(others + (abs (common - card))), e1
in
let _, current = EqualitySet.fold f pos_set initial in
- Printf.printf "\nsymbols-based selection: %s\n\n"
- (string_of_equality ~env current);
+(* Printf.printf "\nsymbols-based selection: %s\n\n" *)
+(* (string_of_equality ~env current); *)
(Positive, current),
(([], neg_set),
(remove current pos_list, EqualitySet.remove current pos_set))
;;
-let forward_simplify env ?(active=[]) ?passive (sign, current) =
- (* first step, remove already present equalities *)
+let forward_simplify env (sign, current) ?passive active =
let pn, pp =
match passive with
| None -> [], []
(List.map (fun e -> Positive, e) pp)
in
let all = active @ pn @ pp in
- let duplicate =
- let rec aux = function
- | [] -> false
- | (s, eq)::tl when s = sign ->
- if meta_convertibility_eq current eq then true
- else aux tl
- | _::tl -> aux tl
- in
- aux all
+ let rec find_duplicate sign current = function
+ | [] -> false
+ | (s, eq)::tl when s = sign ->
+ if meta_convertibility_eq current eq then true
+ else find_duplicate sign current tl
+ | _::tl -> find_duplicate sign current tl
in
- if duplicate then
- None
- else
- let rec aux env (sign, current) = function
- | [] -> Some (sign, current)
- | (Negative, _)::tl -> aux env (sign, current) tl
- | (Positive, equality)::tl ->
- let newmeta, newcurrent =
- demodulation !maxmeta env current equality in
- maxmeta := newmeta;
- if is_identity env newcurrent then
- None
- else if newcurrent <> current then
- aux env (sign, newcurrent) active
+(* let duplicate = find_duplicate sign current all in *)
+(* if duplicate then *)
+(* None *)
+(* else *)
+ let rec aux env (sign, current) = function
+ | [] -> Some (sign, current)
+ | (Negative, _)::tl -> aux env (sign, current) tl
+ | (Positive, equality)::tl ->
+ let newmeta, newcurrent =
+ demodulation !maxmeta env current equality in
+ maxmeta := newmeta;
+ if is_identity env newcurrent then
+ if sign = Negative then
+ Some (sign, current)
else
- aux env (sign, newcurrent) tl
- in
- aux env (sign, current) all
+ None
+ else if newcurrent <> current then
+ aux env (sign, newcurrent) active
+ else
+ aux env (sign, newcurrent) tl
+ in
+ let res = aux env (sign, current) all in
+ match res with
+ | None -> None
+ | Some (s, c) ->
+ if find_duplicate s c all then
+ None
+ else
+ let pred (sign, eq) =
+ if sign <> s then false
+ else subsumption env c eq
+ in
+ if List.exists pred all then None
+ else res
;;
-let forward_simplify_new env ?(active=[]) ?passive (new_neg, new_pos) =
+let forward_simplify_new env (new_neg, new_pos) ?passive active =
let pn, pp =
match passive with
| None -> [], []
let new_pos_set =
List.fold_left (fun s e -> EqualitySet.add e s) EqualitySet.empty new_pos
in
- new_neg, EqualitySet.elements new_pos_set
-;;
-
-
-(*
-let backward_simplify_active env (sign, current) active =
- match sign with
- | Negative -> active
- | Positive ->
- let active =
- List.map
- (fun (s, equality) ->
- (* match s with *)
- (* | Negative -> s, equality *)
- (* | Positive -> *)
- let newmeta, equality =
- demodulation !maxmeta env equality current in
- maxmeta := newmeta;
- s, equality)
- active
- in
- let active =
- List.filter (fun (s, eq) -> not (is_identity env eq)) active
- in
- let find eq1 where =
- List.exists (fun (s, e) -> meta_convertibility_eq eq1 e) where
- in
- List.fold_right
- (fun (s, eq) res -> if find eq res then res else (s, eq)::res)
- active []
+ let new_pos = EqualitySet.elements new_pos_set in
+ let f sign' target (sign, eq) =
+(* Printf.printf "f %s <%s> (%s, <%s>)\n" *)
+(* (string_of_sign sign') (string_of_equality ~env target) *)
+(* (string_of_sign sign) (string_of_equality ~env eq); *)
+ if sign <> sign' then false
+ else subsumption env target eq
+ in
+(* new_neg, new_pos *)
+ (List.filter (fun e -> not (List.exists (f Negative e) all)) new_neg,
+ List.filter (fun e -> not (List.exists (f Positive e) all)) new_pos)
;;
-*)
let backward_simplify_active env (new_neg, new_pos) active =
