng = Sup.infer_left bag maxvar g
+ ([current],ctable) in
+ bag,m,ng@acc)
+ (bag,maxvar,[]) g_actives
+ in
+ let new_clauses = List.fold_left add_passive_clause
+ PassiveSet.empty new_clauses in
+ let new_goals = List.fold_left add_passive_clause
+ PassiveSet.empty new_goals in
+ bag, maxvar, actives,
+ PassiveSet.union new_clauses passives,
+ PassiveSet.union new_goals g_passives
in
prerr_endline
(Printf.sprintf "Number of actives : %d" (List.length (fst actives)));
in
let actives = [], IDX.DT.empty in
try given_clause bag maxvar actives passives g_actives g_passives
- with Sup.Success (bag, _, mp) ->
- prerr_endline "YES!";
- prerr_endline "Meeting point :"; prerr_endline (Pp.pp_unit_clause mp);
- (* prerr_endline "Bag :"; prerr_endline (Pp.pp_bag bag) *)
+ with
+ | Sup.Success (bag, _, (i,_,_,_)) ->
+ let l =
+ let module S =
+ HTopoSort.Make(struct type t=int let compare=Pervasives.compare end)
+ in
+ let module C : Set.S with type elt = int =
+ Set.Make(struct type t=int let compare=Pervasives.compare end)
+ in
+ let all id =
+ let rec traverse acc i =
+ match Terms.M.find i bag with
+ | (_,_,_,Terms.Exact _) -> acc
+ | (_,_,_,Terms.Step (_,i1,i2,_,_,_)) ->
+ traverse (traverse (C.add i1 (C.add i2 acc)) i1) i2
+ in
+ C.elements (traverse C.empty id)
+ in
+ S.topological_sort (all i) all
+ in
+ prerr_endline "YES!";
+ prerr_endline "Proof:";
+ List.iter (fun x ->
+ prerr_endline (Pp.pp_unit_clause (Terms.M.find x bag))) l;
+ let proofterm = B.mk_proof bag l in
+ prerr_endline
+ (NCicPp.ppterm ~metasenv:C.metasenv ~subst:C.subst ~context:C.context
+ proofterm);
+ let _metasenv, _subst, _proofterm, _prooftype =
+ NCicRefiner.typeof rdb C.metasenv C.subst C.context proofterm None
+ in
+ ()
+ | Failure _ -> prerr_endline "FAILURE";
;;