let new_pos = List.map (fun e -> Positive, e) new_pos in
- let active =
+ let active, newa =
List.fold_right
- (fun (s, equality) res ->
- match forward_simplify env ~active:new_pos (s, equality) with
- | None -> res
- | Some e -> e::res)
- active []
+ (fun (s, equality) (res, newn) ->
+ match forward_simplify env (s, equality) new_pos with
+ | None when s = Negative ->
+ Printf.printf "\nECCO QUI: %s\n"
+ (string_of_equality ~env equality);
+ print_newline ();
+ res, newn
+ | None -> res, newn
+ | Some (s, e) ->
+ if equality = e then
+ (s, e)::res, newn
+ else
+ res, (s, e)::newn)
+ active ([], [])
in
let find eq1 where =
List.exists (fun (s, e) -> meta_convertibility_eq eq1 e) where
in
- List.fold_right
- (fun (s, eq) res ->
- if (is_identity env eq) || (find eq res) then
- res
- else
- (s, eq)::res)
- active []
+ let active, newa =
+ let f (s, eq) res =
+ if (is_identity env eq) || (find eq res) then res else (s, eq)::res
+ in
+ List.fold_right
+ (fun (s, eq) res ->
+ if (is_identity env eq) || (find eq res) then res else (s, eq)::res)
+ active [],
+ List.fold_right
+ (fun (s, eq) (n, p) ->
+ if (s <> Negative) && (is_identity env eq) then
+ (n, p)
+ else
+ if s = Negative then eq::n, p
+ else n, eq::p)
+ newa ([], [])
+ in
+ match newa with
+ | [], [] -> active, None
+ | _ -> active, Some newa
;;
let new_pos = List.map (fun e -> Positive, e) new_pos in
let (nl, ns), (pl, ps) = passive in
let f sign equality (resl, ress, newn) =
- match forward_simplify env ~active:new_pos (sign, equality) with
+ match forward_simplify env (sign, equality) new_pos with
| None -> resl, EqualitySet.remove equality ress, newn
| Some (s, e) ->
if equality = e then
;;
-let backward_simplify env ?(active=[]) ?passive new' =
- let active = backward_simplify_active env new' active in
+let backward_simplify env new' ?passive active =
+ let active, newa = backward_simplify_active env new' active in
match passive with
| None ->
- active, (([], EqualitySet.empty), ([], EqualitySet.empty)), None
+ active, (([], EqualitySet.empty), ([], EqualitySet.empty)), newa, None
| Some passive ->
- let passive, new' =
+ let passive, newp =
backward_simplify_passive env new' passive in
- active, passive, new'
+ active, passive, newa, newp
;;
let (sign, current), passive = select env passive active in
(* Printf.printf "before simplification: sign: %s\ncurrent: %s\n\n" *)
(* (string_of_sign sign) (string_of_equality ~env current); *)
- match forward_simplify env (sign, current) ~active ~passive with
- | None when sign = Negative ->
- Printf.printf "OK!!! %s %s" (string_of_sign sign)
- (string_of_equality ~env current);
- print_newline ();
- let proof, _, _, _ = current in
- Success (Some proof, env)
+ match forward_simplify env (sign, current) ~passive active with
+(* | None when sign = Negative -> *)
+(* Printf.printf "OK!!! %s %s" (string_of_sign sign) *)
+(* (string_of_equality ~env current); *)
+(* print_newline (); *)
+(* let proof, _, _, _ = current in *)
+(* Success (Some proof, env) *)
| None ->
(* Printf.printf "avanti... %s %s" (string_of_sign sign) *)
(* (string_of_equality ~env current); *)
(* print_newline (); *)
given_clause env passive active
| Some (sign, current) ->
- print_endline "\n================================================";
- Printf.printf "selected: %s %s"
- (string_of_sign sign) (string_of_equality ~env current);
- print_newline ();
+ if (sign = Negative) && (is_identity env current) then (
+ Printf.printf "OK!!! %s %s" (string_of_sign sign)
+ (string_of_equality ~env current);
+ print_newline ();
+ let proof, _, _, _ = current in
+ Success (Some proof, env)
+ ) else (
+ print_endline "\n================================================";
+ Printf.printf "selected: %s %s"
+ (string_of_sign sign) (string_of_equality ~env current);
+ print_newline ();
+
+ let new' = infer env sign current active in
+ let res, proof = contains_empty env new' in
+ if res then
+ Success (proof, env)
+ else
+ let new' = forward_simplify_new env new' active in
+ let active =
+ match sign with
+ | Negative -> active
+ | Positive ->
+ let active, _, newa, _ =
+ backward_simplify env ([], [current]) active
+ in
+ match newa with
+ | None -> active
+ | Some (n, p) ->
+ let nn = List.map (fun e -> Negative, e) n
+ and pp = List.map (fun e -> Positive, e) p in
+ nn @ active @ pp
+ in
+ let _ =
+ Printf.printf "active:\n%s\n"
+ (String.concat "\n"
+ ((List.map
+ (fun (s, e) -> (string_of_sign s) ^ " " ^
+ (string_of_equality ~env e)) active)));
+ print_newline ();
+ in
+ let _ =
+ match new' with
+ | neg, pos ->
+ Printf.printf "new':\n%s\n"
+ (String.concat "\n"
+ ((List.map
+ (fun e -> "Negative " ^
+ (string_of_equality ~env e)) neg) @
+ (List.map
+ (fun e -> "Positive " ^
+ (string_of_equality ~env e)) pos)));
+ print_newline ();
+ in
+ match contains_empty env new' with
+ | false, _ ->
+ let active =
+ match sign with
+ | Negative -> (sign, current)::active
+ | Positive -> active @ [(sign, current)]
+ in
+ let passive = add_to_passive passive new' in
+ let (_, ns), (_, ps) = passive in
+ Printf.printf "passive:\n%s\n"
+ (String.concat "\n"
+ ((List.map (fun e -> "Negative " ^
+ (string_of_equality ~env e))
+ (EqualitySet.elements ns)) @
+ (List.map (fun e -> "Positive " ^
+ (string_of_equality ~env e))
+ (EqualitySet.elements ps))));
+ print_newline ();
+ given_clause env passive active
+ | true, proof ->
+ Success (proof, env)
+ )
+;;
- let new' = infer env sign current active in
- let res, proof = contains_empty env new' in
- if res then
- Success (proof, env)
- else
- let new' = forward_simplify_new env new' ~active in
-
- (* let active, passive, retained = *)
- (* backward_simplify env [(sign, current)] ~active ~passive *)
- (* in *)
+let rec given_clause_fullred env passive active =
+ match passive_is_empty passive with
+ | true -> Failure
+ | false ->
+(* Printf.printf "before select\n"; *)
+ let (sign, current), passive = select env passive active in
+(* Printf.printf "before simplification: sign: %s\ncurrent: %s\n\n" *)
+(* (string_of_sign sign) (string_of_equality ~env current); *)
+ match forward_simplify env (sign, current) ~passive active with
+ | None ->
+ given_clause_fullred env passive active
+ | Some (sign, current) ->
+ if (sign = Negative) && (is_identity env current) then (
+ Printf.printf "OK!!! %s %s" (string_of_sign sign)
+ (string_of_equality ~env current);
+ print_newline ();
+ let proof, _, _, _ = current in
+ Success (Some proof, env)
+ ) else (
+ print_endline "\n================================================";
+ Printf.printf "selected: %s %s"
+ (string_of_sign sign) (string_of_equality ~env current);
+ print_newline ();
+
+ let new' = infer env sign current active in
+
let active =
- match sign with
- | Negative -> active
- | Positive ->
- let active, _, _ =
- backward_simplify env ([], [current]) ~active
- in
- active
+ if is_identity env current then active
+ else
+ match sign with
+ | Negative -> (sign, current)::active
+ | Positive -> active @ [(sign, current)]
+ in
+(* let _ = *)
+(* match new' with *)
+(* | neg, pos -> *)
+(* Printf.printf "new' before simpl:\n%s\n" *)
+(* (String.concat "\n" *)
+(* ((List.map *)
+(* (fun e -> "Negative " ^ *)
+(* (string_of_equality ~env e)) neg) @ *)
+(* (List.map *)
+(* (fun e -> "Positive " ^ *)
+(* (string_of_equality ~env e)) pos))); *)
+(* print_newline (); *)
+(* in *)
+ let rec simplify new' active passive =
+ let new' = forward_simplify_new env new' ~passive active in
+ let active, passive, newa, retained =
+ backward_simplify env new' ~passive active
+ in
+ match newa, retained with
+ | None, None -> active, passive, new'
+ | Some (n, p), None
+ | None, Some (n, p) ->
+ let nn, np = new' in
+ simplify (nn @ n, np @ p) active passive
+ | Some (n, p), Some (rn, rp) ->
+ let nn, np = new' in
+ simplify (nn @ n @ rn, np @ p @ rp) active passive
in
+ let active, passive, new' = simplify new' active passive in
let _ =
Printf.printf "active:\n%s\n"
(String.concat "\n"
in
match contains_empty env new' with
| false, _ ->
- let active =
- match sign with
- | Negative -> (sign, current)::active
- | Positive -> active @ [(sign, current)]
- in
let passive = add_to_passive passive new' in
- let (_, ns), (_, ps) = passive in
- Printf.printf "passive:\n%s\n"
- (String.concat "\n"
- ((List.map (fun e -> "Negative " ^
- (string_of_equality ~env e))
- (EqualitySet.elements ns)) @
- (List.map (fun e -> "Positive " ^
- (string_of_equality ~env e))
- (EqualitySet.elements ps))));
- print_newline ();
- given_clause env passive active
+(* let (_, ns), (_, ps) = passive in *)
+(* Printf.printf "passive:\n%s\n" *)
+(* (String.concat "\n" *)
+(* ((List.map (fun e -> "Negative " ^ *)
+(* (string_of_equality ~env e)) *)
+(* (EqualitySet.elements ns)) @ *)
+(* (List.map (fun e -> "Positive " ^ *)
+(* (string_of_equality ~env e)) *)
+(* (EqualitySet.elements ps)))); *)
+(* print_newline (); *)
+ given_clause_fullred env passive active
| true, proof ->
Success (proof, env)
+ )
;;
-(*
-let rec given_clause env passive active =
- match passive_is_empty passive with
- | true -> Failure
- | false ->
-(* Printf.printf "before select\n"; *)
- let (sign, current), passive = select env passive active in
-(* Printf.printf "before simplification: sign: %s\ncurrent: %s\n\n" *)
-(* (string_of_sign sign) (string_of_equality ~env current); *)
- print_endline "\n================================================";
- Printf.printf "selected: %s %s"
- (string_of_sign sign) (string_of_equality ~env current);
- print_newline ();
-
- let new' = infer env sign current active in
-
- let rec simplify new' active passive =
- let new' = forward_simplify_new env new' ~active ~passive in
- let active, passive, retained =
- backward_simplify env new' ~active ~passive
- in
- match retained with
- | None -> active, passive, new'
- | Some (rn, rp) ->
- let nn, np = new' in
- simplify (nn @ rn, np @ rp) active passive
- in
- let active, passive, new' = simplify new' active passive in
- let _ =
- Printf.printf "active:\n%s\n"
- (String.concat "\n"
- ((List.map
- (fun (s, e) -> (string_of_sign s) ^ " " ^
- (string_of_equality ~env e)) active)));
- print_newline ();
- in
- let _ =
- match new' with
- | neg, pos ->
- Printf.printf "new':\n%s\n"
- (String.concat "\n"
- ((List.map
- (fun e -> "Negative " ^
- (string_of_equality ~env e)) neg) @
- (List.map
- (fun e -> "Positive " ^
- (string_of_equality ~env e)) pos)));
- print_newline ();
- in
- match contains_empty env new' with
- | false, _ ->
- let active =
- match sign with
- | Negative -> (sign, current)::active
- | Positive -> active @ [(sign, current)]
- in
- let passive = add_to_passive passive new' in
- let (_, ns), (_, ps) = passive in
- Printf.printf "passive:\n%s\n"
- (String.concat "\n"
- ((List.map (fun e -> "Negative " ^
- (string_of_equality ~env e))
- (EqualitySet.elements ns)) @
- (List.map (fun e -> "Positive " ^
- (string_of_equality ~env e))
- (EqualitySet.elements ps))));
- print_newline ();
- given_clause env passive active
- | true, proof ->
- Success (proof, env)
-;;
-*)
-
-
let get_from_user () =
let dbd = Mysql.quick_connect
~host:"localhost" ~user:"helm" ~database:"mowgli" () in
;;
+let given_clause_ref = ref given_clause;;
+
+
let main () =
let module C = Cic in
let module T = CicTypeChecker in
print_endline "--------------------------------------------------";
let start = Unix.gettimeofday () in
print_endline "GO!";
- let res = given_clause env passive active in
+ let res = !given_clause_ref env passive active in
let finish = Unix.gettimeofday () in
match res with
| Failure ->
and set_conf f = configuration_file := f
and set_lpo () = Utils.compare_terms := lpo
and set_kbo () = Utils.compare_terms := nonrec_kbo
+ and set_fullred () = given_clause_ref := given_clause_fullred
in
Arg.parse [
+ "-f", Arg.Unit set_fullred, "Use full-reduction strategy";
+
"-r", Arg.Int set_ratio, "Weight-Age equality selection ratio (default: 0)";
"-s", Arg.Int set_sel,